Best answer: I don't want to sound like a wet blanket, but to grasp QM to any degree beyond platitudes, you're gonna have to do some serious work. You'll need to be competent in linear algebra and several variable calculus at least. Then, or concurrently, you'll have to learn about classical linear wave theory, and finally second order linear differential equations (you could add the standard methods of classical mechanics, like Lagrangian and Hamiltonian mechanics, if you were motivated). Once you've got a good grasp of these, you can work through various problems such as (in order from most to least basic, and you can google these):

• Particle in a box
• harmonic oscillator
• hydrogen atom
• 2 particles on a ring

Then, once you understand these, read about the Copenhagen Interpretation and the Measurement Problem (wherein you'll find Schrödinger's eponymous cat). If you're not exhausted by this point, continue to the Dirac equation, and possibly the Standard model.

I know this sounds daunting, but it's really the only way to get an understanding of the subject. People can write book after book with tortured metaphor after tortured metaphor, but at its base QM is fundamentally vertical and irreducibly mathematical - there really is no way of getting around it. Popular physics writing is really in the same genre as powerpoint displays - their function is fundamentally limited by their form, and they leave you with false sense of understanding.

On the positive side though, QM is, if you're motivated to work at it, maybe the most beautiful and puzzling thing you're likely to encounter in science, second perhaps only to evolution by natural selection in its elegance.
posted by claudius at 8:27 AM on November 29, 2006

Best answer: Seconding claudius.

I probably sound like a broken record on ask.mefi but none of the descriptive books will give you an understanding of quantum physics. They will just familiarize you with someone else's interpretation. This is true of the Greene and Hawking books for example.

The only way to learn QM is to study it and do the math. This means textbooks. You need to work throught them and play with the Shrodinger wave equation and Heisenberg bra-ket notation and Pauli spin matrices and all that good stuff.

The online courses mentioned above look pretty good. But a real understanding of QM presupposes an understanding of classical mechanics, electromagnetism and special relativity.

There's quite a few people here on mefi who have actually studied QM and its frightfully easy to tell them apart from people who have only read about QM.
posted by vacapinta at 9:01 AM on November 29, 2006

Best answer: As everyone else has said, you need to work through the math to really understand quantum. I'd read a bunch of the books suggested above prior to taking quantum, and although I could talk about Schroedinger's Cat and so on, it didn't really make any sense. However, once you get a chance to really study it - math and all - it is incredibly cool [if still very unintuitive, at least for me.]

I used McQuarrie's quantum textbook and found it very clear, but you'll need a solid mathematical base to understand it. If I were you, I'd start with the math: start with single-variable calculus [review your basic knowledge about functions, trigonometry, algebra as necessary], and work your way up through multivariable calculus. You can get through McQuarrie without knowing much about differential equations or linear algebra [although knowing the basics will _certainly_ help], but you'll need multivariable calculus to make sense of even the more basic quantum stuff. Once you feel somewhat comfortable with calculus, you can start using McQuarrie [or another introductory book] to work your way through the sorts of problems that claudius mentions. [Most'll be covered in any basic text].

Note that 5.61, (the intro quantum class taught by MIT's chemistry dept and made available on OCW) uses McQuarrie; if you choose to use that as an introductory text, you'll probably find 5.61 more useful than 8.04, which uses a different pair of textbooks. My apologies for not having recommendations for math textbooks - I haven't been particularly happy with any of the ones I've used. Either way, you should pick up actual textbooks - it won't be possible to gain a real understanding of the material just from coursenotes. [Oh, just realized you said you haven't had college-level physics, either. Again, I disliked my basic physics textbooks, so I don't have good recommendations, but you should really work through basic classical mechanics and E&M before tackling quantum.]
posted by ubersturm at 9:23 AM on November 29, 2006

Best answer: Just to clear up a couple of questions: I am also interested in learning about relativity (probably should have mentioned that in the question). I haven't done maths or physics at undergrad level, just high school.

Do you want to learn about special relativity or general relativity? For the former, you don't need much more than high-school algebra; a small amount of calculus is required for the more advanced stuff, but you can get a very good grasp on the subject without needing to differentiate or integrate. The best book on Special Relativity that I know of is A Traveler's Guide to Spacetime by Thomas A. Moore.

General relativity is a little trickier; there's a lot of complicated math that you need to understand what's going on with it. You would definitely need some college-level calculus (single- and multi-variable) to get a full grip on it. If you're truly interested in knowing the mathematics behind it, you might try looking up Gravity by James Hartle; it's got an interesting "physics-first" approach, in which he describes the structure of spacetimes, and how physics works in them, without (at first) telling you why they're actually valid. Only in the later chapters of the book does he "lift up the hood" and show you all the mathematical machinery required to derive these spacetimes.
posted by Johnny Assay at 10:04 AM on November 29, 2006

Best answer: I ditto the McQuarrie QM book, but it's not a starter text. You'll want at least second-year calculus to make a run at it. The second book of the Feynmann lecutres is also good, but it was written in the fifties.

The book I usually recommend when asked about this is Sudbery's "Quantum Mechanics and the Particles of Nature: An Outline for Mathematicians". It's a bit dated on the particles side now (written in the mid eighties), but the QM bits are a good now as ever. For all the title, it requires more formalism than math. Philosophy students seem to like it in particular.

My favourite texts for QM though are Messiah's "Quantum Mechanics", which, like any classic, is accessible with some effort, and Sakurai's "Modern Quantum Mechanics", which.. isn't.
posted by bonehead at 6:22 PM on November 29, 2006

Best answer: It but it makes things a lot easier if you're fast at algebraic manipulations, Taylor expansions and the basic rules of differentiation and integration. These things show up all the time in formulas, and if they are transparent to you, all reasoning will seem much clearer.

Since you didn't study maths in a while, let me emphasize that you learn it by exercising. You can read the book and think it makes sense, but you have to solve problems. That's how you acquire the speed and the "vision" I mentioned above, that make it possible to parse physics textbooks.

However, you don't have to be great at calculus. What you need most of all is a strong sense for what integrals and derivatives mean, one- and many-dimensional, and being comfortable with all kinds of notation. You get that from exercise, but you don't have to be able to solve every problem in the book.

Complex numbers are particular in that they are ill-suited for most practical purposes, except im QM where they are totally crucial. Make yourself fluent in those!


I second claudius on skipping most of solid state (I say this as a Phd student in experimental solid state/quantum device physics). There's a lot of nice theory there, but it's pragmatic and relies to a large extent on statistical and semiclassical reasoning, and smart assumptions about the systems it describes. Save it for later and concentrate on atoms and quantum information. The latter is something I can't recommend warmly enough - qubits are QM distilled, and don't require too difficult maths to get to the nice parts.

As a final remark, if you're into programming, it's instructive to make numerical calculations yourself and plot solutions to the Schrödinger equation. I used Matlab to apply a transfer matrix method in a course once, and it was quite magical to see a wave packet half bounce, half transmit against a potential step, in a program I made myself out of simple (stationary plane wave) solutions to the SE.

Yeah, and add a vote for the Feynman lectures.
posted by springload at 2:18 PM on November 30, 2006