ZapperZ's
So You Want To Be A Physicist
(Last update: 03/17/2013)
Please go to http://physicsandphysicists.blogspot.com/ or at
http://www.physicsforums.com/ to find the writer of this essay. I welcome feedbacks. If you have recommended or used this guide, I would like to hear from you. If you think there are things are are missing, I also would like to hear from you.
http://www.physicsforums.com/ to find the writer of this essay. I welcome feedbacks. If you have recommended or used this guide, I would like to hear from you. If you think there are things are are missing, I also would like to hear from you.
Thank you.
Table of Contents
Introduction: The motivation for creating the series
Part I: Early Physics Education in High schools
Part II: Surviving the First Year of College
Part III: Mathematical Preparations
Part IV: The Life of a Physics Major
Part V: Applying for Graduate School
Part VI: What to Expect from Graduate School Before You Get There
Part VII: The US Graduate School System
Part VIII: Alternative Careers for a Physics Grad
Part VIIIa: Entering Physics Graduate School From Another Major
Part IX: First years of Graduate School from Being a TA to the Graduate Exams
Part X: Choosing a Research area and an advisor
Part XI: Initiating Research Work
Part XII: Research work and The Lab Book
Part XIII: Publishing in a Physics Journal
Part XIV: Oral Presentations
Part XIII: Publishing in a Physics Journal (Addendum)
Part XIV: Oral Presentations - Addendum
Part XV - Writing Your Doctoral Thesis/Desertation
Part XVI - Your Thesis Defense
Part XVII - Getting a Job!
Part XVIII - Postdoctoral Position
Part XIX - Your Curriculum Vitae
Introduction:
The motivation for creating the series
One of the most frequent questions we get in various physics
forums and IRC physics channels (besides the annoying ”can anything travel
faster than c?”) is the process and background of being a physics major. Often,
we have students asking what are the requirements of obtaining a physics
degree, and what can one do with such accomplishments.
I am hoping that, in a series of postings on this topic, we
get to go over and demystify the whole process of what one can expect as a
physics major in college, all the way to going through a Ph.D program, and even
beyond that in the land of postdoctoral work and employment. This is not as
easy as it sounds, especially considering the wide-ranging educational systems
we have throughout the world. So in most cases, the perspective I will tend to
have the most understanding with is the US educational system. This is where
someone from another country can come in and contribute their experiences and
wisdom.
What I hope to impart is not only what is known, as described
in various brochures and guidelines from many schools, but also what is never
told to the students. Most of these come from personal experience, things that
I found myself saying ”Boy, I wish someone would have told me that earlier!”.
As usual, feedback and questions are welcomed as this series
progresses. Who knows, maybe after this, I may finally be inclined to compile
all this into the book that I’ve always wanted to write! :)
Part I:
Early Physics Education in High schools
Most of us have various reasons or impetus for wanting to go
into this profession. I sometime liken it to wanting to be a priest (I have a
bad joke to accompany that, but I won’t say it) - the calling towards it that
somehow can’t be ignored. We all know that being a physicist would not make us
filthy rich, but there is somehow an intrinsic satisfaction working in this
field.
In this part of the series, I’d like to start at the
beginning. No, not during conception, or while one is still in the womb
(although it isn’t too late to read to a fetus about Newton’s Laws of motion).
The preparation one makes while still in high school before proceeding to
college can be important. The most important of which, in my opinion, is one’s
mastery of basic mathematics. Typically, by the time someone enters college,
there should already be a good command of algebra, trigonometry and geometry.
Taking intro physics without a good command of these three is a recipe for
disaster. In many cases, one also needs at least a semester’s worth of calculus
if the intro physics class includes calculus.
Although this appears to be obvious, it isn’t. In my brief
teaching experience at the freshman level (1st year students in a university in
the US), I often found that many students struggled with their physics homework
not because they did not understand the physics, but they could not do the
mathematics. Of course, they then blamed the difficulty of physics for this
without realizing that the physics course itself was not to be blamed.
Interestingly enough, we often encounter similar situation on our IRC channel.
Students coming in with physics problems are often stuck more with the
mathematics.
So, adequate preparations in mathematics at the high school
level is crucial. In the US, one can still catch up on the necessary basic
mathematics even after enrolling in a university by taking which ever
mathematics courses that one needs. However, this will mean delaying other
physics courses till one has the necessary mathematics skill.
Are high school physics classes necessary? Definitely. It is
always advantageous to have a flavor of the simple ideas of physics before
hand. In the US, there is such a thing as AP Physics, where high school
students get advanced physics lessons almost at the college level of intro
physics. This can do nothing but add to one’s advantage.
Unfortunately, sometime these high school physics classes can
backfire.
It is a sad reality that in many high school in the US, the
physics classes are often taught badly, and often by someone without a physics
degree. This has the negative effect of turning many students off this subject.
Ask anyone who hates physics and chances are, they had a bad introduction to it
in high school.
In Part 2, surviving the first year of college.
Part II:
Surviving the First Year of College
This part covers the survival tips of the first two
undergraduate years. So now you’re in college, and you have every intention to
be a physics major (actually, what I’m about to describe applies to anyone who
is taking a physics class, not just for physics majors). In most US
universities, as a freshman, you do not have a major-specific academic advisor,
mainly because most freshmen do not have an officially-declared major. What you
would probably get during your first week is a ”generic” advising based on what
you INTEND to go into. In all likelihood, assuming that you have all the
necessary background, it is a safe bet that you would need the complete
sequence of Calculus (typically a year, or 3 semesters worth). This would cover
all the basic calculus and analytical geometry (level of Thomas-Finney), and
towards the end of the sequence, may superficially cover more advanced topics
such as vector calculus and partial differential equations. As a physics major,
you will need more mathematics than this, and that includes a separate
mathematics course in the two advanced topics that I have mentioned, and maybe
even a course an complex analysis. These are the courses that you may have to
take after you complete the calculus sequence (more discussion on mathematics
in the next installment of this series).
The introduction physics courses can vary from school to
school. Typically, the broad dichotomy would be Intro Physics with or without
calculus. As a physics major, you would take the former. This means that, if
you do not have any calculus background, you may have to delay your first
physics class after you have at least completed the first semester of your
calculus class (high-school students, take note of this!). The typical intro
physics courses in US universities would be at the level of Halliday-Resnick.
It is typically covered in 2 or 3 semesters and is intended to be a general
survey of many different aspects of physics. These courses tend to be
accompanied by laboratory work, which is intended to be an introduction to a
systematic experimental study of various physics concepts.
I would like to expand on the importance of such laboratory
work, mainly because for many students, this is looked upon as a waste of time,
especially if the experiments and laboratory conditions are less than ideal.
There are certain things that cannot be taught, but can only be acquired. These
are what we call skills. The reason why one has to physically DO something
during a laboratory session is to acquire such skills. This does not just mean
physical skill, such as the ability to read an ammeter, to be able to perform a
task with the least amount of errors, etc., but also mental skills, such as
analytical ability to look at the object of the experiment and figuring out why
certain things are done certain ways. This include the ability to critically
analyze the experimental data to extract relevant information. Upon completion
of such exercise, one must then be able to clearly explain in words and
pictures (graphs) what one did, and the results. Again, such ability is
important for obvious reasons and it is a skill that can’t be taught. It can
only be acquired through practice!
Note that what I have described above is not just applicable
to physics majors. Such skills that can be acquired are important to anyone,
regardless of one’s major. In fact, I would make the assertion that acquiring
such skills is MORE important for most students in a physics class than knowing
the material. It is a fact that the majority of students in a physics class are
not physics majors. Although the knowledge of physics is important as a
foundation for other classes, for most of the students, the skills that can be
acquired through physics classes and laboratories are the more valuable traits
that they will carry with them throughout their academic life and beyond. The
ability for critical analysis and knowing the reliability of data and results
are important skills that are useful in all everyday life.
If you are an undergraduate in a US university, there is no
excuse for not enrolling yourself in The Society of Physics Students (SPS).
This organization is open to all students, not just physics majors. As part of
your membership dues, you are a year subscription to Physics Today, a journal
that practically all physicists read and contains timely information on the
world of physics and physicists. You will also get newsletter and information
specifically targeted for undergraduates like you, and also entitles you later
on for significant discounts and even free registrations to attend various
physics conferences. In other words, if you have even half a brain, enroll in
this! The benefits are just too great to not to. Go to the physics department
at your school and ask if they have a chapter of the SPS there. You can enroll
via your school’s chapter. If there isn’t any, go to the SPS website at
and you may enroll there as an individual member. It is NEVER
too early to be a member, so do it as soon as you are settled. If you are not
in a US university, you may still subscribe to Physics Today by going to their
website at
Throughout your first 2 years, the BEST thing you can do for
yourself is to get excellent grades. This, I’m sure, goes without saying, but
you have to realize that typically, these are the easiest and the most
important courses you will see in your undergraduate years. They are the
foundation that you will build on for your other courses, and they are the ones
you have a better chance of achieving the highest grades. Do not be discouraged
if you feel that at this stage, you are one of the many anonymous ”numbers” in
a large class. Most classes at this level tend to be huge and it isn’t easy to
distinguish oneself from the crowd (you will have plenty of opportunities to
distinguish yourself later on). But do not let this stop you from seeing the
instructor during his/her office hours, or using the Teaching Assistants if you
need help. They have been PAID to do just that!
In the next installment, we will discuss the transition
between the intro classes and the more advanced undergraduate classes, and your
first tentative steps towards distinguishing yourself from other students.
Part III:
Mathematical Preparations
In most universities in the US, a student must have a
declared major by the end of his or her second year. So this is an important
transition - making the commitment in a particular area of study. By now, if
you have followed the first two chapters of this series, you would have been
aware of the necessary background to pursue your academic life in the physical
sciences or engineering. All the discussion that we have had so far has been
”generic” to a large variety of field of studies. However, at this point, this
discussion will be more specific towards being a physics major.
The end of your second year marks the beginning of a more
advanced undergraduate physics courses. You will probably no longer be in the
same classroom as other majors, and most of your classes will comprise of only
physics majors. This part of the series will focus on additional preparation
you should have to be able to sail through your advanced undergraduate physics
courses.
It was alluded to in a previous posting on here of having
sufficient mathematical background. It has often been said that a physics major
sometime needs more mathematics than even a mathematics major. Mathematics is
viewed as a ”tool” that physicists use in describing and analyzing physical
phenomena. So one just never know what tools are needed for which job. This
means that a physics major must have a wide ranging knowledge of different
areas of mathematics, from differential equations, linear algebra, integral
transforms, vector calculus, special functions, etc. These are the mathematics
a physics major will encounter in courses in classical mechanics,
electromagnetic fields, and quantum mechanics. Unfortunately, most physics
majors do not have the inclination, nor the time, to be able to take all the
necessary mathematics classes. What typically happens is that they learn the
mathematics at the same time they are learning the physics. This is an
unfortunate way to learn the material, because more often than not, the
mathematics gets in the way of understanding the physics. It is hard enough to
learn the physics, but having to also learn the mathematics simultaneously
makes the problem rather daunting.
Many physics departments are aware of such problems, and one
of the remedies is to offer a course in mathematical physics. This is typically
a 1 year, 2-semester course covering a wide range of mathematics that a physics
major will need. The purpose of such a course is to give a brief introduction
to various areas of mathematics, not from the point of view of rigorous proofs
and derivations, but from the point of view of how to use them effectively and
correctly, especially when applied to actual physics problems. If there is such
a course at your school, I highly recommend that you enroll for it as soon as
you can, especially before you need them in your physics classes. That last
part, however, can be a problem. I have observed that in many schools, a
mathematical physics course tends to be offered late in undergraduate program,
or even as a graduate course. This, of course, does no good for someone wanting
to learn the mathematics before one needs it. If this is the case, I would
strongly suggest that you purchase this text: ”Mathematical Methods in the Physical
Science” by Mary Boas (Wiley). I have been recommending
(threatening?) this text to several people. This book is meant for someone to
start using at the end of the 2nd year, and can be used as a self-study. It
doesn’t require the mathematical sophistication that other similar books
require, such as Arfken. Furthermore, the Students Solution Manual that
supplements the text is a valuable book to have since it shows the details of
solving a few of the problems. I would recommend getting both books without the
slightest hesitation.
Knowledge of computers is almost a ”given” nowadays. However,
in physics, this goes a step further. No matter which area of physics you
intend to go into, you MUST know (i) how
to program and (ii) how to do numerical analysis. The first part is
automatic. Most schools require at least a class in computer programming, using
a favorite computer language. Most the field of physics, FORTRAN is still in wide usage, C is a language that is gaining in popularity, and C++ is beginning to take hold. I
suggest that the minimum number of programming language you should at least
have a working knowledge of is 2: Fortran
and C.
The 2nd part of programming, numerical analysis, isn’t as
automatic. This is the part most computer science majors do not do, but where
most physics, mathematics, and engineering majors, have to do. In many
instances, the mathematics that describe a physical system is not solvable
analytically. This may be in the form of large matrices, non-linear
differential equations, etc. In those cases, one can only find values out of
the mathematics by solving them numerically. Learning the mathematics of
numerical analysis is an extremely valuable skill for your academic knowledge,
and even for your ”marketability” to be employed. Do not be surprised if a few
of your courses require a class project involving numerical computing of
physical systems. Whether you intend to be an experimentalist or a theorist,
you will need to know how to perform numerical computation.
