(zz)HOW to BECOME a GOOD THEORETICAL PHYSICIST

笨蛋UID：2285236

It so often happens that I receive mail - well-intended but totally useless - by amateur physicists who believe to have solved the world. They believe this, only because they understand totally nothing about the real way problems are solved in Modern Physics. If you really want to contribute to our theoretical understanding of physical laws - and it is an exciting experience if you succeed! - there are many things you need to know. First of all, be serious about it. All necessary science courses are taught at Universities, so, naturally, the first thing you should do is have yourself admitted at a University and absorb everything you can. But what if you are still young, at School, and before being admitted at a University, you have to endure the childish anecdotes that they call science there? What if you are older, and you are not at all looking forward to join those noisy crowds of young students ?
It should be possible, these days, to collect all knowledge you need from the internet. Problem then is, there is so much junk on the internet. Is it possible to weed out those very rare pages that may really be of use? I know exactly what should be taught to the beginning student. The names and topics of the absolutely necessary lecture courses are easy to list, and this is what I have done below. It is my intention to search on the web where the really useful papers and books are, preferably downloadable as well. This way, the costs of becoming a theoretical physicist should not exceed much the price of a computer with internet connection, a printer, and lots of paper and pens. Unfortunately, I still have to recommend to buy text books as well, but it is harder to advise you here; perhaps in a future site. Let's first limit ourselves to the absolute minimum. The subjects listed below must be studied. Any omission will be punished: failure. Do get me right: you don't have to believe anything you read on faith - check it. Try alternative approaches, as many as you can. You will discover, time and again, that really what those guys did indeed was the smartest thing possible. Amazing. the best of the texts come with exercises. Do them. find out that you can understand everything. Try to reach the stage that you discover the numerous misprints, tiny mistakes as well as more important errors, and imagine how you would write those texts in a smarter way.
I can tell you of my own experiences. I had the extreme luck of having excellent teachers around me. That helps one from running astray. It helped me all the way to earn a Nobel Prize. But I didn't have internet. I am going to try to be your teacher. It is a formidable task. I am asking students, colleagues, teachers to help me improve this site. It is presently set up only for those who wish to become theoretical physicists, not just ordinary ones, but the very best, those who are fully determined to earn their own Nobel Prize. If you are more modest than that, well, finish those lousy schools first and follow the regular routes provided by educators and specialized -gogues who are so damn carefully chewing all those tiny portions before feeding them to you. This is a site for ambitious people. I am sure that anyone can do this, if one is gifted with a certain amount of intelligence, interest and determination.
Theoretical Physics is like a sky scraper. It has solid foundations in elementary mathematics and notions of classical (pre-20th century) physics. Don't think that pre-20th century physics is "irrelevant" since now we have so much more. In those days, the solid foundations were laid of the knowledge that we enjoy now. Don't try to construct your sky scraper without first reconstructing these foundations yourself. The first few floors of our skyscraper consist of advanced mathematical formalisms that turn the Classical Physics theories into beauties of their own. They are needed if you want to go higher than that. So, next come many of the other subjects listed below. Finally, if you are mad enough that you want to solve those tremendously perplexing problems of reconciling gravitational physics with the quantum world, you end up studying general relativity, superstring theory, M-theory, Calabi-Yau compactification and so on. That's presently the top of the sky scraper. There are other peaks such as Bose-Einstein condensation, fractional Hall effect, and more. Also good for Nobel Prizes, as the past years have shown. A warning is called for: even if you are extremely smart, you are still likely to get stuck somewhere. Surf the net yourself. Find more. Tell me about what you found. If this site has been of any help to someone while preparing for a University study, if this has motivated someone, helped someone along the way, and smoothened his or her path towards science, then I call this site successful. Please let me know. Here is the list. Note that this site NOT meant to be very pedagogical. I avoid texts with lots of colorful but distracting pictures from authors who try hard to be funny. Also, the subjects included are somewhat focused towards my own interests.


LIST OF SUBJECTS, IN LOGICAL ORDER (not everything has to be done in this order, but this approximately indicates the logical coherence of the various subjects. Some notes are at a higher level than others).  

