Real Solutions in Time Independent Schrodinger's Equation?

In summary, the time independent Schrodinger's equation (TISE) deals with real terms in the Hamiltonian, allowing for solutions to also be purely real. This is based on the assumptions that the Hamiltonian is a compact self-adjoint operator on a complex separable Hilbert space and its spectral equation has real coefficients. However, even with these conditions, solutions to the spectral equation can still be complex functions.
  • #1
spaghetti3451
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This question is about the time independent schrodinger's equation, but is best posted here.

In the TISE, all the terms in H-hat are real, so it is possible, and not uncommon, for the solutions u(x) to also be purely real.

I don't understand why H-hat is real implies that u (x) is real.
 
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  • #2
One must understand 2 things under the following (admittedly simplifying) 2 assumptions:

i) The Hamiltonian is a compact self-adjoint operator on a complex separable Hilbert space.
ii) Its spectral equation is a PDE/ODE with real coefficients (one coefficient is the spectral value which is always real as the operator is s-adj).

1. A basis of the space of solutions of the PDE/ODE in ii) can always be chosen to be formed by real functions.
2. Even in the conditions of 1, generally, due to the fact that the Hilbert space where solutions of the spectral equations are sought is complex, a solution to the spectral equation is a complex function.
 
  • #3
Boy oh boy. this is too complicated for my level!
 

What is the difference between real and complex functions?

Real functions are those that take real numbers as inputs and outputs real numbers. Complex functions, on the other hand, take complex numbers as inputs and outputs complex numbers.

What are some common examples of real functions?

Some common examples of real functions include linear functions, quadratic functions, exponential functions, and trigonometric functions.

What are some common examples of complex functions?

Some common examples of complex functions include polynomial functions with complex coefficients, trigonometric functions with complex arguments, and logarithmic functions with complex arguments.

How are real and complex functions used in science?

Real and complex functions are essential tools in various fields of science such as physics, engineering, and economics. They are used to model real-world phenomena and make predictions about their behavior.

What are some key properties of real and complex functions?

Real and complex functions share some key properties, such as continuity, differentiability, and periodicity. However, complex functions also have unique properties, such as analyticity and holomorphicity, which make them particularly useful in complex analysis.

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