To give students such skill, most schools offer a specific
course in computational
physics (in some cases, this is a specific area of study in itself
at the graduate level). However, sometime such a course is not offered by the
physics department, but rather by either the mathematics department (as a
numerical analysis course) or the engineering department. Either way, you need
to make sure you get a formal education in one of these, especially if it isn’t
part of a required set of classes that you have to take. In the next
installment of this series, we will discuss on the most important people in
your life as a physics major: your adviser, your instructors, and your
teaching/laboratory assistants.
Part IV:
The Life of a Physics Major
So far, I have covered what I believe a student needs all the
way to the end of the 2nd year of studies. In most schools in the US, an
undergraduate must have a declared major by the end of the 2nd year (if not
sooner). So by now, you should already be officially a physics major.
Hopefully, by now, you would have made acquaintances with other physics majors
and know who are in the same year group as you. This is important because
chances are, you may want to find someone to discuss homework problems, etc.
This is where having a local chapter of the Society of Physics Students (SPS)
at your school can be useful. You get to meet other physics majors, and also
talk to the more senior students who can give you a better idea of what to
expect (or which professor to avoid in certain classes). You should also keep
in mind that there is a good chance that these are probably the same people who
might continue on in this profession, and that the friendship you are
establishing might someday turn into a valuable point of contact in your
professional career. Never underestimate
the value of personal contacts.
The transition from the 2nd year into the 3rd year of college
can mean smaller classes and more advanced subjects. This is where you start
studying the ”meat” of a physics program - what I would call the 3 foundations
of physics: classical mechanics,
electromagnetic fields, and quantum mechanics. These are taught in separate
courses, typically over 2 semesters each. Typical textbooks for each course
are: classical mechanics - Marion or Symon; E&M: Griffith,
Reitz/Milford/Christy; QM: Griffith, Liboff. Now pay attention to this: ALL
other physics subjects BUILD on the foundation laid by these three courses. The
importance of these subjects cannot be overemphasized. In fact, if you are able
to do it, you
may even want to consider lowering your class load for 1 or 2 semesters while
you’re taking one or more of these classes just so you can devote extra time to
them. An E&M class, for example, can easily suck in a lot of
time to understand and the homework problem can take a long time to finish. If
you can afford it, do not hesitate to buy
one of those books that have sample questions and worked out answers
(Schaum and Rhea have a series of those). Now don’t cheat! Use them as guides
and extra practice exercises to make sure you understand the material.
If you are in a school with a small student population,
chances are that the faculty would already know you either by sight or by name.
If not, this is where you have to start distinguishing yourself. Talk to your
instructors if you do not understand something, that is why they have office
hours. Introduce yourself so that they know your name. By the middle of your
3rd year, you should have enough physics knowledge that you might be somewhat
useful to do some work. Ask around if there are any research project or groups
that you can work in, or find a professor that might be interested in giving
you a simple project for you to work on. This is especially relevant in your
4th and final year where most schools have a senior research class available.
Start attending your department’s weekly seminar/colloquium. Most of these may
be way over your head, but they tend to cover a lot of research front areas of
physics. You might also get some flavor if some of these research work are
either done, or of some interest, at your school. The point here is that you
need to start distinguishing yourself slowly by this time. The faculty in your
department should not just see you during class time.
Your contact with our academic adviser may depend on you and
your needs. Most of the time, you only need to see him/her when you have to
decide on what classes you need to take for the next academic term. But if you
want to discuss with someone about your academic goals and what advanced level
classes to take if you want to follow a certain path, he/she should also be
someone you should consider. Make full use of the responsibility that they have
been given. Now, in many schools, you are also given the freedom to choose your
own academic adviser. Check with the policy of your department. If that is the
case, you can certainly ask if a faculty member that you prefer can in fact
become your undergraduate adviser. Again, this option may not be available in
all schools, especially for smaller ones. Many undergraduates tend to stick to
the person they were assigned to when they declared their major. The role of an
academic adviser at this level isn't as crucial under ordinary circumstances as
when you get into graduate school.
The next part of this essay applies only to US universities
and to US citizens/permanent residents. If your school lacks the research work
that are of any interest to you, or if you want additional experience over the
summer holidays, then you may want to consider applying for the summer internship
programs provided by the US Dept. of Energy. This provides an excellent
opportunity for you to work at a world-renowned facility with practicing
physicists. You may find the necessary information at the DOE website below:
Keep in mind that competition for the internship is very
intense. So, apply early!
In the next installment of this series, we address the final
year of your undergraduate life, and the looming reality of either joining the
rat race, or continuing on to graduate school.
Part V:
Applying for Graduate School
We have now reached the final year of your undergraduate
program. By now, you would have gone through courses in the fundamental pillars
of physics (Classical
mechanics, Quantum mechanics, and E&M), and even courses in Thermodynamics/Statistical
Physics. Academically, this is where you start taking more advanced
courses, even some graduate level courses. There are plenty of options,
depending on where you go to school, how large your physics department is, etc.
The choices can range from a class in Solid
State Physics, Particle Physics, advanced laboratory work, etc. If you
already have a clear set of interest and know what area of physics you would
like to end up in, then this is where you want to try to enroll in a class in
that area. But even if you don’t know for sure yet (and this tends to be the
case for most students), it is still valuable to enroll in one of these
"specialized” area of physics, even if you may not eventually go into that
field.
The start of your senior year requires that you do some
serious thought on what you wish to do upon graduation. Most physics majors
will go on to graduate school with the hope of obtaining their doctorate. So in
this part of the series, we will concentrate on the application process of
going to graduate school. If this is the path you intend to take, then you need
to prepare yourself in a number of ways:
1. Prepare to take your Graduate Record Examination (GRE).
This should include both the GRE General and GRE Subject Test. While the GRE
scores may not be required for admission application in many schools, they are
usually required if you are seeking any form of assistantship. So it is best if
you already have the test scores.
2. Apply to graduate schools EARLY! If you intend to enroll
in the Fall, you should have ALL your applications in by December of the
previous year, especially if you are seeking assistantship. In many highly
competitive schools, your applications may need to be in even earlier. It is
NEVER too early.
3. Unless you have a 4.0 GPA, have outstanding letters of
recommendation, and the son of the President of the United States, you have
some uncertainty if your first choice of schools will accept you. It is ALWAYS
recommended that you group the schools you are applying to into 3 categories:
(i) Top Tier schools that you know are very difficult to get in (ii) Middle
tier schools that you may have a chance to get in and (iii) lower tier schools
that you think you can definitely get in. Note that these does not have any
reflection on the QUALITY of instructions/programs at each school. In many
instances, it is only the ”perceived” prestige that makes one school more
”desirable” than the other.
4. Do as much research on each school that you are applying.
If you know of some program or research area that a school is good in that you
are also interested in, then look it up and try to find the latest publications
in physics journals. Your admission application usually requires that you write
an essay regarding your aims, ambitions, and why you would want to study there.
So it is always good to be specific, and not just give some generic
description. Mention things specific to that school and that physics program
and why you want to be involved in that. It is extremely important if you can
also show a previous interest or work in a similar area. This will tell the
admission officer that you are a candidate that can be beneficial to them. Note
that saying such a thing in your application typically does NOT commit you to
that particular area of physics. You can still change your mind later on if you
wish. So don't hold back on the enthusiasm.
5. This last part is a bit dicey, since the situation can
either turn out very positive, or very bad. If you feel confident enough in
your ability, you may want to contact directly a faculty member of school that
you would like to attend. Obviously, this would be a school that is highly
competitive. You want to do this in cases where you think a direct
communication may enhance your chances - so don’t do this if you think your
contact may backfire. The best way to do this is to see if any of the faculty
member of your undergraduate institution know of anyone there personally. It is
always best to have such recommendation. If you do decide on such contact, tell
the person why, your interest, and that you would be interested in working in
his/her research group, etc.
In the next installment, I will try to describe what you can
expect graduate school to be BEFORE you get there.
Part VI:
What to Expect from Graduate School Before You Get There
We are still discussing the final year of your undergraduate
program where you are in the midst of applying to graduate schools. In Part 5,
I mentioned the word ”assistantship” several times, and it is important that
you understand what this is, and why you should apply for it. So this part of
the series will focus solely on the issue of assistantship. Take note that the
kind of assistantship that I will be discussing applies only to US
universities. However, ALL incoming graduate students, regardless of whether
they are US citizens or not, qualify for these assistantships. So a qualified student from another country
can certainly apply for one of these. However, as in many cases, there could be
exceptions to this, especially if the source of the money comes with
restrictions (such as research funded by the US Department of Defense, which
would require US citizenship and/or background security checks).
There are two forms of assistantships: (i) teaching
assistantships (TA) and (ii) research assistantships (RA). No matter which form
of assistantships that is being offered, typically what is involved is a
complete tuition/fees waiver, and a stipend. What this means is that your
schooling tuition and fees are being paid for by your department, and you will
also receive a paycheck (stipend) for your services. The amount of your stipend
depends entirely on your school. So this award is certainly significant
especially since top tier schools can have outrageously high tuition and fees.
So now, what are the differences between the two types of assistantships?
In practically all physics departments, and especially so at
large schools, they need the manpower from the physics graduate students to
either conduct tutorial/discussion sections, run physics laboratories, and/or
do homework/exam grading of lower-level physics courses. Therefore, they award
a number of TA each year or semester. So you become part of the department’s
manpower to help the various faculty members in various physics courses.
As an incoming physics students, TA’ship is the one you most
likely have a chance to get. However, your chances of getting one depends on
the number applying for it. Each school tends to already reserve TA’ships for
they graduate students who have already earned one the previous year. So
whatever is left to fulfill their needs/budget is the one being offered to the
new incoming pool of applicants. So certainly, competition for this award can
be intense. Take note also that in many schools, especially the ones that care
about the quality of their instructions, you may need to prove your ability to
communicate clearly in English, both written and verbal. Since you will be
dealing, often directly, with undergraduate students taking those various
physics classes, it is important that you are able to communicate with them. So
if you are from a non-English speaking background, you will need a good TOEFL
scores, and other supporting evidence, to bolster your chances.
The RA’ship, on the other hand, isn’t usually available for
new, incoming graduate students. An RA is a research position, and it is
awarded by individual faculty members based on the research grant that he/she
has obtained. Most faculty members do not award
RA’ships to a graduate student until he/she has at least passed the
department’s qualifying exam (more on what this exam is in a future
installment of this series). For most graduate students, the RA’ship is a way
to do one’s doctoral research work while being paid for it. So your RA work
also becomes your doctoral dissertation, meaning that you’d better be working
in the area of physics that you want to specialize in.
Depending on what field of physics you want to go into, and
whether it is theoretical or experimental, you may end up receiving a TA’ship
throughout your graduate career, especially if your supervisor has no research
grants to hire you. Experimentalists tend to have higher chances of getting an
RA’ship, simply due to the nature of the work.
The point that I’m trying to get across is that depending on
your ability and your GPA, graduate school may not cost you an arm and a leg.
It’s true that many US universities are extremely costly. However, a physics
graduate student has a lot more options in finding ways to reduce such cost.
Schools such as Stanford, for instance, automatically assumes that you will
require some form of assistantship when you apply to the physics graduate
program. In fact, practically all of their graduate students are on some form
of assistantships/scholarships. However, due to intense competition for the limited
funds, you need to do all you can to make yourself stand out. Hopefully, you
have done that during your undergraduate program, and have sent in your
applications early.
Part VII:
The US Graduate School System
We are still stuck in the discussion of your fourth and final
year of college. This time, I feel that a clearly explanation of the US
graduate school system is warranted, especially to others from the rest of the
world who intend to continue their graduate education in the US. This is
because there is often a great deal of confusion, from the conversation that
I’ve had, regarding what is required to apply for a Ph.D program in physics in
the US.
The broad dichotomy of higher education in physics in US
institutions can be lumped into (i) undergraduate education and (ii) graduate
education. When you have completed your physics undergraduate education, you
typically earn a degree of Bachelor of Science (B.Sc). (There are some schools
that actually award a Bachelor of Arts in physics, but that’s a different path
that we won’t discuss here.) Now this is what we refer to as your undergraduate
degree.
If you do decide to go on to graduate school, then the two
different physics degrees available to you are the Masters of Science (M.Sc)
and Doctor of Philosophy (Ph.D).
Now the next step is where US institutions differ from many
educational system throughout the world. If you intend to pursue a Doctorate
degree in physics, you do NOT need to first obtain a M.Sc. degree. Practically
all of the universities in the US that I’m aware of require that you have an
undergraduate degree to apply to a Ph.D program. Your undergraduate degree and
transcripts of your undergraduate class grades are the ones being used to
evaluate your candidacy. This is different from, let’s say, the UK system,
where you first pursue your M.Sc, and then after completing that, go on with
your Ph.D. In US institutions, if you are pursuing your Ph.D, you can get your
M.Sc ”along the way”, since at some point, you would have fulfill the requirements
for a M.Sc degree. In fact, I know of a few people who didn’t even bother
declaring for their M.Sc degrees. So you will see some people with academic
credentials as ”B.Sc in physics from so-and-so; Ph.D in physics from
so-and-so”, with the M.Sc degree missing.