• Languages
• Primary Mathematics
• Classical Mechanics
• Optics
• Statistical Mechanics and Thermodynamics
• Electronics
• Electromagnetism
• Quantum Mechanics
• Atoms and Molecules
• Solid State Physics
• Nuclear Physics
• Plasma Physics
• Advanced Mathematics
• Special Relativity
• Advanced Quantum Mechanics
• Phenomenology
• General Relativity
• Quantum Field Theory
• Superstring Theory

More resources
The .ps files are PostScript files §.
(In this initial phase this page is still incomplete!)

笨蛋UID：2285236

Languages:
English is a prerequisite. If you haven't mastered it yet, learn it. You must be able to read, write, speak and understand English, but you don't have to be perfect here. The lousy English used in this text is mine. That's enough. All publications are in English. Note the importance of being able to write in English. Sooner or later you will wish to publish your results. People must be able to read and understand your stuff.


Free English courses and resources.
BBC world service learning English.


French, German, Spanish and Italian may be useful too, but they are not at all necessary. They are nowhere near the foundations of our sky-scraper, so don't worry. You do need the Greek alphabet. Greek letters are used a lot. Learn their names, otherwise you make a fool of yourself when giving an oral presentation. Now, here begins the serious stuff. Don't complain that it looks like being a lot. You won't get your Nobel Prize for free, and remember, all of this together takes our students at least 5 years of intense study (at least one reader was surprised at this statement, saying that (s)he would never master this in 5 years; indeed, I am addressing people who plan to spend most of their time to this study). More than rudimentary intelligence is assumed to be present, because ordinary students can master this material only when assisted by patient teachers. It is necessary to do exercises. Some of the texts come with exercises. Do them, or better, invent your own exercises. Try to outsmart the authors, but please refrain from mailing to me your alternative theories until you have studied the entire lot; if you do this well you will discover that many of these authors were not so stupid after all.

笨蛋UID：2285236

Primary Mathematics:
Are you comfortable with numbers, adding, subtracting, square roots, etc.?

*Beginning Algebra* (West Texas A&M)
*Intermediate Algebra* (West Texas A&M)
  

Natural numbers: 1, 2, 3, ...
Integers: ..., -3, -2, -1, 0, 1, 2, ...
Rational numbers (fractions): ¼, ½, ¾, 23791 / 773, ...
Real numbers: Sqrt(2) = 1.4142135... , pi = 3.14159265... , e= 2.7182818..., ...
Complex numbers: 2+3i, eia= cos(a) + isin( a), ... they are very important!
Dave E. Joyce's trigonometry course
This is a must:
Prof. James Binney's course on complex numbers(PDF)

(nearly) complete overview of primary mathematics(K.Kubota, Kentucky)

See also Chris Pope's lecture notes:
Methods1-ch1
Methods1-ch2

The complex plane. Cauchy theorems and contour integration (G. Cain, Atlanta)
Set theory: open sets, compact spaces. Topology.You may be surprised to learn that they do play a role indeed in physics!
Algebraic equations. Approximation techniques. Series expansions: the Taylor series. Solving equations with complex numbers. Trigonometry: sin(2x)=2sin x cos x, etc.

Infinitesimals. Differentiation. Differentiate basic functions (sin, cos, exp). Integration. Integrate basic functions, when possible. Differential equations. Linear equations.
The Fourier transformation. The use of complex numbers. Convergence of series.

The complex plane. Cauchy theorems and contour integration (now this is fun).
The Gamma function (enjoy studying its properties).
Gaussian integrals. Probability theory.

Partial differential equations. Dirichlet and Neumann boundary conditions.

This is for starters. Some of these topics actually come as entire lecture courses. Much of those are essential ingredients of theories in Physics. You don't have to finish it all before beginning with what follows next, but remember to return to those subjects skipped during the first round.

笨蛋UID：2285236

Classical Mechanics: An intermediate level course on Analytical Classical Dynamics by  R. Fitzpatrick, Univ. of Texas, Austin.
A good set of Lecture notes from Harvard.

