corrected errors from Wednesday lecture
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@ -330,23 +330,23 @@
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\begin{frame}{Antisymmetry}
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\begin{frame}{Antisymmetry}
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\begin{block}{Problem:}
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\begin{block}{Problem:}
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\violet{\textit{``Show that, for a system of two fermions, the wave function vanishes when they are at the same point in space''}}
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\violet{\textit{``Show that, for a system of two fermions, the wave function vanishes when they are at the same point in spin-space''}}
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\end{block}
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\end{block}
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\pause
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\pause
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\begin{block}{Solution}
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\begin{block}{Solution}
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\blue{Indistinguishable} particles means
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\blue{Indistinguishable} particles means
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\begin{equation}
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\begin{equation}
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\boxed{\abs{\Psi(x_1,x_2)}^2 = \abs{\Psi(x_2,x_1)}^2 \Rightarrow \Psi(x_1,x_2) = \alert{\pm} \Psi(x_2,x_1)}
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\boxed{\abs{\Psi(\bx_1,\bx_2)}^2 = \abs{\Psi(\bx_2,\bx_1)}^2 \Rightarrow \Psi(\bx_1,\bx_2) = \alert{\pm} \Psi(\bx_2,\bx_1)}
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\end{equation}
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\end{equation}
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\\
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\\
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\bigskip
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\bigskip
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\pause
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\pause
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\violet{Bosons} mean \violet{$\Psi(x_1,x_2) = \Psi(x_2,x_1)$} and \orange{Fermions} mean \orange{$\Psi(x_1,x_2) = -\Psi(x_2,x_1)$}
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\violet{Bosons} mean \violet{$\Psi(\bx_1,\bx_2) = \Psi(\bx_2,\bx_1)$} and \orange{Fermions} mean \orange{$\Psi(\bx_1,\bx_2) = -\Psi(\bx_2,\bx_1)$}
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\\
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\\
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\bigskip
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\bigskip
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Let's put them at the same spot, i.e. \blue{$x = x_1 = x_2$}
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Let's put them at the same spot, i.e. \blue{$\bx = \bx_1 = \bx_2$}
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\begin{equation}
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\begin{equation}
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\text{\violet{For Fermions, }} \Psi(x,x) = - \Psi(x,x) \quad \Rightarrow \quad \boxed{\Psi(x,x) = 0}
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\text{\violet{For Fermions, }} \Psi(\bx,\bx) = - \Psi(\bx,\bx) \qq{$\Rightarrow$} \boxed{\Psi(\bx,\bx) = 0}
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\end{equation}
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\end{equation}
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\alert{The wave function vanishes! $\quad \Rightarrow \quad$ This is called the Fermi hole!}
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\alert{The wave function vanishes! $\quad \Rightarrow \quad$ This is called the Fermi hole!}
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\end{block}
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\end{block}
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@ -354,29 +354,29 @@
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\begin{frame}{Antisymmetry (Take 2)}
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\begin{frame}{Antisymmetry (Take 2)}
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\begin{block}{Problem:}
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\begin{block}{Problem:}
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\violet{\textit{``Given two one-electron functions $\chi_1(x)$ and $\chi_2(x)$, could you construct a two-electron (fermionic) wave function $\Psi(x_1,x_2)$?''}}
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\violet{\textit{``Given two one-electron functions $\chi_1(\bx)$ and $\chi_2(\bx)$, could you construct a two-electron (fermionic) wave function $\Psi(\bx_1,\bx_2)$?''}}
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\end{block}
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\end{block}
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\pause
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\pause
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\begin{block}{Solution}
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\begin{block}{Solution}
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A possible solution is
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A possible solution is
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\begin{equation}
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\begin{equation}