These differences have created a sometime confusing
discussion from people intending to enroll in the graduate program in the US.
The first confusion comes in when they check the average length of time to
complete a physics Ph.D. Most are shock that the average length of time to
complete a Ph.D in the US is 5 1/2 to 6 years. I was told that it takes an
average of 3 years in the UK. However, if you consider what I have mentioned
earlier, the length of time for a Ph.D is taken from the enrollment into the program
by someone with a B.Sc degree, whereas the UK number is taken from the start of
the program after someone has obtained a M.Sc. or equivalent. It takes an
average of about 2 years to complete a physics M.Sc in the UK, I think. So now
there is a explanation of the apparent discrepancy between the length of time.
The total length of time to obtain a Ph.D after someone has a B.Sc degree is
still roughly similar in both educational systems.
The second, of course, is the idea that one must have a M.Sc
degree before applying for a Ph.D degree. Again, if one were to browse through
the requirement for acceptance into a Ph.D program at a US institution, one
will see that the major requirement is an undergraduate degree. I know of many
international students who either (i) stayed in their home countries to get
their M.Sc and then apply for a Ph.D program in the US, or (ii) apply
explicitly for a M.Sc program in the US even though their goals are to obtain a
Ph.D, because they assume that one must obtain a M.Sc first, before going on to
a Ph.D program. This can actually create additional annoying problems, because
one sometime has to REAPPLY for enrollment into the Ph.D program (this means
you may have to pay again the application fee, fill in application forms, etc...)
They also must apply for a change of status on their visas, because they are
now pursuing a different degree.... In other words, these are all messes and
annoyances that could have been avoided had one understood the graduate school
system.
So remember: check the requirements for admission into a Ph.D
program for a US institution. A B.Sc degree is required, not a M.Sc. So if you
intend to pursue a Ph.D, apply directly for a Ph.D program, using your B.Sc.
degree.
Part VIII:
Alternative Careers for a Physics Grad
We are still discussing the final year of your undergraduate
education. So far, we have covered what you need to consider if you want to go
on to graduate school and prepare yourself as best as you can for that part of
your journey. This is the "traditional" path that many physics
students follow. However, this isn’t the only path one can take with an
undergraduate physics degree. Many physics degree holder do not continue to
pursue a graduate degree in physics. So in this part of our series, I will
discuss this aspect of an education or career beyond the traditional physics
path.
If you have followed the series so far, you would have
noticed that very early on, I emphasized one very important thing: the
acquiring of a range of skills during your undergraduate years. This includes
everything from computer programming skills to experimental skills. This is
extremely important for any students, but especially if you end your physics
education upon completion of your undergraduate degree. If you decide to pursue
employment, your employability depends very much of what you can do. Let’s face
it, not many employers are looking for someone who can ”do physics”. There are,
however, employers who would like someone who can analyze numerical models and
maybe write codes, or maybe someone who can work in an electronics industry
doing thin film fabrication, etc. You will be surprised that some of the things
you accidentally picked up in an advanced physics lab might be the very thing
that gets you the job.
One of the most popular path that physics graduates take at
this point is to go into teaching at high schools. Most who intend to pursue
this line of work usually were enrolled in a simultaneous education program
while they were pursuing their undergraduate degree. That way, by the time one
obtain one’s physics degree, one is also qualified to teach high schools.
However, there are many graduates who obtain their teaching certificates after
the fact. So it is never too late to decide that this is the profession you
want. Keep in mind that different states in the US may have their own
requirements with regards to teaching credentials. Some may even allow you to
start teaching while you are in the process of getting your certification. So
this advice comes with plenty of caveat.
One of the growing options for physics degree holders is to
go into a graduate program in a different field of studies. There is now a
clear, growing need for physics degree holders to go into law. With the high
demand for patent lawyers (not to mention very high salary), there are many
physics graduates who are pursuing their law degrees.
Another popular career change is to go into medical schools.
This is very common to many students especially if they intend to go into
medical physics research (note that one doesn’t need to go into medical school
to major in medical physics). Again, there is a growing number of physics
degree holders who are making use of their physics degree in this field. One of
the other ”untraditional” avenue being adopted by physics graduates is to go
into either journalism, or writing. There are schools now offering
cross-disciplinary programs in which students majoring in an areas of science
or engineering can also augment their education with either a minor or even a
double major in such untraditional subjects. Most are training either to go
into mass media (science reporter), or even politics as assistants to various
representatives in Congress. There clearly is a demand for scientists who can
write and speak very well to the public, and programs such as these aim to
produce such people.
A growing number of physics degree holders (with B.Sc, M.Sc.,
and Ph.D.) are now opting to go into industries and become
"engineers". This is especially true for the electronics/semiconductor
industries that have hired many physics degree holder. It is often confusing
and misleading to many because these people often hold the title of
"engineers", but with a physics degree. Industrial physicist is
definitely a viable option for many as shown in the latest AIP job statistics:
http://www.aip.org/statistics/
There are many other avenues one can pursue with a physics
degree. I have only listed just a few. However, in every single one of these,
the preparation is still the same. One must have as wide as an experience as
possible as an undergraduate. This will allow for the possibility that
something one did might end up being the useful skill that one needs for a
certain line of career.
In the next installment of this series, we will finally
graduate out of our undergraduate years and go into the dreaded first year as a
graduate student and the nightmare of facing with the qualifying exam!
Part VIIIa:
Entering Physics Graduate School From Another Major
I have decided to tackle this issue because it became a very
common question in many physics forums. Can someone, without a degree in
physics, get accepted and succeed in physics graduate school all the way to
obtaining a Ph.D?
Obviously, this question cannot be answered easily, because
it depends on (i) your major (ii) what physics and mathematics classes you took
as an undergraduate. Students majoring in, say electrical engineering,
engineering mechanics, mathematics, applied mathematics, etc. will have an
easier path to going into physics than, say, student who majored in economics,
musics, etc., mainly because of many overlap in courses that one took as an
undergraduate.
Still, I think that there is a concrete way to determine how
well-prepared you are in going into a physics graduate program. This is
something you can do yourself as a first level of self-evaluation on whether
you are well-equipped to enter such program, or if you lack some necessary
knowledge to complete it successfully.
1. Get a copy of a GRE Physics Subject test. Now try to do
the test yourself. If you did not score 75% or better, you lack the necessary
preparation to go into a physics graduate school
2. If you have a school that you already have in mind on
where you might want to apply to, get a copy of the previous-year's qualifying
exams (more on the qualifying exams in Part IX of this essay). You don't even
have to actually do the exam. Just read it, and see if you actually understand
what it is asking, and what you will need to be able to solve it. If you find
that there are questions that go over your head, and you don't know where to
look for the way to start solving it, you immediately lack the necessary
preparation to go into a physics graduate school.
These are concrete, self-evaluation that you can test on
yourself. The GRE self-test should test a wide variety of physics knowledge
that a typical physics undergraduate should have by the time he/she graduates.
This allows you to compare your knowledge to such group of student. 75th
percentile score isn't that high, but in this self-test, you get to use as much
time as you need, and may even need to refer to physics text books to help you
with your test (something you can't do in an actual GRE test). I consider
knowing where to look for help as an indication that a student isn't clueless.
The qualifying exam self-test is more school-specific. This
is the standard of knowledge that a particular school would want their graduate
candidates to have, so the questions tend to be more difficult, and it isn't a
multiple choice exam. Here, I merely wanted you to see if you can actually
understand what is being asked, and then to know a way to solve it, without
actually having to solve it. Most physics students can understanding the
question, and have an idea on how to solve it. The process of solving the
question itself may not be trivial (usually, it isn't!), but knowing a way to
do it is a major indication that a student has the necessary knowledge. So if
you encounter anything here that makes no sense to you, and you also are
clueless in figuring out a way to solve it, then you lack the necessary
preparation.
The thing here is that, depending on where you intend on
applying and your educational background, getting accepted into a physics
graduate program isn't the biggest issue, especially if you're paying the full
tuition and fees yourself. With an engineering degree/computer science/math
degree and a GAP of 3.0 or better, you can find schools that might accept you
into their program. The question is, can you survive in the program and
ultimately, get to your goal of receiving your Ph.D? It would be a waste of
time (and financial resources if you're paying full fare) if you get snagged in
the qualifying exams because you were not sufficiently prepared.
If you don't think you are sufficiently prepared, you need to
evaluate on whether you should apply to a school, and then spend maybe a year,
or even two, in advanced undergraduate courses to not only get you up-to-speed,
but also to prepare you for the qualifying exams. Many schools will allow you
to do this. This evaluation will depend on your current educational background.
I would say that engineering and math majors will have the advantage here on
not needing way too many courses to get them up and running. If you come from a
non-science, non-technical background, you may want to consider how far up a
hole you're willing to climb to achieve your goal.
Using the two self-tests that I mentioned above will give you
a concrete evaluation of your knowledge to survive a physics graduate program.
Part IX:
First years of Graduate School from Being a TA to the Graduate Exams
You are now entering your first year of graduate school. In
terms of academic aspect, you will have a set of required courses that you must
take. Typically, these courses would be advanced classical mechanics (at the level of Goldstein),
advanced QM (at the level of Merzbacher and Sakurai), and advanced E&M (at
the level of Jackson or Landau-Lifschitz). Some or all of these
classes may cover more than a semester or quarter. No matter what you intend to
specialize in later on in your graduate studies, these are courses that all
physics graduate students must take. So plan on spending maybe the first 2
years of your graduate life taking your required and optional classes. This
should also give you the opportunity to get to know the various faculty
members, the specific types of research work being done at the school, the
faculty members who has the money to support graduate research assistants, people
you want to avoid like a plague, etc. These are all intangibles that you can
only find out once you are there and experiencing the system.
Take note that in the majority of graduate programs, you do
not have to enroll in as many credits hours per semester as what you were
required as an undergraduate. Most schools have a lower minimum credit hours
for graduate students than undergraduates, some even have no minimum. So you
can take one, two, or even just three classes per semester. This is especially
helpful if you are also a teaching assistant and have to put in some hours per
week doing your responsibility. However, keep in mind also that in most
schools, graduate students are expected
to attain higher grades than undergraduates in all their classes. Typically,
anything below a B is a failure (this varies from school to school, so double
check!). So you cannot get below some minimum grades (not just an F) to
maintain a passing mark.
If you are lucky enough to receive a teaching assistantship,
then you will be assign duties with certain faculty members. This may include running a
physics undergraduate laboratories, grading homework/tests, or even conducting
a discussion/tutorial session. Many graduate students tend to look
at these as a chore, but permit me to give you one important advice. You have NOT understood a material UNTIL
you are able to teach it effectively to another person. I will say without
hesitation that my experience in being a TA has been nothing but a completely
wonderful learning experience FOR ME. You quickly realize that if you want to
do a good job (rather than a mediocre one), you have to be meticulous in how
you present things to the students who are about to learn the material. Even
grading homework solutions can be a challenge sometime, especially when you
have a bunch of very intelligent students who can sometime offer a rather
different approach to answering a question. My philosophy in approaching my TA duties had always been
”if I have to to this, I might as well do it as well as I can”. I
think if you have pride in yourself and your ability, you’d never want to
produce a half-baked piece of work. This, I believe, is the only way to not
only fulfill your responsibility for what they hire you for, but for you to
also get as much out of it as possible. Besides, you CAN add this to your
resume later on!
But now, we come to the BIG MONSTER that is looming in your
future : the dreaded qualifying examination.
First of all, what the hell is it? It is an exam given by the
physics department of your school, to test if you have the basic, fundamental
physics knowledge to be able to complete the program. So these tests are highly
”school-dependent”, and thus, can vary in scope, nature, procedure, length,
etc. Typically, the exam is offered once a year, and a phd candidate has the
opportunity to pass it by the end of his/her 2nd year of graduate studies.
Failure to pass it by then will prevent the candidate from continuing (a polite
way of saying ”You have to leave and can’t come back!”). This is why many
research groups would not want you working for them till you pass this thing,
because they can’t be sure that you won’t just disappear.
Secondly, what is involved in such an exam? Again, this
varies quite a bit from school to school. Based on my observation, the
qualifying exam can go from one big exam in a single day, to an exam spread
over 2 days, to something that goes on for 5 consecutive days! I have seen
schools having separate days for different subject areas in physics: Day One -
Classical Mechanics, Day Two - E&M, Day Three - QM, etc.. I’ve seen
graduate exams in which if you pass CM and E&M, but fail QM that year, then
the following year, you only need to retake the QM part of the exam, while
others make you retake the whole thing. And get this, in some schools, the
written part is only HALF of the exam - there could be an oral part of the
qualifying exam where you are asked various questions and have to respond
verbally and work out your answer on the board. I’ve seen schools that use such
oral exams for students with borderline pass/fail results to see if they have a
higher ability than what is reflected in their exam scores.