A short course on Classical Mechanics by  Prof. J. J. Binney
Static mechanics (forces, tension); hydrostatics. Newton's Laws.
The elliptical orbits of planets. The many-body system.
The action principle. Hamilton's equations. The Lagrangean. (Don't skip - extremely important!)
The harmonic oscillator. The pendulum.
Poisson's brackets.
Wave equations. Liquids and gases. The Navier-Stokes equations. Viscosity and friction.
Return to List


Optics: A.A. Louro's lecture Notes on Optics
R. V. Jones lecture notes on Classical and Quantum Optics
fraction and reflection.
lenses and mirrors.
The telescope and the microscope.
Introduction to wave propagation.
Doppler effect.
Huijgens' principle of wave superposition.
Wave fronts.
Caustics.
Return to List


Statistical Mechanics and Thermodynamics: The course "Statistical Mechanics" by Alfred Huan
Prof. Kelly's lecture notes on Statistical Physics

Gould/Tobochnik lecture notes

Intermediate level course on Statistical Mechanics by R. Fitzpatrick


The first, second and third laws of thermodynamics.
The Boltzmann distribution.
The Carnot cycle. Entropy. Heat engines.
Phase transitions. Thermodynamical models.
The Ising Model (postpone techniques to solve the 2-dimensional Ising Model to later).
Planck's radiation law (as a prelude to Quantum Mechanics)
Return to List


Electronics:
(Only some very basic things about electronic circuits)
Lessons In Electric Circuits by T. R. Kuphaldt

Ohm's law, capacitors, inductors, using complex numbers to calculate their effects.
Transistors, diodes (how these actually work comes later).

笨蛋UID：2285236

Electromagnetism: W.J.Spence, Electromagnetism
Notes on Classical Electromagnetism by R. Fritzpatrick.

Bo Thide's EM Field theory text(advanced)

Worked out exercises from Jackson's book,
set 1 / set 2
Maxwell's Theory for electromagnetism
homogeneous and inhomogeneous

Maxwell's laws in a medium. Boundaries. Solving the equations in:
vacumm and homogeneous medium (electromagnetic waves)
in a box (wave guides)
at boundaries (fraction and reflection)

The vector potential and gauge invariance (extremely important)
emission and absorption on EM waves (antenna)
light scattering against objects.
Return to List


Computational Physics : Mathematica for Students of Science by James Kelly
Angus MacKinnon, Computational Physics

Prof. Mathews' projects on Numerical Analysis



Even the pure sang theorist may be interested in some aspects of Computational physics.







Return to List


Quantum Mechanics (Non-relativistic): Introduction to QM and special relativity: Michael Fowler
Niels Walet lecture course on QM (Manchester)


Lecture Notes on QM from MIT

lecture notes
Bohr's atom.
DeBroglie's relations (Energy-frequency, momentum-wave number)
Schrödinger's equation (with electric potential and magnetic field).
Ehrenfest's theorem.
A particle in a box.
The hydrogen atom, solved systematically. The Zeeman effect.Stark effect.
The quantum harmonic oscillator.
Operators: energy, momentum, angular momentum, creation and annihilation operators.
Their commutation rules.
Introduction to quantum mechanical scattering. The S-matrix. Radio-active decay.
Return to List

笨蛋UID：2285236

Atoms and Molecules: Notes on General Quantum Chemistry from Georgiatech
Lecture notes on Physical Chemistry by Darin J. Ulness


Chemical binding
Orbitals
Atomic and molecular spectra
Emission and absorption of light.
Quantum selection rules
Magnetic moments.
Return to List


Solid State Physics: An introduction to Solid State Physics by Yuri M. Galperin
A course in Solid State Physics by Mark Jarrell

Solid State Physics: notes by Chetan Nayak (UCLA)


Crystal groups
Bragg reflection
Dielectric and diamagnetic constants
Bloch spectra
Fermi level
Conductors, semiconductors and insulators
Specific heat
Electrons and holes
The transistor
Supraconductivity
Hall effect.
Return to List


