# Mathematics for Quantum Mechanics [duplicate]

What math should I study if I want to get a basic understanding of quantum mechanics and especially to be able to use the Schrodinger's equation.

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## marked as duplicate by Chris White, Manishearth♦Feb 7 '13 at 13:29

Possible duplicate: physics.stackexchange.com/q/5014/2451 , physics.stackexchange.com/q/16814/2451 and links therein. – Qmechanic Sep 30 '12 at 17:56
You need to understand partial differential equations. If you understand this, I would next recommend starting with an introductory book on quantum mechanics and look up the mathematics you don't know as you go. – Mew Oct 1 '12 at 3:28

You should study operator and calculas. You should also have the knowledge of matrix operation.

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A good chunk of the formalism in quantum mechanics involves extensive use of linear algebra. For example, if an operator is given in matrix form, you should know how to compute eigenvalues and eigenvectors. An understanding of group theory is helpful but not required at the basic level. It gives you a better understanding of the formalism for spin, accidental degeneracy in the hydrogen atom, etc. Fourier series and transforms should be at your fingertips. It is very common to frequently switch between momentum space and real space representations. You should familiarize yourself with different representations of the Dirac delta function and learn all the tricks involved in doing Gaussian integrals.

What I described above are tools that one generally uses for a wide variety of problems. Certain mathematical tools, however, might only be used in specific examples. For practical purposes, the Schrödinger equation is solved in the so-called position basis. In this case, your eigenvalue equation is, in general, a partial differential equation (PDE). You should learn how to solve at least the most basic PDEs. You should also look into series solutions of differential equations. Special functions such as Legendre, Laguerre, Airy polynomials etc. would be helpful in certain problems.

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+1 for linear algebra and PDEs. Fourier analysis is a good bridge between linear algebra and partial differential equations. I would strongly suggest studying Fourier analysis, as it also gives you another way of deriving the Heisenberg uncertainty principle. – Alex Nelson Sep 30 '12 at 19:43

Before going inside PDE theory, special functions and all this material other people cited: as for what I understood, you want tu understand Schroedinger equation rather than solve it in strange cases. I'll tell you what I think is the essential to start understanding:

• complex numbers
• linear algebra and calculus

• complex Hilbert spaces and scalar products

• operators in Hilbert spaces
• Fourier transforms
• Dirac's notation