Phy5646/Born-Oppenheimer Approximation: Difference between revisions
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Consider R is fixed, to solve the schrodinger equation of electron. | Consider R is fixed, to solve the schrodinger equation of electron. | ||
Second step: | Second step: | ||
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<math>\left|\Psi >=\int \Psi \left(\overset{\rightharpoonup }{R}\right)\right|\overset{\rightharpoonup }{R}>|n\left(\overset{\rightharpoonup }{R}\right)>d^3R</math> | <math>\left|\Psi >=\int \Psi \left(\overset{\rightharpoonup }{R}\right)\right|\overset{\rightharpoonup }{R}>|n\left(\overset{\rightharpoonup }{R}\right)>d^3R</math> | ||
To solve: <math><\overset{\rightharpoonup }{R'}\left|<n\left(\overset{\rightharpoonup }{R}\right)\right|H|\Psi ></math> | |||
You will find: | |||
<math> \ | <math>\left[\frac{1}{2M}\left(\overset{\rightharpoonup }{P}-\overset{\rightharpoonup }{A}^{(n)}\right)^2+\Phi ^{(n)}+E_n\left(\overset{\rightharpoonup }{R}\right)\right]\Psi \left(\overset{\rightharpoonup }{R}\right)=E\Psi \left(\overset{\rightharpoonup }{R}\right)</math> | ||
The Berry Vector Potential: | The Berry Vector Potential: | ||
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The Berry Scalar Potential: | The Berry Scalar Potential: | ||
<math> \Phi^{(n)} = \frac{\hbar^2}{2m} [ \langle \overrightarrow{\nabla}_R n(R) | \overrightarrow{\nabla}_R n(R) \rangle - \langle \overrightarrow{\nabla}_R n(R) | n(R) \rangle \langle n(R) | \overrightarrow{\nabla}_R n(R) \rangle ]</math> | <math> \Phi^{(n)} = \frac{\hbar^2}{2m} [ \langle \overrightarrow{\nabla}_R n(R) | \overrightarrow{\nabla}_R n(R) \rangle - \langle \overrightarrow{\nabla}_R n(R) | n(R) \rangle \langle n(R) | \overrightarrow{\nabla}_R n(R) \rangle ]</math> | ||
It's a method to get the energy of the system. Indispensable method in Quantum Chemistry. | |||
Latest revision as of 20:02, 20 April 2010
Consider the problem of two protons and one electron.
As for the two protons, we consider the two bodies problem as one body problem.
The wave function is:
First step:
Consider R is fixed, to solve the schrodinger equation of electron.
Second step:
Seek an solution of H as:
To solve:
You will find:
![{\displaystyle \left[{\frac {1}{2M}}\left({\overset {\rightharpoonup }{P}}-{\overset {\rightharpoonup }{A}}^{(n)}\right)^{2}+\Phi ^{(n)}+E_{n}\left({\overset {\rightharpoonup }{R}}\right)\right]\Psi \left({\overset {\rightharpoonup }{R}}\right)=E\Psi \left({\overset {\rightharpoonup }{R}}\right)}](https://wikimedia.org/api/rest_v1/media/math/render/svg/1166e5aa87c4e004224ab2a05e05842e840b50d5)
The Berry Vector Potential:
The Berry Scalar Potential:
![{\displaystyle \Phi ^{(n)}={\frac {\hbar ^{2}}{2m}}[\langle {\overrightarrow {\nabla }}_{R}n(R)|{\overrightarrow {\nabla }}_{R}n(R)\rangle -\langle {\overrightarrow {\nabla }}_{R}n(R)|n(R)\rangle \langle n(R)|{\overrightarrow {\nabla }}_{R}n(R)\rangle ]}](https://wikimedia.org/api/rest_v1/media/math/render/svg/1bdff9df02da5511e0624427115677585263f542)
It's a method to get the energy of the system. Indispensable method in Quantum Chemistry.