Nuclear Physics Five lectures on Nuclear Theory by D. B. Kaplan
A A primer in nuclear theory by J. Dobaczewski


Isotopes
Radio-activity
Fission and fusion
Droplet model
Nuclear quantum numbers
Magic nuclei
Isospin
Yukawa theory
Return to List




Plasma physics: Introduction to plasma physics by R. Fritzpatrick

magneto-hydrodynamics
Alfvén waves
Return to List


Advanced Mathematics: See John Heinbockel, Virginia.
See Chr. Pope: Methods2§
Mathematics textbooks list

G.'t Hooft: Lie groups in Physics, (now also in English) + exercises

For Lie Groups, see also the last section of Chr. Pope's lectures (under "General Relativity")

The special functions and polynomials(PDF) (just understand the principles)
Group theory, and the linear representations of groups
Lie group theory
Vectors and tensors
More techniques to solve (partial) differential and integral equations
Extremum principle and approximation techniques based on that
Difference equations
Generating functions
Hilbert space
Introduction to the functional integral
Return to List


Special Relativity Peter Dunsby's lecture course on tensors and special relativity
Prof. Firk's book on Special Relativity


The Lorentz transformation
Lorentz contraction, time dilatation
E = mc2
4-vectors and 4-tensors
Transformation rules for the Maxwell field
Relativistic Doppler effect
Return to List


Advanced Quantum Mechanics: Prof. Stringari's course on Ultracold Fluids
Introduction to the Quantum Hall effect by A.H. MacDonald

Introduction to Coherent States and Quantum Information Theory by K. Fujii

Tutorial on Quantum information by Peter Zoller

Intoduction to Quantum Computation by A. Chatterjee

Advanced QM by Freeman J. Dyson

K. Schulten's notes on advanced QM


Hilbert space
Atomic transitions
Emission and absorption of light
Stimulated emission
Density matrix
Interpretation of QM
The Bell inequalities
Towards relativistic QM: The Dirac equation, finestructure
Electrons and positrons
BCS theory for supraconductivity
Quantum Hall effect
Advanced scattering theory
Dispersion relations
Perturbation expansion
WKB approximation, Extremum principle
Bose-Einstein condensation
Superliquid helium
Return to List


Phenomenology: Lecture notes on phenomenology by R. Casalbuoni
Paolo Franzini's notes on elementary particles


subatomic particles (mesons, baryons, photons, leptons, quarks) and cosmic rays; property of materials and chemistry; nuclear isotopes; phase transitions; astrophysics (planetary system, stars, galaxies, red shifts, supernovae); cosmology (cosmological models, inflationary universe theories, microwave background radiation); detection techniques.

Return to List


General Relativity: Introduction + exercises by G. 't Hooft
Alternative: Sean M. Carrol's lecture notes on GR

Chr. Pope, Geometry and Group Theory, PS, PDF
The metric tensor
Space-time curvature
Einstein's gravity equation
The Schwarzschild black hole
Reissner-Nordström black hole
Periastron shift
Gravitational lensing
Cosmological models
Gravitational radiation
Return to List


Quantum Field Theory: Pierre van Baal's notes on QFT
The Conceptual Basis of Quantum Field Theory by G. 't Hooft
a chapter in Handbook of the Philosophy of Science

Magnetic monopoles and instantons
Classical fields: Scalar, Dirac-spinor, Yang-Mills vector fields.

Interactions, perturbation expansion. Spontaneous symmetry breaking, Goldstone mode, Higgs mechanism.

Particles and fields: Fock space. Antiparticles. Feynman rules. The Gell-Mann-Lévy sigma model for pions and nuclei. Loop diagrams. Unitarity, Causality and dispersion relations. Renormalization (Pauli-Villars; dimensional ren.) Quantum gauge theory: Gauge fixing, Faddeev-Popov determinant, Slavnov identities, BRST symmetry. The renormalization group. Asymptotic freedom.

