Key equations from quantum statistical tools: Difference between revisions

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Equilibrium

Expectation values

$A = T r [{\hat{ρ}}_{e q} \hat{A}]$

Density matrix of fermions in equilibrium

using spectral decomposition:

${\hat{ρ}}_{e q} = \sum_{α} f (E_{α}) | E_{α} ⟩ ⟨ E_{α} | = f (\hat{H} - μ \hat{I})$

using Green functions:

${\hat{ρ}}_{e q} = - \frac{1}{π} \int d E I m G^{r} f (E)$

Fermi-Dirac distribution function: $f (E) = 1 / [\exp ((E - μ) / k_{B} T) + 1]$

Hamiltonian and its spectral decomposition: $\hat{H} = \sum_{α} E_{α} | E_{α} ⟩ ⟨ E_{α} |$

function of Hamiltonian: $F (\hat{H}) = \sum_{α} F (E_{α}) | E_{α} ⟩ ⟨ E_{α} |$

Green operators:

${\hat{G}}^{r, a} (E) = [E \hat{I} - \hat{H} \pm i η]^{- 1}$

$I m {\hat{G}}^{r} = ({\hat{G}}^{r} - {\hat{G}}^{a}) / 2 i$

Charge density

charge density operator: $\hat{n} (𝐫) = | 𝐫 ⟩ ⟨ 𝐫 |$

expectation value: $n (𝐫) = T r [{\hat{ρ}}_{e q} | 𝐫 ⟩ ⟨ 𝐫 |] = ⟨ 𝐫 | {\hat{ρ}}_{e q} | 𝐫 ⟩$ (in some discrete representation these is just diagonal matrix element)

Density of states

definition of total DOS: $g (E) = \sum_{α} δ (E - E_{α})$ (with possible normalization factors like $2_{s} / V$ )

definition of LDOS: $g (E) = \int d^{3} 𝐫 g (𝐫, E)$

LDOS using wavefunctions: $n (𝐫) = T r [{\hat{ρ}}_{e q} | 𝐫 ⟩ ⟨ 𝐫 |] = \sum_{α} | Ψ_{α} (𝐫) |^{2} f (E_{α}) = \int d E [\sum_{α} | Ψ_{α} (𝐫) |^{2} δ (E - E_{α})] f (E) = \int d E g (𝐫, E) f (E)$

LDOS using Green functions:

$g (𝐫, E) = - \frac{1}{π} ⟨ 𝐫 | I m {\hat{G}}^{r} (E) | 𝐫 ⟩$

total DOS using Green functions:

$g (E) = - \frac{1}{π} T r [{\hat{G}}^{r} (E)] = - \frac{1}{π} \int d^{3} 𝐫 ⟨ 𝐫 | I m {\hat{G}}^{r} (E) | 𝐫 ⟩$

Nonequilibrium

Expectation values

$A = T r [{\hat{ρ}}_{n e q} \hat{A}]$

Current operators:

@@ Line 21: / Line 21: @@
 * function of Hamiltonian: <math> F(\hat{H}) =  \sum_\alpha F(E_\alpha) |E_\alpha \rangle \langle E_\alpha| </math>
-* Green operators: <math> \hat{G}^{r,a} = [E\hat{I}-\hat{H} \pm i\eta]^{-1} </math>
+* Green operators:
+<math> \hat{G}^{r,a}(E) = [E\hat{I}-\hat{H} \pm i\eta]^{-1} </math>
+<math> \mathrm{Im} \hat{G}^r = (\hat{G}^{r} - \hat{G}^a)/2i </math>
 ===Charge density===
@@ Line 40: / Line 44: @@
 <math> g(\mathbf{r},E) = -\frac{1}{\pi} \langle \mathbf{r} |\mathrm{Im} \hat{G}^r(E) | \mathbf{r} \rangle </math>
+* total DOS using Green functions:
+<math> g(E) = -\frac{1}{\pi} \mathrm{Tr}[ \hat{G}^r(E)] = -\frac{1}{\pi} \int d^3 \mathbf{r} \, \langle \mathbf{r} |\mathrm{Im} \hat{G}^r(E) | \mathbf{r} \rangle  </math>
 ==Nonequilibrium==
-*Expectation values:
+===Expectation values===
+<math> A = \mathrm{Tr}[\hat{\rho}_\mathrm{neq} \hat{A}] </math>
-*Current operator:
+*Current operators:

Key equations from quantum statistical tools: Difference between revisions

Latest revision as of 14:32, 27 September 2012

Contents

Equilibrium

Expectation values

Density matrix of fermions in equilibrium

Charge density

Density of states

Nonequilibrium

Expectation values

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