Thirdly,
what is covered in the exam? A simple answer: everything that was taught to you
at the undergraduate level in a typical physics curriculum.
Because of this, it is often that a graduate student enroll in an
advanced undergraduate class or two during their 1st year of graduate studies
just to get up to speed with areas that he/she is weak in. So you do have a
limited time to shore up your weak points. In some schools, especially the
highly competitive ones, even the 1st year graduate material is included in the
qualifying exam. So again, the scope and difficulties of the exam content can
vary school to school. But what is common is that
you MUST know your undergraduate CM, E&M, and QM without fail! This is a
given. You should also know very well Thermodynamics and Statistical Mechanics.
Some exams allow you the option to choose the more specific areas such as
particle physics, solid state physics, nuclear physics, atomic physics, etc. I
have also seen a qualifying exam that, essentially, tests you on your
”historical” knowledge. A question lists a number of important experiments in
physics, and you are asked to pick... oh, 3 or 4, and write down what it is,
and why it was such an important experiment. So the moral of the story is,
almost everything and the kitchen sink, can be in one of these exams.
Fourth, how does one prepare for it? As I’ve said above, some
students retake a few undergraduate classes as preparation. However, the most
effective way for you to prepare for such an exam at your particular school is
to ask for copies of previous qualifying exams. The department usually keeps a
record of old exams (if they don’t, they should!). If not, ask the elder
graduate students. Unless they take back the exam questions, the more advanced
graduate students should have copies of the exam they sat for. Now work through
them. It may be useful to work in groups so that you all can agree on what the
correct solution is. There may be also books that publish old qualifying exam
questions - I’ve seen one for Princeton (with answers!). What this will do is
give you a flavor of the kinds of questions and the level of knowledge that you
are expected to have. But here’s a warning: qualifying exam committee changes
every year. So do NOT be surprised if you get blindsided and the exam looks
nowhere near what it looked like in previous years. It totally depends on who
is in the committee and what they wish to ask. This is where having an
eccentric faculty member in the exam committee is not to your advantage.
Fifth, how do they determine who passes and who doesn’t? From
what I’ve seen, schools have done both curving the results, or have a fixed
exam score as the passing mark. However, this is only a guess on my part,
because most schools do not tell you before hand (or even after) how this is
done. Sometime this even change from year to year. I have only heard unofficial
remarks on how the cut-off was set. So I have no inside information on this
one.... yet!
Finally, the worse thing you can do to yourself is worry
yourself to death! Granted, this is probably the biggest obstacle you will ever
face in your graduate studies. However, people DO pass the exam, ordinary people
like you and me, and not superhuman geniuses. What you need to do is focus your
life on the exam, devise a systematic study approach, and cover the things that
you know that you must know cold. Again, get a study partner who is in the same
boat as you are. Split the exam questions so that you two can cover a larger
scope, and discuss the solution. I think most students who passed the
qualifying exam did this (I certainly did). And try not to lose your sanity.
Get enough sleep, eat properly, and take care of your health. You (both your
mind and your body) will need to be at your best when you enter the examination
hall.
Part X:
Choosing a Research area and an advisor
In the previous part, I described the trials and tribulations
of going through the qualifying exam that almost all graduate physics students
have to go through. In this part, we will assume that you got through that very
difficult part of your graduate program and now ready to do some serious, real
physics work - choosing a research area and an advisor.
I neglected to mention last time that when you first enter
the graduate program, very often, you are assigned a faculty member at random
to advice you on what you need to do the first year or two before you actually
choose an area of specialization. This is because most physics students will be
taking roughly similar classes that are part of the required set. Your initial
advisor can be helpful in determining if you need to do a refresher course in
advanced undergraduate classes to prepare you for the qualifier. In any case,
there’s a good chance that you will not maintain the same advisor once you
decided to specialize in a particular field of physics.
So now what happens after you pass through your qualifier? If
you’re lucky (or stubborn), you would have an idea of an area of physics to go
into. In many large schools, there usually is more than one faculty member
working in that area. If not, then do what I did - shop around. Start with the
department’s graduate program description. Figure out who is doing what. Then
ask other graduate students, especially the senior ones, what so-and-so is
doing, if he/she has research grant money, etc. I will give you my criteria on
choosing an advisor:
1. And obvious one, is he/she knowledgable or a well-known
expert in that field. This is a given, but you’d be surprise how there are
faculty members who are clueless in the latest development in a field of study.
This is especially true of he/she doesn’t have research fundings and thus, do
not often travel to attend conferences, etc.
2. Is that person available for easy contact? This may be
surprising but consider the fact that many research projects requires one’s
presence elsewhere, even out of the country. There is no point in choosing
someone well-known, and have that person not available often for you to talk
to. Worse still, some time you are assigned to a post- doc to supervise your
work. This may or may not be a bad thing, but you should at least be aware that
this is what is going to happen before you go into it.
3. But most importantly (at least in my book), can you get
along with this person. I have seen way too many sad situations where the
mentor and the student are simply either miscommunicating with each other, do
not understand each other, or simply cannot get along. This will make for a
hellish experience and I have never seen anything good coming out of such a
thing.
Choosing an advisor is the next most important task you have
to do after your qualifier. This is the person who might determine your future,
and certainly your professional future. An excellent advisor will not only
advise you on the official requirements that you must complete for graduation,
but also train you to become a good physicist. Such training are not covered in
the school’s bulletin or official requirements. Yet, these are the stuff that
could be more important for your future as a physicist. Your advisor needs to
tell you the state of the knowledge in that field of study so that the two of
you can decide on a particular work that you can do that will become your
research dissertation. He/she needs to make sure you start to establish your
reputation by making sure you get to publish a few papers in respected physics
journals. And as important, he/she will make you attend and present your work
at various physics conferences so that you acquire the ability to speak in
front your peers and experts in the field. This will also serve to give you
visibility to others in the same field, gives you the opportunity to know who’s
who in your field, and make contacts. Never, ever underestimate the benefits
professional contacts - you will come to value those if you continue in
physics.
So if your advisor cares for your development as a physicist,
he/she will take steps to ensure that you will have such an experience.
There is one thing that I should also mention : pedigree.
Having a very well-known physicist as an advisor often can play a big role in
one’s future. For example, as far as I can remember, practically all of Phil
Anderson’s graduate students at Princeton went on to hold prestigious faculty
positions at prominent schools. The same can be said with a number of other
famous physicists. Of course, these people get to choose the cream-of-the-crop
candidates in the first place, so that already ensure that these students are
some of the best minds there are. It is why many students clamor for well-known
physicist, because in the ensuing competition for post-doc and employment, who
your advisor was can be the tie-breaker. My personal observation on this is
that this is more prevalent in theoretical physics than in experimental
physics. This is because even someone from a small, less well-known school can
make a big impact in experimental work, especially if there’s access to either
a large facility, or a Nat’l Lab. This occurs less often in theoretical
physics, and usually well-funded theoretical programs are often found centered
around well-known theorists.
In the next installment, we’ll go over the daily grind of
doing graduate research work.
Part XI:
Initiating Research Work
It has been a while since the last installment of this
series, so let’s recap on where you are right now. You should already made a
choice on the physics subject area that you want to work in, and you have
picked an advisor who will be (i) supervising your Ph.D research work (ii) the
chairperson of your thesis committee.
We will now be in the ”meat” of the whole thing. This is
where most physics students entering college have wanted to be - doing
research-front work in an area that one has picked, and hopefully, has an acute
interest in. Since this is such an important and major part of your Ph.D
program, I will devote several chapters to this. I will also describe this from
the point of view of someone who worked as an experimentalist, so some of the
advice being given tend to be more applicable to experimentalists than to
theorists. But in general, most of the generic events and steps tend to be
quite similar.
The first thing you have to get rid of is the notion that doing
research work is ”glamorous”, exciting, 30-thrills-a-minute type of work.
Nothing could be further than that. A lot of time, you will be sitting on your
rear end, waiting for something to either occur, or finished. Sometime it
requires taking a graveyard shift, late at night. Often, you have to do
physical labor work, crawling under things, doing repairs, etc. Or, you are
sitting in front of a computer monitor at 3 AM trying to find the bug in your
codes. I’m telling you all this now to make sure you do not go into this with
the wrong set of misconceptions. While doing research work CAN be exciting and
fascinating, most of the time, it can be downright boring. So be prepared for
such things and adjust.
One of the things that one MUST do as soon as one selects an
area of study is to figure out the STATE OF KNOWLEDGE of that field. You need
to be aware of what is currently known, what is being actively studied, what
are the ”hot news”, who are the BIG names, and who’s doing what to whom. What
this means is that you may end up spending a considerable portion of your time
doing nothing but reading tons and tons of papers and journals. Often, you
start reading a paper, and then discover that you need to look at the reference
being cited in that paper. So you get that reference and it turns out you need
another paper or two being cited there! It’s a chain of events that can
sometime be quite frustrating, but it is a necessary part of trying to be up to
date on the state of knowledge in that field. I certainly know that when I
started my Ph.D research work, I spent on average 30% of my time during the
first 3 months or so reading everything I could get my hands on about the field
that I’ve chosen.
You need to know the state of knowledge of the field for a
number of reasons:
(i) you do not want to replicate what has already been done
(unless you think there’s something more to be done and that somebody missed
something)
(iii) you need to be aware of what area is the ”hot” topic,
and who is working in this topic. Something that is hot tends to get funding.
Your advisor may have a specific project in mind for you to
work on, or you and him/her have already agreed on what you will do, but you
still need a broader perspective on what is going on in the field that you have
selected. So even though you have decided that you want to study tunnelling
spectroscopy of superconductors for example, it doesn’t mean that you shouldn’t
be paying attention to the progress in the field of superconductivity in
general. You must start to be aware of the whole area of study that, more often
than not, have a direct impact on your work.
So be prepared to do a lot of reading and catching up. Don’t
be surprised if you end up spending up to half of your time doing nothing but
reading journal papers. This is effort you have to put in to prepare you for
the next step in your research work.
Part XII:
Research work and The Lab Book
Now where were we? Oh yes! You have now started with your
actual research work. You and your adviser have agreed on at least the general
type of area you will be working in and you have started to do a lot of
literature search of what is going on in that field, what is known, what is
unknown, what are the hot areas of study, etc. One important note here is that
to NOT be rigid in one particular area especially during the early years of
your project. In many cases, you and your adviser are still exploring an area
of study before both of you narrow down into the exact, specific area that will
eventually end up as your thesis research work. The best thing you can do right
now is to gain as wide of a knowledge base as possible. If you are working in
tunnelling spectroscopy, don’t try to limit yourself with just one family of
material. If a wide range of material is available and open for study, go for
it. You’d be surprise how something that may appear at first to not be
important, might turn out otherwise later on. Trust me on this.
What I would like to stress in this installment of this
series in the ”ethics” of doing research work. I will illustrate this from the
point of view of an experimentalist, but there are elements here that are also
relevant to theorists. In general, the ethical practice of doing research
applies to every field of science, so use what I will be describing as a ”case
study” and apply it appropriately to you line of work/study.
When I used to conduct physics laboratory session for
undergraduates, one of the practice I tried to instill onto my students was the
writing of everything they did and observed during the experiment into a
laboratory book. I want them to acquire the skill of writing these observations
clearly, to write down what they are doing, why they are doing it, and their
observations, even to the extend of writing down what they are thinking
regarding the data they collected. Was there something peculiar? Are there
something not working correctly? Are the data consistent with something else?
Are things just making no sense? Are the equipments malfunctioning or not
giving the expected results?
Not only that, I wanted them to write all of these in INK,
and I prohibited any ”erasing” of anything they wrote in their lab book. If
they think they made a mistake, just cancel it out, but leave it legible. Now
was I being psychotic for insisting things like this? I hope not, and I will
explain why. In doing research work, it is imperative that you record almost
everything clearly. In most cases, it is for your own good, so that if and when
you need to figure out what you did later on, you just don’t have to rely on
your memory, especially if you want to know what you did then, what parameters
were used to make such a measurement, etc. However, there is also another
important reason for such a record. While this doesn’t occur very often, when it
does, you’ll be glad you have such a record. In certain cases where it is
necessary to establish who did what, and when, your lab book is often used as
official evidence, especially in the court of law. If you work for an
institution, be it governmental, academic, or commercial, the lab book is the
property of that institution (i.e. you can’t take it with you when you no
longer work for that institution). If there are disputes, questions, issues,
etc. arising out of your work, your lab or record book is the definitive
evidence in such matter.
This is why you should always write your entries with a date
and in ink. You want as permanent of a record as possible. In addition, if
someone else comes in and want to reproduce your work, this is the ultimate
source to see what was done exactly.
We have seen cases where improper or lack of record-keeping
created serious consequences. The infamous Schon debacle at Bell Labs is the
most recent example. The fact that he could not show any written record of his experiments
(he could not produce any lab books of his experiments) created a serious doubt
on the validity of his work. This resulted in his fall into disgrace - he was
fired from Bell labs, a large portion of his published work were retracted, and
his alma mater withdrew the granting of his Ph.D degree.