Solitons, Skyrmions. Magnetic monopoles and instantons. Permanent quark confinement mechanism. The 1/N expansion. Operator product expansion. Bethe-Salpeter equation. Construction of the Standard Model. P and CP violation. The CPT theorem. Spin and statistics connection. Supersymmetry.

笨蛋UID：2285236

There are numerous good books on all sorts of topics in Theoretical Physics.

Just to name a few:

Classical Mechanics:
Classical Mechanics - 3rd ed. - Goldstein, Poole & Safko
Classical dynamics: a contemporary approach - Jorge V. José, Eugene J. Saletan
Classical Mechanics - Systems of Particles and Hamiltonian Dynamics - W. Greiner
Mathematical Methods of Classical Mechanics, 2nd ed. - V.I. Arnold
Mechanics 3rd ed. - L. Landau, E. Lifshitz
Statistical Mechanics:

L. E. Reichl: A Modern Course in Statistical Physics, 2nd ed.
R. K. Pathria: Statistical Mechanics
M. Plischke & B. Bergesen: Equilibrium Statistical Physics
L. D. Landau & E. M. Lifshitz: Statistical Physics, Part 1
S.-K. Ma, Statistical Mechanics, World Scientific
Quantum Mechanics:

Quantum Mechanics - an Introduction, 4th ed. - W. Greiner
R. Shankar, Principles of Quantum Mechanics, Plenum
Quantum Mechanics - Symmetries 2nd ed. - W. Greiner, B. Muller
Quantum Mechanics - Vol 1&2 - Cohen-Tannoudji
J.J. Sakurai, Advanced Quantum Mechanics, Addison-Wesley
Electrodynamics:

J.D. Jackson, Classical Electrodynamics, 3rd ed., Wiley & Sons.
Electromagnetic Fields And Waves - lorrain and corson
Classical Electrodynamics - W. Greiner
Introduction to Electrodynamics - D. Griffiths
Quantum Electrodynamics - 3rd ed., - W. Greiner, J. Reinhardt
Optics:

Principles of Optics - M.Born, E. Wolf
Principles Of Nonlinear Optics - Y. R. Shen
Thermodynamics:

Thermodynamics and an Introduction to Thermostatistics 2ed - H. Callen
Thermodynamics and statistical mechanics - Greiner, Neise, Stoecker
Solid State Physics:

Solid State Physics - Ashcroft, Neil W, Mermin, David N
Introduction to Solid State Physics 7th edition- Kittel, Charles
Special Relativity:

Classical Mechanics - Point Particles And Relativity - W. Greiner
Introduction to the theory of relativity and the principles of modern physics - H. Yilmaz
General Relativity:

J.B. Hartle, Gravity, An Introduction to Einstein's General Relativity, Addison Wesley, 2003.
T.-P. Cheng, Relativity, Gravitation and Cosmology, A Basic Introduction, Oxford Univ. Press, 2005.
Particle Physics:

Introduction to Elementary Particles - D. Griffiths
Fundamentals in Nuclear Physics - From Nuclear Structure to Cosmology - Basdevant, Rich, Spiro
Field Theory:

B. de Wit & J. Smith, Field Theory in Particle Physics, North-Holland
C. Itzykson & J.-B. Zuber, Quantum Field Theory, McGraw-Hill.
String Theory:

Barton Zwiebach, A First Course in String Theory, Cambridge Univ. Press, 2004
M.B. Green, J.H. Schwarz & E. Witten, Superstring theory, Vols. I & II, Cambridge Univ. Press
Cosmology:

An Introduction to cosmology, 3rd Ed – Roos
Relativity, thermodynamics, and cosmology - Tolman R.C.
General:

J.B. Marion & W.F. Hornyak, Principles of Physics, Saunders College Publishing, 1984, ISBN 0-03-049481-8
H. Margenau and G.M. Murphy, The Mathematics of Physics and Chemistry, D. v.Nostrand Comp.
R. Baker, Linear Algebra, Rinton Press

笨蛋UID：2285236

Find lists of other useful textbooks here: Mathematics, Physics (most of these are rather for amusement than being essential for understanding the World),
or a little bit more seriously: Physics.

