Scattering rate

A formula may be derived mathematically for the rate of scattering when a beam of electrons passes through a material.

The interaction picture

Define the unperturbed Hamiltonian by ${\displaystyle H_{0}}$ , the time dependent perturbing Hamiltonian by ${\displaystyle H_{1}}$  and total Hamiltonian by ${\displaystyle H}$ .

The eigenstates of the unperturbed Hamiltonian are assumed to be

${\displaystyle H=H_{0}+H_{1}\ }$ 

${\displaystyle H_{0}|k\rangle =E(k)|k\rangle }$ 

In the interaction picture, the state ket is defined by

${\displaystyle |k(t)\rangle _{I}=e^{iH_{0}t/\hbar }|k(t)\rangle _{S}=\sum _{k'}c_{k'}(t)|k'\rangle }$ 

By a Schrödinger equation, we see

${\displaystyle i\hbar {\frac {\partial }{\partial t}}|k(t)\rangle _{I}=H_{1I}|k(t)\rangle _{I}}$ 

which is a Schrödinger-like equation with the total ${\displaystyle H}$  replaced by ${\displaystyle H_{1I}}$ .

Solving the differential equation, we can find the coefficient of n-state.

${\displaystyle c_{k'}(t)=\delta _{k,k'}-{\frac {i}{\hbar }}\int _{0}^{t}dt'\;\langle k'|H_{1}(t')|k\rangle \,e^{-i(E_{k}-E_{k'})t'/\hbar }}$ 

where, the zeroth-order term and first-order term are

${\displaystyle c_{k'}^{(0)}=\delta _{k,k'}}$ 

${\displaystyle c_{k'}^{(1)}=-{\frac {i}{\hbar }}\int _{0}^{t}dt'\;\langle k'|H_{1}(t')|k\rangle \,e^{-i(E_{k}-E_{k'})t'/\hbar }}$ 

The transition rate

The probability of finding ${\displaystyle |k'\rangle }$  is found by evaluating ${\displaystyle |c_{k'}(t)|^{2}}$ .

In case of constant perturbation,${\displaystyle c_{k'}^{(1)}}$  is calculated by

${\displaystyle c_{k'}^{(1)}={\frac {\langle \ k'|H_{1}|k\rangle }{E_{k'}-E_{k}}}(1-e^{i(E_{k'}-E_{k})t/\hbar })}$ 

${\displaystyle |c_{k'}(t)|^{2}=|\langle \ k'|H_{1}|k\rangle |^{2}{\frac {sin^{2}({\frac {E_{k'}-E_{k}}{2\hbar }}t)}{({\frac {E_{k'}-E_{k}}{2\hbar }})^{2}}}{\frac {1}{\hbar ^{2}}}}$ 

Using the equation which is

${\displaystyle \lim _{\alpha \rightarrow \infty }{\frac {1}{\pi }}{\frac {sin^{2}(\alpha x)}{\alpha x^{2}}}=\delta (x)}$ 

The transition rate of an electron from the initial state ${\displaystyle k}$  to final state ${\displaystyle k'}$  is given by

${\displaystyle P(k,k')={\frac {2\pi }{\hbar }}|\langle \ k'|H_{1}|k\rangle |^{2}\delta (E_{k'}-E_{k})}$ 

where ${\displaystyle E_{k}}$  and ${\displaystyle E_{k'}}$  are the energies of the initial and final states including the perturbation state and ensures the ${\displaystyle \delta }$ -function indicate energy conservation.

The scattering rate

The scattering rate w(k) is determined by summing all the possible finite states k' of electron scattering from an initial state k to a final state k', and is defined by

${\displaystyle w(k)=\sum _{k'}P(k,k')={\frac {2\pi }{\hbar }}\sum _{k'}|\langle \ k'|H_{1}|k\rangle |^{2}\delta (E_{k'}-E_{k})}$ 

The integral form is

${\displaystyle w(k)={\frac {2\pi }{\hbar }}{\frac {L^{3}}{(2\pi )^{3}}}\int d^{3}k'|\langle \ k'|H_{1}|k\rangle |^{2}\delta (E_{k'}-E_{k})}$ 

References

• C. Hamaguchi (2001). Basic Semiconductor Physics. Springer. pp. 196–253.
• J.J. Sakurai. Modern Quantum Mechanics. Addison Wesley Longman. pp. 316–319.