Now granted that things like this do not occur very often
(luckily), but many smaller forms of double-checking do. It is never too early
to make sure you keep a careful record of what you are doing. Even if you are a
theorist, it is always a good idea to make sure your work and ideas are kept in
a record book. Not only will this allow you to go back and remember what you
did (or why you were doing it), but it allows others to understand what you did
and when you did it. Besides, if you win the Nobel Prize and become a
world-famous physicist, they’ll want your doodling to be put in a museum or
some place! :)
Moral of the story: keep as complete of a record of your
research work as possible.
ADDENDUM: I know I sometime have an uncanny timing, but this
is ridiculous!
In the just released online edition of Nature (22 September
2005), a news report about the embattled japanese researcher has indicated that
his lack of record-keeping is casting doubt on his work. The report says that
"A respected
Japanese scientist who failed to produce laboratory notebooks confirming his
published results now faces a furore over the credibility of his findings. On
13 September, the University of Tokyo’s School of Engineering held a press
conference to say that Kazunari Taira, a professor at the school who
specializes in RNA research, had not provided raw data to verify his team’s
results. The RNA Society of Japan has also questioned some of Taira’s methods.”
So kids, I’m NOT making this up when I say that you’d better
start learning to write everything down on paper when you are doing something
related to your studies/work. It may be a boring and tedious task, but when
stuff happens, you’ll be sorry that you didn’t.
Part XIII:
Publishing in a Physics Journal
At this stage, you are well into your Ph.D research work, and
depending on what area of physics you are in, you may already start producing
new results. This next part of the series will cover an extremely important aspect
of your graduate work that is typically not covered (some time not even
required) in your graduate school requirement. It is the aspect of publicizing
your work. Your graduate school curriculum will not have much, if any, on this.
Yet, as a physicist, this is one of the most important aspect of your
profession.
There are two major means by which physicists publicize and
report their work - via physics journals, and via presentation at physics
conferences. In this chapter, I will first cover journal publications and will
reserve conference presentation to the next chapter.
If you have ventured into your library, you will notice that
there are hundreds of physics-related journals, or journals that accept physics
papers. While a lot of these journals tend to specialize in a particular area
of physics, there are three journals that are considered to be very prestigious
for physics publications: Nature, Science, and the Physical Review Letters.
Nature and Science publishes science papers in general, not
just physics. They also tend to be extremely selective on what appears on their
pages. One criteria is that the work being reported must have widespread appeal
or importance, not just within the confines of that particular area of study.
So things that claim a discovery of never- observed phenomenon, such as
fermionic condensates, or apparent superluminal group velocity propagation, are
the types that the editors of these journals look for. This criteria adds to
the difficulty in getting published in these journals. In many cases,
manuscripts submitted to these journals do not even get passed the editors.
They are often rejected before the manuscripts reach the referees. Phys. Rev.
Lett. publish exclusively physics and physics-related papers. Because of this, they
tend to publish more physics papers per week than Science and Nature combine.
But they are no less difficult to get through. The editors, while still more
forgiving than the editors of Science and Nature, will ramp up their review of
the submitted manuscripts and will be more discriminating of what they sent to
their reviewers. Now unlike Science and Nature, Phys. Rev. Lett. has a page
limit to 4 typeset pages. So articles submitted to be published in this journal
will have to be able to convey their messages within that limit.
I will now describe the typical process that one goes through
in trying to get one’s work published in a physics journal. Since the largest
”family” of physics journals is the Physical Review series, I will use the
process of getting published in one of these journals as a concrete example.
However, the method is quite generic and can be adapted to any reputable
physics journal.
To publish a work, you need to be very clear what is the
single, most important message you are trying to get across. Once you, your
adviser, and your collaborators agree on that message, it is time to figure out
how to convey that in the most effective and CONVINCING manner. Figure out what
results must be included, what data must be presented, what figures are needed,
and how to show all of these in the clearest possible manner. There is no point
in having an important thing to say, but saying it in a confusing, obtuse
manner that makes it difficult to understand. Your message will tend to be
lost, not only to the reader, but more importantly, to the people who will
review your work. This is a formula for a rejection.
Once you have decided what to present, you will have to
decide where you might submit such a work. Note that in many instances, this is
often decided later, after the manuscript is written. However, more often than
not, your adviser and collaborators will know how significant the work is, and
will already have some idea in mind on which journal to aim for. If this is the
case, go to the journal website, and look for instructions to the authors. The
journal will have a clear set of guidelines on the format that it will accept
for submission. Often, they also will have a template that one can use as a
guide. This is especially helpful because it can allow you to typeset your
manuscript to look like what it would appear in the final print. It allows you
to judge the length of your paper, which is important for journals like Phys.
Rev. Lett. that has a page limit.
It goes without saying that you should already be familiar
with the journal you want to submit to. All that literature search that you did
while trying to familiarize yourself with the field of study that you went into
(see an earlier So You Want To Be A Physicist chapter) should make you
comfortable with many physics journals. So look at a paper from that journal
and pay attention to how the authors present their work. This will be a very
good illustration of what works.
Now that you know what to write, where to send it to, and how
to present it, it is time to write. This is where you will regret all those
complaints you had in your writing classes. It is most likely that if you were
the one who did the significant portion of the work that you will be the one to
write it. All journals require that the manuscript requires an abstract, an
introduction, the body of the work, and possibly a conclusion or summary at the
end. This is true even if there are no structured sections that is part of the
style given by the journal. Such things are helpful for people who want to do a
quick browse of a paper. When you have understood this, then write! Keep in
mind one unavoidable fact: your manuscript WILL go through several iterations
before everyone involves will agree to it. This happens to everyone, no matter
how many times we write and publish our papers. You will learn that different
people prefer certain phrases, emphasis, style, etc. Do not be discouraged by
this. Discuss why you think certain things should be said in certain ways
(example: Why should you not say ”this results proves that...” rather than ”..
this result is consistent with...”). You will learn how certain words and
phrases can cause problems during the review process that you may not
anticipate. These are all things that you will pick up along the way as you
write your first, and subsequent papers. There’s no way to learn other than by
doing it yourself.
Note that it is not unusual for a number of people to share
writing the manuscript. Maybe someone will write one part of it, and you write
another part, while your adviser writes the rest. However, what is more common
is to have just one person starting out by writing the first version, and then
it gets passed around to a number of people for corrections, additions,
modifications, etc. I find this to be more efficient than the first, and the
paper tends to at least be more coherent as a whole rather than a mishmash of
different styles.
Physics papers tend to have figures, especially graphs. You
need to have a good graphing software. This goes without saying. You will also
need to be aware that the figures tend to be rather small when it appears in
print. So make sure your letters and numbers will be legible when they are
compressed to the typical size of that journal. This is where having a template
from the journal and inserting the figures yourself can be useful. You can see
how it may appear in the end and see for yourself if you need to make certain
things bigger/clearer. See if your figures have too much clutter that someone
who is not familiar with your work will find it difficult to decipher what you
are trying to convey. Always keep in mind that you are trying to convey some
information to someone who is not familiar with what you are doing. Being brief
and right to the point are always important.
Unless you are Albert Einstein, your paper will have
references. Again, look at a paper from that journal to see the format on how
references are cited. However, more importantly, you need to make sure you did
not miss an important work that needs to be cited. This is where your adviser
will be useful. He/she will probably know what you should include in your
citations. If you don’t, don’t be surprised if the referee will come back and
ask you why you missed so- and-so. This is where, if you have followed the
earlier advice on doing an extensive literature search, you would have known
who did what when and why such a thing needs to be included. Be aware that you
can ruffle a few feathers if you left out something you should have cited. The
people who are also in your field will tend to remember that you neglected to
cite their work when it was appropriate to do so. They might just do the same
when it is their turn. You do not want to put the wrong foot out especially
when you’re just starting out. So do your homework.
Who to list as the authors on your manuscript is initially
the decision of your supervisor/adviser. If you did the work, and are the
primary writer, you should be listed as the first author. However, this rule is
not followed all the time. Sometime, unfortunately, it is a matter of politics
on who gets listed, and where. Typically, those who did the most work gets
listed first, and the list follows on the degree of contribution to that work.
[Addendum to the
original article - In experimental high energy physics papers, the number of
people participating in the work can be HUGE, often more than a hundred. It is
usually difficult to pick a single person who did more work than others in such
a collaboration. So for such papers, the authors are listed alphabatically
using their last names.]
I suppose this is also the place to tell you that if you do
not know how to write LaTex codes, this is the time to learn. The Physical
Review journals, especially, prefer LaTex format as the submission document,
while the figures have to be in postscript (PS) or encapsulated postscript
(EPS) files. There are several graphical Tex editors that allows you to type
your document and mathematical equations very easily (the FULL version of
MathType Equation Editor that comes with Word can convert equations into LaTex
codes). So you don’t really have to learn that much. Note that if you submit
your documents in the format that they prefer, you get a discounted publication
fees for Physical Review journals (more on this later).
When you are ready with a final manuscript, it’s time to
submit. All of the major journals now prefer electronic submission. Go to the
journal’s website for explicit instructions. Once you have submitted your
manuscript, you will be given a manuscript or submission code. This is the
reference number you and the editors refer to whenever there’s communications
between the two parties. It is also the code that the referees are given if and
when your manuscript is evaluated. The editors will determine if your
manuscript satisfies the standard requirement for the journal. If it does, it
will be submitted to either one, or more than one referees. For journals such
as Science, Nature, and Phys. Rev. Lett., 2 referees are normal, 3 is not
unusual, and 4 or 5 is not unheard of. These referees are anonymous to you, the
author. On the Physical Review author’s webpage, you can actually track the
progress of your manuscript and at what stage it is in. So you can tell if it
has been sent to the referees, and when the referees have responded back to the
editors.
The responses from the referees determine the next step that
you have to make. There are several possible outcomes:
(i) ALL the referees gives a positive review and agree that
your manuscript deserves to be published. You may need to make minor changes,
but overall, it is accepted. Then congratulations! The editors will give you
instructions on what you need to do if you have to make minor modifications,
etc. But don’t get used to this. This doesn’t occur often. More likely on what
would happen is option (ii)
(ii) which is one referee has a set of comments/questions,
but gives a positive review, while the other referee doesn’t give a positive
review and also have comments/questions. When this occur, you will have a
chance to submit a rebuttal, and make changes to your manuscript to take into
account the referees’ comments, suggestions, etc. I strongly suggest you make a
much of an attempt to accommodate the referees’ suggestions. It will shows that
you respect their opinions and may make the 2nd round of review smoother. You
then resubmit your manuscript and usually the same referees will get to review
it again, unless one or more of the referees refuse to review it again for some
reason (this has happened before to yours truly). If all goes well, you’ll get
all positive review and your paper is accepted. But it can happen that even
after the 2nd round, you still do not get a unanimous approval. When this
occurs, you need to pay close attention to the journal’s policy. Most journals
would view this as an automatic rejection. You might as well try to submit your
manuscript to another journal. Some journals, such as the Physical Review
journals, will give you the final option of appealing to the associate editor.
You’d better have an extremely good reason to do this because it will again
take some time for the process to occur and you really, really want to get your
work published in that particular journal.
(iii) you get all negative reviews on the first round. This
again will usually result in an automatic rejection. You can appeal or send in
a rebuttal, but there’s a good chance you won’t get through if the editors see
that all the referees agree that it shouldn’t be published. If this occurs, my
advice is to go to a different journal.
Writing papers is a necessary part of your career as a
physicist. Many started out with a series of publications by the time they
completed their Ph.D work. You need to established your reputation by the time
you graduate, to make your credentials stronger in your search for
post-doctoral position or employment. Your adviser should help you in making
sure you have a few publications under your belt by the time you are done. So
such an exercise is a necessary practice in becoming a physicist. You should
not be satisfied with your graduate work until you have at least a publication
to your name.
Part XIV:
Oral Presentations
I mentioned earlier that there are two ways for physicists to
communicate their work. The first is via publications in peer-reviewed
journals. I have covered this in the last chapter of this series. The second,
which we will cover here, is through oral presentations at various scientific
conferences.
Each year, there are scientfic conferences, workshops, etc.
in various parts of the world, and for various scientific disciplines. In
physics, there are many such conferences, often specific to a particular area
of physics. However, there are two major physics conferences that are held
yearly and typically receive the largest yearly attendence by physicsts from
all over the world - The American Physical Society (APS) March Meeting, and the
APS April Meeting. The March Meeting is typically the largest yearly physics
conference, with attendence in excess of 5000. In fact, the APS Centenial
meeting in 1999 in Atlanta brought more than 11,000 attendees, including all
the living Nobel Laureates in Physics and Chemistry. The subject matter covered
in these two conferences differ, and you are recommended to go to the APS
website for a listing of all the various divisions and when they meet (www.aps.org).
There are two major reasons why a physicist would attend a
physics conference. The first is of course the need to present one's work.
While printed publications can also accomplish that, there is nothing that
beats a human interaction in conveying an idea. It works both way - the
presenter can present his/her idea in a clearer fashion, and the listener gets
a more detailed or dynamic presentation, allowing for possible questions of
things that aren't that clear. And let's face it, there is a huge amount of
papers being published. Your work can often be overlooked. This is one way to
make sure people pay attention, and allows you to argue on its importance to
the field of study. Sometime, you do have to trumpet your own horn.
