Levinson's theorem

Last updated June 04, 2022

Levinson's theorem is an important theorem in non-relativistic quantum scattering theory. It relates the number of bound states of a potential to the difference in phase of a scattered wave at zero and infinite energies. It was published by Norman Levinson in 1949.^[1]

Statement of theorem

The difference in the $\ell$ -wave phase shift of a scattered wave at zero energy, $\varphi _{\ell }(0)$ , and infinite energy, $\varphi _{\ell }(\infty )$ , for a spherically symmetric potential $V(r)$ is related to the number of bound states $n_{\ell }$ by:

\varphi _{\ell }(0)-\varphi _{\ell }(\infty )=(n_{\ell }+{\frac {1}{2}}N)\pi \

where $N=0$ or $1$ . The case $N=1$ is exceptional and it can only happen in $s$ -wave scattering. The following conditions are sufficient to guarantee the theorem:^[2]

V(r)

continuous in

(0,\infty )

except for a finite number of finite discontinuities

V(r)=O(r^{-3/2+\varepsilon })~{\text{ as }}~r\rightarrow 0~~\varepsilon >0

V(r)=O(r^{-3-\varepsilon })~{\text{ as }}~r\rightarrow \infty ~~\varepsilon >0

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References

↑ Levinson's Theorem
↑ A. Galindo and P. Pascual, Quantum Mechanics II (Springer-Verlag, Berlin, Germany, 1990).

External links

M. Wellner, "Levinson's Theorem (an Elementary Derivation," Atomic Energy Research Establishment, Harwell, England. March 1964.

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[1] Levinson's Theorem

[2] A. Galindo and P. Pascual, Quantum Mechanics II (Springer-Verlag, Berlin, Germany, 1990).

[1]

[2]

Levinson's theorem

Contents

Statement of theorem

Related Research Articles

References

External links