What to study for quantum mechanics?

In summary, the conversation revolves around the topic of studying quantum mechanics, specifically through textbooks and other resources. The person is interested in starting with the math and is seeking recommendations for easy-to-understand books or links. Some suggestions include Griffith's "Introduction to Quantum Mechanics," Sakurai's rigorous book, the Schaum's outline for solved examples, and Vol III of the Feynman lectures. Others mention Bransden & Joachim's "Introduction to Quantum Mechanics" and Rae's book. There is some disagreement about the effectiveness and rigor of Griffith's book, with some praising its focus on the big picture and others finding it lacking in depth. Overall, the conversation provides a range of options for someone looking to begin studying quantum mechanics.
  • #1
Peter Pan
32
0
I put a hold on my education, but want to keep studying physics. I left school after finishing SR. Would you kindly point me in a direction to begin with QM. Laymen books and links are would get my appitite wetted, but I would also like to start with the math.

Thank you for your help.
Pan
 
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  • #2
How about Griffith's "Introduction to Quantum Mechanics?"

- Warren
 
  • #3
is that a textbook or a book i can find in barnes and noble?
 
  • #4
It's a textbook. You're not going to find anything at Barnes & Noble to teach you quantum mechanics. You might be able to pick up a copy of the Feynman Lectures there (Volume III is on quantum), but they might not be the right place to start...

- Warren
 
  • #5
How about Griffith's "Introduction to Quantum Mechanics?"

Is that a good book? It's the one my current physics class uses, but I don't have anything to compare it to so I don't really know how good it is. And is Griffiths a smart guy, or just another physics guy who wrote a book?
 
  • #6
Originally posted by LeBrad
Is that a good book? It's the one my current physics class uses, but I don't have anything to compare it to so I don't really know how good it is. And is Griffiths a smart guy, or just another physics guy who wrote a book?
Well, it's not the most in-depth QM book, nor the most rigorous. But it's by far the most enjoyable to read of those I've gone through, and that's important to me, since I do a lot of self-study. I like it. I'd say a combination of several books, the shotgun approach, is probably best:

1) A rigorous book like Sakurai. This book is IMO very hard to read, leaving large, important parts of the discussion to the reader. Also, the problems are generally much more difficult than anything in the text. It's really a pretty obstinate goddamn book.

2) A rather fun, easy to read book like Griffiths. This book was the focus of my concerted self-study program.

3) A book like the Schaum's outline for a large body of solved example problems.

4) A very high-level, almost oppositely-structured book, like Vol III of the Feynman lectures, to help see "the big picture" of it all.

Your mileage, of course, will vary.

- Warren
 
  • #7
What about Path Integrals in Physics volumes I and II, are they any good? (I'm just about to buy them as their prices have gone right down)
 
  • #8
I learned quantum mechanics using Bransden & Joachim - Introduction to Quantum Mechanics. I found this a nice book, which is not too hard (as indeed Sakurai can be!) but still treating all the required basics.
 
  • #9
I'm not a fan of Griffiths. I think its too wishy-washy. Liboff is a fairly good start I think. Personally, I find almost all QM textbooks start in basically the same way. Its possibly the most efficient way to learn the theory (and you need to know it at some point), but I doubt it will keep you awake for long.

I liked Feynman's "Quantum Mechanics and Path Integrals," but I don't remember if it would be useful as an introduction. It has a much better perspective than most books IMO. The problem is that nobody else uses his concepts.
 
  • #10
I'm not a fan of Griffiths. I think its too wishy-washy.
Could you be specific in your critcism? I'd agree that Griffiths is very chatty, but I would not agree that he equivocates or misleads. I really like both Sakurai and Ballentine but I would not describe these as introductory texts. I think Griffiths is fine, especially for self-study.
 
  • #11
My problem with Griffiths (as far as I remember) was that it was not very rigorous. It developed things out of order with statements that some crucial step would make sense later. It also never went into much depth I think. It covered a lot of points, but only thinly. Much of the presentation seemed to be more focused on how to calculate things rather than understanding why the calculations go the way they do.

I tend to like more precise explanations, but that sort of thing is of course a matter of personal preference.

To be honest, I never really involved myself in this book, so take the above with that disclaimer. I looked at it a little, and didn't like it. My friends who had read it in detail agreed with my first impression (the more theoretical ones at least), so I didn't give it any more of my time.
 
  • #12
I like Rae's book as a first introduction to QM, but it sounds like the same sort of criticism applies to it as to Griffith's book.
 
  • #13
Originally posted by Stingray
My problem with Griffiths (as far as I remember) was that it was not very rigorous. It developed things out of order with statements that some crucial step would make sense later. It also never went into much depth I think.
i don t agree with this sentiment at all.

Griffiths takes great pains, i think, to make sure you see the big picture, and understand what it really means.

its true, that he doesn t start with bra-kets for a while, but that is because the beginning student often has a lot of difficulty with the more abstract notation. his treatment of the harmonic oscillator is great, his discussion of interpretations of quantum mechanics is the kind of thing that you can t find in a lot of introductory books, and gives you the feeling that he wants you to understand what quantum mechanics "really means".

he has some great problems, which can teach you things about e.g. neutrino oscillation, and non-hermitean observables, those are things i remember off the top of my head, at least.

i dunno... i am surprised that you don t like griffiths, because as far as beginning texts go, i don t think you can beat it.
 
  • #14
Peter Pan
Check this out. These are the actual Feynman lectures...on video...on the net...FREE!

http://vega-movie.central.susx.ac.uk/series/lectures/feynman/index.html [Broken]

I miss Richard P ( and Carl).
 
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  • #15
I have also been looking for some good introductory books to quantum mechanics. After some searching online I found a book that looks promising. It is one by A. C. Phillips. It is a paperback edition that only costs about$43. It says it has answers to the problems in the review of it, but does anyone know if this is a good book? For me, cost is a concern, which is why I don't want to get griffiths. Also, is there somewhere I could just get some good problem sets to work through?

Oh, and for anyone who wants to look at a nice expensive textbook without buying it, I recommend searching for it online and getting the isbn. Then go to a barnes and noble or other bookstore and order it. When it comes in they will call you and you can look at it without having to buy it. That is what I am doing.
 
  • #16
If you're looking for a cheap book with a lot of solved problems, look no further than "Schaum's Outline of Quantum Mechanics." It's $15 well spent. It's not well suited as a self-study textbook, though.

- Warren
 

1. What is quantum mechanics?

Quantum mechanics is a branch of physics that deals with the behavior of matter and energy at a very small scale, such as atoms and subatomic particles. It explains the fundamental principles that govern the behavior of these particles and their interactions.

2. Why is quantum mechanics important?

Quantum mechanics has revolutionized our understanding of the universe and has led to many technological advancements, including lasers, transistors, and computers. It also plays a crucial role in fields such as chemistry, material science, and engineering.

3. What are the key concepts in quantum mechanics?

Some of the key concepts in quantum mechanics include wave-particle duality, superposition, uncertainty principle, entanglement, and quantum tunneling. These concepts explain the bizarre and counterintuitive behavior of particles at the quantum level.

4. What are some practical applications of quantum mechanics?

Quantum mechanics has practical applications in various fields, such as quantum computing, cryptography, and sensing. It also has potential applications in medicine, energy production, and communication.

5. How can I study quantum mechanics?

To study quantum mechanics, one must have a strong foundation in mathematics and physics. It is recommended to start with introductory courses in classical mechanics, electromagnetism, and quantum mechanics. Additionally, reading textbooks, attending lectures and seminars, and solving practice problems can help deepen understanding of the subject.

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