The second major reason is the interaction with others who
are your peers, or will be your peers. Presenting a talk at a physics
conferences is one way for you to get people in your field to recognize you.
Chances are, when you are done with your studies, these might be the very same
people who might be the ones you seek employment from. It is never too early to
make a name for yourself, and for people to start recognizing your name and
your face (not to mention, your ability). Do not underestimate the importance
of making contacts.
Furthermore, in terms of the workings of physics, you will be
very surprised to learn that a lot of important insight and progress are often
made at these conferences, especially when you're sitting down with someone
discussing something during a coffee break, or simply standing outside the
conference hall. I've lost count how many important ideas that I've gathered
simply by discussing things with others. The majority of us do not, and cannot,
work in isolation. These conferences offers us the latest news on who is doing
what, the latest results that may have not yet even been published, and simply
the ability to judge the "winds of change" on what might be the next
important direction where the field is heading. In fast moving fields such as
superconductivity, by the time one reads a published paper in a journal, that
particular issue may no longer be the "hot" topic. These conferences
can truly give you a gauge on what the community is heading to, and what is
considered to be the important topics. You may not want to go along with the
trend, but at least you know what it is. The point here is that there's a lot
of physics that is done at one of these conferences, and often there are many
new stuff that you haven't heard about.
OK, now that I've hopefully convinced you on the importance
of attending such a conference, how does one prepare for it? Often, your
adviser will be the one suggesting that you attend one of these, at least a
couple before you graduate, to present your work. So hopefully he or she will
also have a plan to get you ready for it. This could be done by first
discussing in exact detail what you should be presenting, what should be on
your transparencies or viewgraphs, etc. A lot of advisers would ask that you do
a practice run. He or she will either have you present it in front of him/her,
or call on other graduate students to attend your practice and try to ask you
all kinds of questions. This will allow you to see if there's any part of your
presentation that is weak or unclear, and also give you an idea on how long
your presentation is. These conferences some time can have tight time limit,
and you need to make sure you are not running long and have to omit important
part of your work.
There are many resources you can read on making a good
presentation. A polished, well-done presentation is a joy to sit through. A
poorly thought of presentation is a bedtime story waiting to happen, and a torture
to sit through. While you may not care if people are bored or not, my
philosophy has always been that if I have to do something, I might as well do
it as best as I can. So the following is my suggestion on how you should
organize your talk, based on my experience at giving and sitting through many
of these throughout my career.
1. Organize your thought. Sit down, and figure out the
sequence of items that you will be presenting. Make sure that it is clear
enough that someone who doesn't quite know your field might have a chance to
understand. But here, you have to know the kind of audience you might be
facing. If you are presenting this at a conference specific to your area of
study, then you can skip a lot of background information that the audience already
know. On the other hand, if you are presenting this to a mix audience, then
expect to put a little more background info on the physics and maybe even the
technique involved. From that point, look at the logical and sequential flow of
the info that you will be presenting. Is there too abrupt of a jump from one
viewgraphs to the next? Can one see a connection from one to the other?
2. Keep in mind that out of sight is out of mind. You
shouldn't expect too much that the audience will remember previous viewgraphs
that have gone passed them. So your viewgraphs should try to contain as much
relevant information as possible. However, the trap here is that you may make
it too full and too convoluted that it is difficult to read. What you need to
keep in mind that (i) lots of equations don't help, unless you are a theorist
and presenting a talk to only theorists (ii) pictures and graphs are good, IF
they are properly annotated. Never, ever, present a graph or data without
clearly indicating on the viewgraph itself what it is, what the quantity
represents, and all the pertinent information. (iii) A very concise but brief
description in words of important points you want to make on that viewgraphs.
Do NOT, I repeat, do not write lines and lines, or paragraphs of descriptions.
If the audience is reading this, chances are, they are not listening to you. So
why are you even there? Besides, it is annoying having to read a lot of things
on a screen - one can get that by reading a paper. So limit only to the
important points that you want to get across. This includes the description of
the pictures or graphs that are shown, and any relevant parameters. For
example, if there are two different graphs and you are trying to compare the
two, write in point form their similarities and differences. This accomplishes
two things: you can look at the screen itself and be reminded of the things you
are trying to convey and can emphasize them verbally, and the audience can read
them and along with your oral presentation, be reinforced on the important
point that you are trying to get across. This is also helpful if you are not a
native English speaker and your English pronunciation is weak. Having the
points written on the screen can still allow the audience to have an idea what
you are trying to say. But again, do not write lengthy prose and expect the
audience to have the patience to read it.
3. Here's a mistake that I see many presenters make - they
are OBLIVIOUS to the audience. What this mean is that either the presenter
spent most of his/her presentation talking to the screen and not even looking
at the audience, or the presenter did not pay attention to the audience
reaction. While an oral presentation is you standing in front of people and
giving a talk, it really is a two-way street. You have to judge if what you are
saying is getting though (after all, that's the reason you are there). Look at
the facial expression of some of the audience members. Do you see a puzzled
look? Do you see a bored look? Is the senior physicist nodding his head off to
sleep and about to fall off his chair at any moment? It allows you to judge if
you have time to go back and re-emphasize certain points that may be unclear.
Of course, you do this after you are quite skillful at doing one of these presentations
AND you have the luxury of time management. But it is still important to judge
how your audience is reacting. A good presenter can tell if he or she needs to
make the presentation clearer and not just stick to the "script".
4. Learn from other presenters. By now you should have
already attended several talks, department colloquium, seminars, etc. Learn
from them what to do and what NOT to do. Start paying attention to the slides
and viewgraphs that you are seeing. Is that clear, or not very clear? Is it too
packed with info that the message is lost? Is the person going way too fast
that you don't have time to properly absorbed what is being said?
5. Timing and pace are very crucial. Figure out how much time
you have. This will limit on the number of viewgraphs you can have. Most people
will tell you that you estimate that you will spend 1 minute per viewgraphs. So
this means that if you are given 20 minutes to talk, you should have 20
viewgraphs. I personally find that very unrealistic. I would do LESS number of
viewgraphs. Chances are, you will have to do quite a bit of explaining, and you
need to allow yourself some margin for error in case someone interrupts you
during your talk to ask a question. It also can allow you to go back to an
earlier viewgraphs if you need to and explain some things. In my book, it is
better to end early than to end too long. It allows for more time for question
and answer. Also, what many people do (and I do this often), is that you have
extra viewgraphs in case you do have time left. These viewgraphs should be
considered as "bonus", in that you don't really have to include them
if you run long or on time, but in case you do have time, you can include them.
6. Don't expect the audience to remember what you said, at
least not everything. This is where trying to emphasize one, or two points, is
important. Try to sum up the "moral of the story" at the very end, to
make sure they are aware that this is what you are trying to convey, and why it
is important. You should try to make sure that you leave them with at least one
thing that they remember. That's all you should expect.
7. Practice, practice, practice. Your first few times at
doing this may be nerve-wrecking, and may not even go well. Unfortunately, the
only way to do this well is to do this many times. It is a skill that can only
be acquired through practice. You will learn what works and what doesn't.
By the time you are done with your graduate work, you should
have presented at least once to an audience of professional physicists in your
field of study. You should not be happy with your graduate training if you
haven't done so. If you intend to pursue a career in physics, chances are, your
employer would want you to prove that you have the ability to talk in front of
an audence as one of your communication skills (read the physics job
advertisements if you need any more convincing). Conveying the importance of
your work in front of an audience, be it people from a funding agency, other
physicists, or just the general public, is a necessary skill as a physicist.
You should have such skill by the time you are done with your Ph.D training.
Part XIII:
Publishing in a Physics Journal (Addendum)
When I first wrote this part of the series, I wasn't quite
sure if I should include this. for most people submitting to most of the
physics journals, this isn't an issue. But considering the number of very
bright students we have on here, inevitably some of you might consider
submitting a manuscript to Nature or Science. When you do that, then you will
start learning of the meaning of the word "embargo".
First, a bit of background. Many people are familiar with the
electronic e-print ArXiv repository. Many scientists upload their preprints
there almost at the same time they submitted their manuscript to a journal. It
is also a common practice that scientists discuss their work either via
presenting it in a talk at a seminar or conference, or by putting it up
somewhere on a webpage.
Most journals have a "first right of publication"
policy. This means that the work being publish must not have appeared anywhere
else. Additionally, Nature and Science have an embargo policy. To many people,
this policy means that a submitted work to Science or Nature cannot be
distributed or discussed in any form or means, including uploading it onto an
e-print server. Such distribution will cause an automatic disqualification from
being considered for publication.
Having gone through the process of submitting to Science and
Nature, I have a bit of first-hand experience in dealing with this. I have also
talked to one of Nature's editors regarding such a policy and obtained a more
definite clarification on this.
First of all, this is what you can find on Nature's webpage
regarding their embargo policy (this is only a part of what you can find
there):
"Nature does not wish
to hinder communication between scientists. For that reason, different embargo
guidelines apply to work that has been discussed at a conference or displayed
on a preprint server and picked up by the media as a result. (Neither
conference presentations nor posting on recognized preprint servers constitute
prior publication.)
Our guidelines for authors
and potential authors in such circumstances are clear-cut in principle:
communicate with other researchers as much as you wish, but do not encourage
premature publication by discussion with the press (beyond a formal
presentation, if at a conference)."
What this means is that there is no restrictions in
scientific discussions of a submitted manuscript. This includes scientific
presentation at conferences, uploading the manuscript on ArXiv, etc. What is
not allowed is a discussion with the media or journalists until 1-week before
the publication of the work. However, and this is something that the Nature
editor told me, if during your scientific discussion or presentation, another
media decided to use it and report it, then you have inadvertently violated the
embargo policy, and Nature has the right to refuse publication. This has
happened before, and I have seen other media reporting on an ArXiv paper that
hasn't been published yet. If that paper was meant for Nature or Science, such
reporting would have disqualified that paper.
So for many people, if they have submitted to Nature or
Science, they tend to wait before uploading the manuscript on ArXiv, or even
presenting a partial result at a scientific conference. While violation of the
embargo policy resulting in disqualification is rather rare, many people tend
to take the more cautious route and wait a month or two before reporting the
complete work.
Part XIV:
Oral Presentations - Addendum
I'll try not to make a habit out of this, but I believe
there's something to add to this chapter of the series.
In Part XIV, I mentioned the APS Meetings - March and April -
which typically tend to be the largest yearly gathering of physicists. They
both covered different areas of physics, i.e. different divisions under the APS
wing would meet in March and in April. The March Meeting tends to be the
condensed matter, material science, atomic/molecular physics, etc.. whereas the
April Meeting covers particle, nuclear, astrophysics, etc. I have not attended
the April Meeting, but I have attended the March Meeting numerous times and
have given a talk at all but one of the meetings that I attended. Based on what
I have been told, the April meeting, while smaller than the March Meeting,
follows roughly the same format as the March meeting. So this description
covers both.
The reason why I am going to spend time describing these
conferences is because for most physics graduate students, one of these
meetings will probably be the conference where they cut their teeth at
presenting to people in their profession. Chances are, you will present your
first ever professional talk at one of these conferences. This is where you
will meet your peers, the people you have cited in your work, the people you
read about when you decided to go into your particular field, etc. And chances
are, this will be the time you will start to be known not just from your name,
but what you look like and how you interact. So rather than going into this
blindly, it might be useful to know a bit more of what goes on at one of these
meetings. Also, the March and April meetings are unlike other physics
conferences due to its size. So if you have attended other conferences, don't
be surprised if the March/April meetings appear a lot different.
The March Meeting is HUGE. With an attendance upwards of more
than 5000, and with almost every attendees presenting, the scientific program itself
used to be the size of 2 phonebooks! At any given time, there are at least 50
simultaneous sessions going. So out in the lobby and in the hallway, it can be
quite a zoo, but it is nevertheless a well-controlled chaos, with people
jumping in and out of one session into another.
If we neglect the special symposiums, there are 3 different
categories of presentations at the March Meeting: (i) invited talk (ii)
contributed talk (iii) poster session.
The invited talk is when you are invited by the organizing
committee to present your work. This can occur either by someone nominating you
to present your work, or someone in the committee notices an important work,
usually in scientific journals, and would like you or someone on the authors
list, to present the work. This is a very prestigious honor (I strongly suggest
you note this in your resume and if possible, save the invitation - trust me on
this, you'll thank me later). It means that your work was deemed important
enough and deserves to be invited to give a presentation on it at such a major
conference.
Now the invited talks can be presented in two types of
session. Typically, you may lead off a smaller session of the same subject
group and given maybe 20 minutes. Other people that follow you are those giving
contributed talks and have shorter time (more on this later). However, sometime
the conference committee may deem that a particular area or topic either
deserves its own plenary session, or that they have sent out invitations to a
number of people in the same subject area. In that case, a special plenary
session in a large conference hall is held and each speakers is given a longer
time to present their talk (typically 40 mins).