There already is some response. I thank: Rob van Linden, Robert Tough, Thuy Nguyen, Tina Witham, Jerry Blair, Jonathan Martin, David Cuthbertson, Trent Strong, and many others.


Mr. Hisham Kotry came with an important question:
"...You sketch the path for potential students through the forest of college level physics... Two years ago I decided to self-study theoretical physics by following the syllabus of a renown university and the advice from your page and now I'm half-way through the journey but I was wondering about what happens next? Quoting you from the former page "In short, it is for all those who decided to study theoretical physics, in their own time.", Do you know of anyone who got tenure at a physics department or any research institute based on studies he did in his own time without holding a university degree?"

This is not so easy to answer, unfortunately. What I can say, is:
Eventually, whether you like it or not, you will have to obtain some University degree, if you wish a self-supporting career in theoretical Physics. One possibility is to follow a Master course such as the one offered by our University. I don't know about your qualifications, but I suspect that, with enough determination, you may be able to comply.

This is not a burocratic argument but a very practical one. It is also advisable not to wait until you think your self-study is completed. You must allow your abilities to be tested, so that you get the recognition that you may well deserve. Also, I frequently meet people who get stuck at some point. Only by intense interactions with teachers and peers one can help oneself across such barriers. I have not yet met anyone who could do the entire study all by him/herself without any guidance. If you really think you have reached a professional level in your studies, you can try to get admitted to schools, conferences and workshops in topics of your interest.

3/04/06: Message received from John Glasscock, Bloomington, IN:
The only one I know of currently is John Moffatt at U Toronto, who was a student of Abdus Salam at Imperial College, London. He started life as a painter in Paris, had no undergraduate degree, taught himself, corresponded with Einstein, and was admitted, based on his demonstrated original work, at IC. (Source: João Magueijo, _Faster than the Speed of Light_. Perseus Publishing, Cambridge, MA. 2003.)

Suggestions for further lecture notes from Alvaro Véliz:

1. The archimedeans webpage: It has a lot of lecture notes in Physics and Mathematics from Part I and II from Cambridge.
2. David Tong's (DAMTP)  lectures in classical mechanics I found these lectures fascinating.
3. Bo Thide's (Uppsala) lectures in electromagnetic theory.
4.  Angel Uranga's lectures in String Theory._
5. I found also extremely helpful MIT's OpenCourseWare: Lewin's lectures in basic Physics are terrific (in video).
6. Michael Fowler's (Virginia) lectures in Quantum Mechanics
        (not checked, G. 't H.)

渡渡鸟UID：145880

霍霍。。。好长啊
3X for S;d:

yezhenyuUID：2201973

是UU的Gerardus ("Gerard") 't Hooft写的
http://www.phys.uu.nl/~thooft/theorist.html
还有一个是写bad的
http://www.phys.uu.nl/~thooft/theoristbad.html
UU的理论物理荷兰最牛，在物理方面出过近十个nobel，UU的一个教学楼上挂着这些人的照片，Gerard 't Hooft在99年拿了Nobel，他的个人主页也挺有意思的。

狐狸大叔UID：2342950

说实话大多数人还不想成为theoretical physicist

yezhenyuUID：2201973

如果有funding，玩玩theoretical physics挺有意思的。不过现在funding竞争激烈。我学校做comp. arch.最牛的教授就是从理论物理改行的，当初他的phd好像是研究重力的，感觉发自内心爱玩theoretical physics的人都是牛人。

yezhenyuUID：2201973

所以我一直隐约感觉到lovephysics是牛人。

狐狸大叔UID：2342950

我怎么觉得很多牛人本科学了理工，然后毕业后申请了law school了。
以前cc forum有个牛人原来本科学engineering，后来去law school。好像还写过一篇文章解释，去law school多么得rewarding，engineering相比之下不理想。。。。

反正我是这么理解的，不为名利搞物理的都是牛人，无论他得什么奖了。

tohokuUID：2283178

小披风说的道理哦...