The contributed talk, on the other hand, can feel more like a
automated, production-line presentation. The majority of the talks at this
meeting is of this category. This is where you submit an abstract to the
conference for an oral presentation, and then you are assigned to a particular
session (usually with like-minded people in the same subject area). Everyone
who registers for the conference CAN present a contributed talk. You have 10
mins plus 2 minutes for question and answer before the next person comes up. So
things move very fast and the time is strictly adhere to. This is because in
the scientific program (the one that can be 2-phonebook thick) the time that
such-and-such talk will occur in a particular conference room is listed. This
allows for people who are jumping from one session to the next to know when
such-and-such talk will commence. Running long will mess things up, and the
chairperson has been instructed to be very strict with the timing.
[This brings up an unusual occurrence where in the case that
there's a missing presenter, the next person after this presenter still cannot
just walk up and do his/her presentation because that will throw off the
timing. His/her presentation has been scheduled for a particular time, and if
he/she goes early, someone who may have planned on being there at the start of
his/her talk may miss it. So what ends up happening is that people just sit
patiently in the room till it is time for the next presenter to begin. I have
never seen this occur in other conferences.]
Note that just because it is a contributed session doesn't
mean the talk isn't important. I think there's a rule that if you received an
invited talk one year, you cannot receive another one the following year (they
want to make sure no single person monopolize these things). There are still
important work and results being presented in these talks.
The last type of presentation is the poster session. What you
do here is present your work in a well-thought of poster that you put up on
boards. Depending on your subject matter, you will be assigned a location and a
date for your poster to be put up. People wonder through the poster hall
continuously during the session, and it is advisable that you (or one of the
people working in your group) be by your poster throughout the session. This
will allow people who have questions or comments to be able to talk to the
people who are responsible for your work. You'd be surprised how much valuable
information can be gathered from such conversations. It is also a good idea to
attach to the poster board any publications that the poster is based on. Many
people attach a large envelope containing copies of the paper for people to
take one if they wish. Again, it is a way to "advertise" your work.
For most graduate students going to one of these meetings for the first time,
they tend to be presenting posters, since it is less nerve-wrecking than doing
an oral presentation. This will give them a flavor of one of these meetings so
that next year, they'll know what to expect when they actually present a talk.
It is my personal opinion that if you are a physics graduate
student in an institution in the US, you should attend one of these meetings at
least once. If your adviser does not bring it up, ask. At some point, you will
have to produce an original work for your phd research, and this is what you
should present at one of these meetings. It is your best chance to meet other
physicists in your field. It is an opportunity not to be missed.
Part XV -
Writing Your Doctoral Thesis/Desertation
At this stage, you have performed your doctoral research
work, maybe even have published (or about to publish) a paper or two, and may
have presented your work at a physics conference. It is time for you to think
about finishing this part of your life. However, before you can do that, you
have a couple more obstacles to get through - writing your thesis/dessertation
and defending it. We will discuss the first one in this chapter.
You and your adviser should have narrowed down the main
points that you will need to cover in your thesis. More often than not, you
would have done more than you need during your graduate research work. It is
not unusual that a graduate student has studied a number of different areas
within his/her field of study, especially in the very beginning of his/her
research work. However, it doesn't mean that anything and everything need to be
included in the doctoral thesis. Your thesis must present a coherent research
work that you have accomplished that no one else has done. So you and your
adviser do need to be very clear on exactly what area that should be included,
and what shouldn't. Chances are, if you have published your work in a
peer-reviewed journal, the area being covered by that paper would qualify as
something that should be covered in your thesis.
Once you and your adviser have agreed on the general scope
that should be in your thesis, it is time for you to organize your thoughts and
figure out what to write. You should have plenty of practice already by now if
you have published a few papers already. So all the advice on writing a paper
applies here. Figure out the central points that you wish to convey and try to
make your point as direct and as clear as possible. Note also that depending on
your school's requirement, you may have to explore the background of the
issues/physics in general terms. This is because in many schools, your thesis
committee may comprise of not just individuals who are familiar with your field
of study, but also individuals from other fields or even other departments. So
pay attention to what needs to be covered based on what kind of thesis
committee that you will be facing.
When it comes to the actual writing process, this is where
you will need (i) your institution's thesis guidelines and (ii) copies of
thesis that have already been written. The first one should be available from
the graduate school program at your school. Read it carefully. It will tell you
a number of things you must follow, including (i) thesis formatting/typesetting
requirement (ii) the format and order of the thesis (iii) thesis committee
requirements. Pay attention to how your thesis should be written, especially in
terms of figures(*), captions, bibliography format, section titles, etc. In
some schools, they might even have a read-made template for you to use with
your favorite word processor (or even Tex editor) that can make your life
easier. Looking at older thesis from your department will give you specific
examples on what can and cannot be done. Chances are, your adviser will give
you examples of already-approved thesis, or you may even have been referring to
one already. So look at all of those as guides. Do not relegate this as
something trivial. Your thesis will be looked at by a thesis examiner, who can
and will reject it if it does not conform to the format required, and thereby
possibly delaying your graduation. Note also that in many schools, the graduate
program often has a short briefing on those who intend to submit their thesis
in that particular semester. This can be either a 1 hour class, or an
individual meeting with the thesis examiner. Make sure you attend this and be
aware of what is required.
How long a thesis should be is highly subjective. I've seen
advisers who don't care how long it is, while others who don't want it longer
than, say 150 pages. I'd say that it should be as long as it needs to be. Don't
ramble on and on and turn it into War and Peace, but you also do not want it to
be lacking in details, because these are the details that probably no one else
has worked on.
As you are writing it, pay attention to the deadlines that
you school has listed if you wish to graduate at the end of a particular year
or semester. This is very important, because missing it could mean that your
graduation will be delayed. If you wish to graduate at the end of the semester,
look at first and foremost, when your thesis is due for submission to the
graduate program. Now work backwards. Move that date two weeks earlier. Why?
This is because you want to be sure that if there's unanticipated problems with
your thesis, that there's plenty of time to correct it. So that two-weeks-early
date should be the latest you should hand it in. Note that this is your planned
FINAL SUBMISSION. This should NOT be the first time you have shown your thesis
to the thesis examiner. So you should plan on a meeting with the thesis
examiner even earlier than this two-weeks-early date. For the sake of
illustration, let's put this as 4 week's early than the final deadline. So 4
week's before the graduate school's published deadline, you should meet the
thesis examiner for the very first examination of your thesis. There's a very
good chance that you will need to make modifications, hopefully minor ones if
you have paid close attention to the required format. This will give you two
weeks left to make the correction and to make your final submission two weeks
before the graduate school deadline. Confusing? Hopefully, not.
So it does mean that if you wish to have a completed form 4
weeks before the hard deadline, you need to already have done your thesis
defense by then. This means you have incorporated comments you received during
your thesis defense into your written thesis, AND have received final approval
from all your thesis committee members [thesis defense process will be
discussed in the next chapter]. This, again takes time. This means that you
should schedule your thesis defense at least 2 months before the graduate
school's hard deadline (I would even suggest a little longer). This will give
you time to make changes, to send the corrected version to all the committee
members, to allow for more changes, and then to get their approval. These
things can be time consuming, trust me!
So if you have to schedule your thesis defense 2 months
before the hard deadline, then you should need to contact your thesis committee
members before then to schedule your defense. Sometime it can be a chore to get
a suitable date, so plan ahead. It also means that you now have a good idea on
when you should be done with the writing of your thesis! So pay attention to
that date! It is the clearest indicator that, if you want to graduate at the
end of that semester, you must be done writing by that date! Your thesis
committee members will need to have your thesis in their hands at least a week before
you can call for your defense. So if you work this backwards again, you should
have a good idea of the date where you should be all done. Knowing this, it
will guide you on when you should start writing your thesis, and how fast you
have to work to be done by that date.
Note that, depending on how involved your adviser wants to
be, he or she may want to see the progress of your thesis as you are writing
it. You may also want to consult with him/her along the way as you are
progressing. This may save major revisions afterwards especially if both you
and your adviser don't see eye-to-eye. Fine as this may be, you should always
keep in mind that the thesis should be your own work and not expect your
adviser or anyone else to write parts of it for you.
Hopefully, this guide will give you an idea on what to
expect, especially on time management. The last thing you want to have is sleep
deprivation while writing your thesis simply because of things you haven't
anticipated, or you didn't give yourself ample time.
(*) The issue on how figures can be displayed in a thesis can
be a major headache. Most thesis requirements do not allow for color figures
because your thesis will be sent to a service that will archive it as a
microfilm. This destroys all color effects. In some schools, they will allow
you to make two versions of your thesis - one with a color figure that can be
used as the distribution/department/library copies, while another for microfilm
archive.
Part XVI -
Your Thesis Defense
At this point, you have completed writing your thesis, your
adviser has approved of it, and you have distributed it to all the members in
your thesis committee. It is now time for you to do your thesis defense.
Officially, this is the final obstacle standing in your way between you and
your Ph.D degree. Needless to say adequate preparations are necessary.
What exactly is a thesis defense? This is where you
demonstrate your mastery of the subject matter that you have been researching
during your years as a Ph.D candidate. To put it bluntly, since you are
producing an original, new work to be added to the body of knowledge of
physics, you have to prove that (i) you understand the physics inside out and
(ii) you are the world expert on this particular area. In fact, in certain
parts of your thesis, even your adviser may not know as much, or as in detail,
as you. This is where you have to establish yourself as someone who knows a lot
on this particular topic. You must know every single thing that you wrote in
your thesis, and maybe even some beyond that, especially if you make specific
reference to other theories or experiments. Your thesis committee will try to
judge if you are an expert in such a field.
The most important person that should prepare you for your
defense (other than yourself) is your adviser. Your adviser would have guided
you in the beginning into a research subject that would satisfy the graduate
school/departmental requirement that your work is new, original, and something
significant that contributes to the body of knowledge. Publishing in respected
peer-reviewed journals would be a major indication that your work is accepted
as being new and significant. So in preparation for your defense, he/she should
try to impress upon you on making sure that you mention somewhere during your
thesis defense that such-and-such work that you did was published in so-and-so
journal. More importantly, though, is that your adviser might know certain
"quirkyness" of certain members of your committee that might help you
to prepare for. If a particular professor always likes to ask about
"historical significance" of certain things, or maybe he/she likes to
always try to include his/her own research area, then these are the things you
should prepare for. It is ALWAYS a good strategy that if you happen to have
used or cited the work of one or more of the committee members, then you should
make sure you mention this clearly. You'd be surprised how well those kinds of
acknowledgments can go down. This should be a common practice throughout your
career. In any case, in preparing for your defense, talk to your adviser and
ask him/her for his opinion. It may be that your adviser would like you to do a
trial run at doing your defense. JUMP at such an opportunity. Such practice is
always a good idea. Do this in front of your adviser and other graduate
students (who should already be keen on seeing what it should look like since
they have to go through the same thing soon enough). Such practice should allow
for last-minute kinks to be worked out and to prevent major disasters.
How long your defense should take place depends very much on
your adviser and the procedure enacted at your school. Most schools leave it
entirely to your adviser. In turn, most advisers would prefer a defense that is
between an hour to two hours. However, I have seen a defense that took place
over a span of 2 days! It wasn't pretty. So in your practice, make sure you pay
attention to how long you are presenting your defense. You do not want your
audience, or worse yet, your committee members, to fall asleep.
Most thesis defense are usually announced to the public via
the usual seminar/colloquium announcement made by your department. So everyone
is usually welcome to attend your defense. Typically, the first part of your
defense is similar to you giving a seminar. At the end of your presentation,
everyone in attendance is invited to ask questions. The committee members
usually would not ask anything during this time, but they will pay attention to
how you respond to the questions being asked. So do not trivialize a question,
even though it came from one of your buddies in attendance. After this question
and answer session, the rest of the audience will be asked to leave, and the
closed session will be just between you and the committee members. This is
where usually the difficult questions will come up. They will disect your
presentation and the content of your written thesis. Pay careful attention to
what they ask, answer as thoroughly as you can, and acknowledge any comment or
suggestion that they give. Sometime, a question can really come out from left
field that you simply did not expect, and you find yourself stumbling along.
More often than not, if you have a good adviser, he/she might offer a reply to
try to guide you into a right path. So pay attention and try to see if you can
get any hints there. Just keep in mind that just because you are unable to
answer something which might not be central to your work, this does not mean
that they will fail you. So whatever you do, do not panic.
After the committee is done with this session, you will be
asked to leave and they will deliberate your fate. My anecdotal account of my
defense goes like this: they decided to stay in their deliberation for about 10
minutes longer JUST to make me squirm and sweat. At this stage, there's nothing
else you can do. Just exhale, relax, and try not to stress out. Unless
something really disasterous happened during your defense, you can almost be
assured that you have accomplished your goal. After the committee's
deliberation, your adviser will officially informed you if you have passed
through your defense. He/she will also inform you of any changes that are
necessary to your thesis based on suggestions from the committee members. These
are the changes that you need to make before getting the final approval from
all of them for you to submit to the thesis examiner/graduate school.
Other than that, it is time to rejoice. You have done a
significant accomplishment that was not easy, and took years of hard work and
sacrifice. In the eyes of many, you are now a Physicist!
However, is that all there is? You can go out now and work as
a Physicist? If only life is that simple and straightforward. In the next
chapter, we will go back in time to approximately one year from your joyous
occasion at completing your studies. Your journey on becoming a physicist isn't
done yet just because they are handing you your Ph.D degree.
Part XVII -
Getting a Job!
In the previous chapter, we have reached the point where you
have finished with your thesis defense, and also thesis submission to the
graduate school. You are all set to go into the nasty physics world and look
for a job.
If that is your case, then you are SCREWED! You do NOT start
to look for a job only after you are done with your defense. This will be too
late and should only be resorted to if you have no other choice. So while you
think you are done with your physics curriculum, your job future requires that
we go back in time to about one year before you plan on graduating.
By that time, you would have an idea on your career path. You
should know if you wish to pursue an academic career, an industrial career (for
those of you who have this option), or maybe even get out of physics
completely. Still, unless you have a Nobel Laureate as an adviser and have made
a name for yourself in such a way that there are institutions rolling out the
red carpet for you, you should keep your options open. Remember, you will have
to start making a living, and ideals will not feed you much.
I will go into the academic career path first since this is
the more tedious side. If you do decide to follow this path, then you will have
to start seeking a post-doctoral appointment. Most universities and national
laboratories will tend to hire new Ph.Ds at the post-doctoral level (note that
US National laboratories will not hire a Ph.D for a post-doc position who
obtained a Ph.D beyond 4 years of the date of the appointment).
There are two common places to look for openings for a
post-doc position. The first is the classified section of Physics Today.
Typically, the largest number of openings for post-doc and faculty positions
are advertised during the Fall/early Spring for an appointment in the Fall of
the following year. So an opening for Fall 2007 would tend to get advertised
more often in Fall 2006/ early Spring 2007. This is why you have to start
almost a year in advance in your job hunt.
The other avenue to find post-doc openings is during physics
conferences, specially the APS March and April Meetings. The APS provides a job
service to both job seekers and employers during the conference. You will have
to register with the APS and submit your resume. While you don't have to attend
these conferences to submit your resume, I strongly advice you to be present.
There are professors and schools that will advertise for an opening right on
the spot (these are usually posted on the Job Center bulletin boards). So you
can also look for something that you might qualify and immediately make
contact. Not only that, but in many cases, if you have submitted a resume, you
might be contacted by an employer present at the conference, and an interview
can be set up during the conference itself.
This is where I will illustrate with my own personal
experience. A few months before I graduated, I attended the APS March Meeting
to not only present a talk, but also continue looking for a job. I already had
an offer from Applied Materials to go into the industrial route. While I was
excited with this and would pursue this line gladly, I knew that my first aim
was still in academia/research and so I continued to look. Attending the Job
Fair at this March Meeting was almost a last-minute decision. As fate would
have it, a faculty member was looking for a post-doc to work at Brookhaven, and
happened to be well-acquianted with my adviser at that time. He read my resume
and figured that with my background and with the "name recognition"
from my adviser, that I would be a strong candidate. I received a message from
the Job Center of a request for an interview later in the week of the
conference. However, without my knowing it, the faculty member seek out when I
will be presenting my talk, and attended the session to see me "in
action", so to speak.
I found this out later during our interview, and he was
satisfied that I fit the bill to carry out the research work that he had
planned. While no job offers were made at the interview, I left feeling that it
went tremendously well. It was a week later that the job offer was officially
made, which I accepted.
The moral of the story here is that in many cases, you truly
have to try all the possible avenues, and the Job Fair at these conferences can
be quite effective because in many instances, the employers are also there
seeking candidates.
The last possible avenue is the one that is very uncertain
and something you should not depend on - word of mouth. Often, various faculty
members, usually your adviser, would have heard from his/her various colleagues
or contacts, about post-doc openings elsewhere, or even within your department.
If a faculty member recommends something to you, consider it seriously. There's
a good chance that the person looking to hire knows the faculty member, and
name recognition alone will give you a leg up on another candidate. This is
what I meant by "pedigree" in an earlier chapter of this series.
Unfortunately, this situation doesn't happen often, and that is why I said that
you should not rely on such a thing happening.
If instead, you are opting for an industrial or non-academic
position, then you need to cast your net a lot wider. Sources such as Physics
Today and the APS Meetings are still valid, since those do carry non-academic
positions (that was how I managed to snag the Applied Materials offer).
However, you also need to look at the "trade journal" of the area you
are looking for. Solid state physics specialists should look in IEEE journals,
for example.
Do not forget to use your school's job placement services.
Many employers will seek out new graduates, and your school can also list your
resume with employers they think might be interested with your background.
Industrial employers will tend to go through this route, especially if they had
success with a particular school before. So don't leave out this option.
Again, all of these should be done approximately a year
before you plan on graduating. Make sure you have your resume ready. Have it
checked properly, and make sure you include ALL publications.
In the next installment, I will go into your role as a
post-doc fellow, and how things will look different from that point onwards.
Part XVIII
- Postdoctoral Position
If you intend to pursue an academic/research career, chances
are, you will need postdoctoral experience. This is typically a 2 to 3-year
appointment either at a university, national laboratories, or industrial
laboratories such as Bell Lab. It is not uncommon for someone to do 2
postdoctoral positions before finding a suitable employment. So this part of
your career could drag on longer than expected. However, for most candidates,
this could easily be the most productive part of your career and when you can
effectively make a name for yourself.
A postdoctoral position is usually created out of a research
grant. It means that funds have been allocated to hire a person at that
position for the duration stated. Once that duration ends, the position will
also end. This is why it is a temporary position. In some cases, if the
institution has an opening, they might consider you for a permanent position.
However, you should not depend on this and should always consider it as
temporary.
The reason why a postdoctoral experience is usually deemed
necessary to obtain highly sought-after position in leading universities and national
laboratories is that these institutions want to employ individuals who (i) have
shown the ability to carry on world-class research work on their own (ii) have
the creativity to find new and important things to study (iii) can seek
funding. These are the skills that one obtains and can demonstrate while a
being a postdoctoral appointee (seeking funding may not be relevant for a
postdoc in many areas such as theoretical work, or in large projects such as
high energy physics).
Unlike your position as a graduate student, a postdoctoral
appointee is expected to hit the ground running. Presumably, with your Ph.D,
you were hired for your expertise in a particular area. You also have quite a
bit more freedom in pursuing the particular area of research. While the broad
outline of the area of study is set by your supervisor, you essentially can, in
fact, discuss with him/her a line of research that you think should be pursued.
You are expected to be able to work
independently and show your creativity in that field of study. Your supervisor
is no longer there to hold your hand the way your Ph.D adviser did.
If your appointment is with an academic institution, part of
your responsibility may also involve some form of teaching or academic
responsibility. Again, while such responsibility may take you away from doing
research work, consider it as added experience that you can add to your resume
as you continue to seek a more permanent position. It can only be an advantage
to be able to include teaching experience in your job application, especially
if you apply to an academic institution. So do not look at such responsibility
with disdain.
During your postdoctoral appointment, you are highly expected
to publish a few papers, preferably in leading journals. You are expected to
know how to go about doing this. You may also be expected to supervise graduate
students who will learn from you and your expertise. This is your chance (and
even responsibility) to give back what you were given while you were a graduate
student.
The issue of funding is a bit difficult to tackle because in
many cases, it really depends on the institution. In some institution, the very
fact that you can get research funding on your own might be the impetus for
them to continue to hire you as a staff member. In national laboratories, you
might be expected to be able to seek funding via what is known as the LDRD
(laboratory-directed research and development), which are short-term fundings
for projects that are potentially capable of receiving larger external funding.
Remember that you are there only temporarily. Your ability to attract funding
may in fact make you more attractive to be hired, or simply lengthen your
postdoctoral appointment. However, you should try to learn as much as possible
(probably from your supervisor) on how to seek research funding. Try asking him
or her to see an example of a research funding proposal that has gotten
through. In physics, the majority of research funding comes from the US Dept.
of Energy (DOE) and the National Science Foundation (NSF). Go to their websites
and look carefully at the requirement and format to submit a research funding
proposal, even if you don't intend to write one. Chances are, you will need to
know how to do one of these sooner or later.
Throughout your appointment, you should not stop continuing
to look for job opening. It may turn out that as your appointment ends, you may
have to seek a second postdoctoral position. Note however that for US National
labs, there is usually a 6-year limit from the date that you received your Ph.D
to qualify for a postdoctoral position. So if you have received your Ph.D
longer than 6 years ago, you no longer qualify for a postdoctoral position.
As temporary and as uncertain as it is, to me, the
postdoctoral period is when one truly begins to feel like a physicist. One is
now doing directly the type of work one has been dreaming off all those years.
There is also little to no other distractions away from one's work, so this is
what a physicist truly is, in the purest sense. You will realize later on that
as one finally obtain a more permanent position, one is also saddled with other
administrative responsibilities that come with the job. So look at the
postdoctoral position as the buffer, or transition between your life as a
student having a mentor, to being a physicist where you now have to make your
own decisions. This transition period may be your most productive and the last
time you get to be single-minded on a particular area of physics.
Zz.
Part XIX -
Your Curriculum Vitae
I am going to backtrack a little bit and talk about writing
your Curriculum Vitae (CV) and what you should focus on in search for a job in
physics. This includes looking for a Postdoctoral position, a research
position, and possibly a faculty position at a university.
I am going to base this on my own personal experience in
hunting for jobs, my conversation with others who were in my position, my
discussion with other supervisors who were looking for candidates for a
position, and my own experience in browsing applicants' CV to fill a couple of
positions. I would say that most physics applicants do not pay that keen of an
attention to their CV, and one sometime wonders if they are truly interested in
a particular position that they are applying for.
Here are the items that MUST appear on your CV:
1. Name, mailing address, e-mail address, phone number;
2. A brief (one short paragraph, or even just a sentence) on
your goal;
3. Your educational background. List in reverse chronological
order, i.e. the last degree obtained first.
4. Your skills, expertise, and knowledge;
5. Other awards, recognition;
6. List of publications (if there's too many, list the more
important ones, or the ones relevant to the job you are applying to).
Try not to exceed more than 2 pages. Keep in mind that people
who are reading this have to read a lot of other CVs from other applicants. If
it is too long, one loses interest very quickly.
Most of what I've listed above are pretty self-explanatory,
and most applicants know what do write, except for #4. This is what I will try
to discuss in the rest of this chapter. From what I have read of a number of
CVs lately, this is where many applicants drop the ball.
Most CVs that I've received wrote way too much on the
"physics" content. Now, such a thing may be appropriate in some
circumstances, especially if you're applying in the very exact, same area of
knowledge as your research area. The person who is hiring would probably know
the subject matter quite well, and would be very interested in it. However,
this is also not very common. What occurs most of the time is that you are
applying for a position, especially for a postdoc position, in which the
subject area is a bit different, some time VERY different, than the subject
area that you majored in. What is in common are the skills and expertise that
you have that the potential employer is looking for. So HIGHLIGHT THE EXPERTISE
AND THE SKILLS in the CV! Don't bury it under lots of physics and don't simply
mention it in passing. Not only are you not showing to the potential employer
what he/she is looking for, but it also shows that you simply sent out a
generic CV without bothering to tailor it to this particular job position. I
had that impression many times while reading several CVs.
Let's do an example. Say I'm looking for someone who can make
photocathodes for some particular application. Now, I'm not looking for someone
with an exact background who majored in photocathode physics, because it isn't
a common area of specialization, and there probably isn't that many students
who graduated with that knowledge. However, I am looking for someone who has
the expertise to make material fabrication. In particular, I'm looking for
someone who has the expertise to make thin films of semiconductors, using
various deposition technique, especially chemical vapor deposition (CVD).
Unfortunately, it was hard to find that in many of the CVs
that I read. Most of the CV talked about the physics (or chemistry) of the
material, what was studied, how the physics was important, etc. In cases where
the applicants did mention about making thin films, the skimped on the details.
I would say something like this: "Ability
to make thin films for XRD and XPS studies to arrive at the strain-stress effects
on the band structure". Yes, what WHAT did you use to make the thin
films? That is what I am looking for, and you had just glossed over that piece
of information! The strain-stress effects on band structure is the
"physics", and unless you are applying for a research position in
which THAT is one of the areas of study for that open position, the potential
employer probably cares VERY little about that useless fact.
Instead, what the applicant should have done is say something
like "Ability to fabricate metals and semiconductor thin films using
MOCVD, producing large epitaxial single crystals. I am also able to analyze
these thin films using XRD to evaluate the quality of the thin films". The
applicants could also list ALL of the thin film materials that he/she had the
ability to make. Now THIS would be something valuable. In doing that, the
applicant has revealed the skill that he/she has, and it is a skill that
completely transcends any particular subject matter area. This is because the
skill to make films using CVD technique is used in MANY different areas, and
not just in physics either. Having that skill allows one to apply to a large
variety of jobs that would not have been possible if one were to stick to
simply the subject matter of one's major area. This is why such skills MUST be
clearly and plainly described in one's CV!
Zz.
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