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\Psi(x_1,x_2) = \chi_1(x_1) \chi_2(x_2) - \chi_1(x_2) \chi_2(x_1)
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\Psi(\bx_1,\bx_2) = \chi_1(\bx_1) \chi_2(\bx_2) - \chi_1(\bx_2) \chi_2(\bx_1)
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\end{equation}
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\end{equation}
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This has been popularized by \blue{Slater}:
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This has been popularized by \blue{Slater}:
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\begin{equation}
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\begin{equation}
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\boxed{
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\boxed{
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\Psi(x_1,x_2) =
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\Psi(\bx_1,\bx_2) =
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\begin{vmatrix}
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\begin{vmatrix}
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\chi_1(x_1) & \chi_2(x_1) \\
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\chi_1(\bx_1) & \chi_2(\bx_1) \\
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\chi_1(x_2) & \chi_2(x_2) \\
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\chi_1(\bx_2) & \chi_2(\bx_2) \\
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\end{vmatrix}
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\end{vmatrix}
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= \chi_1(x_1) \chi_2(x_2) - \chi_1(x_2) \chi_2(x_1)
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= \chi_1(\bx_1) \chi_2(\bx_2) - \chi_1(\bx_2) \chi_2(\bx_1)
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}
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}
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\end{equation}
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\end{equation}
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\alert{This is called a Slater determinant!}
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\alert{This is called a Slater determinant!}
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\\
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\\
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\bigskip
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\bigskip
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A wave function of the form \green{$\Psi(x_1,x_2) = \chi_1(x_1) \chi_2(x_2)$} is called a \green{Hartree product}
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A wave function of the form \green{$\Psi(\bx_1,\bx_2) = \chi_1(\bx_1) \chi_2(\bx_2)$} is called a \green{Hartree product}
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\end{block}
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\end{block}
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\end{frame}
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\end{frame}
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@ -562,34 +562,34 @@
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\begin{itemize}
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\begin{itemize}
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\item \orange{Coulomb operator}
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\item \orange{Coulomb operator}
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\begin{equation}
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\begin{equation}
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\cJ_{\green{i}}(\blue{1}) \ket{ \chi_{\purple{j}}(\red{2}) }
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\cJ_{\green{j}}(\blue{1}) \ket{ \chi_{\purple{i}}(\blue{1}) }
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= \mel{ \chi_{\green{i}}(\blue{1}) }{ r_{\blue{1}\red{2}}^{-1} }{ \chi_{\green{i}}(\blue{1}) } \ket{ \chi_{\purple{j}}(\red{2}) }
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= \mel{ \chi_{\green{j}}(\red{2}) }{ r_{\blue{1}\red{2}}^{-1} }{ \chi_{\green{j}}(\red{2}) } \ket{ \chi_{\purple{i}}(\blue{1}) }
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= \qty[ \int d\blue{\bx_1} \chi_{\green{i}}^*(\blue{\bx_1}) r_{\blue{1}\red{2}}^{-1} \chi_{\green{i}}(\blue{\bx_1}) ] \ket{ \chi_{\purple{j}}(\red{\bx_2}) }
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= \qty[ \int d\red{\bx_2} \chi_{\green{j}}^*(\red{\bx_2}) r_{\blue{1}\red{2}}^{-1} \chi_{\green{j}}(\red{\bx_2}) ] \ket{ \chi_{\purple{i}}(\blue{\bx_1}) }
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\end{equation}
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\end{equation}
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\item \orange{Coulomb matrix elements}
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\item \orange{Coulomb matrix elements}
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\begin{equation}
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\begin{equation}
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\begin{split}
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\begin{split}
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\cJ_{\green{i}\purple{j}}
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\cJ_{\purple{i}\green{j}}
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& = \mel{\chi_{\purple{j}}(\red{2})}{\cJ_{\green{i}}(\blue{1})}{\chi_{\purple{j}}(\red{2})}
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& = \mel{\chi_{\purple{i}}(\blue{1})}{\cJ_{\green{j}}(\blue{1})}{\chi_{\purple{i}}(\blue{1})}
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= \mel{ \chi_{\green{i}}(\blue{1}) \chi_{\purple{j}}(\red{2}) }{r_{\blue{1}\red{2}}^{-1}}{ \chi_{\green{i}}(\blue{1}) \chi_{\purple{j}}(\red{2})}
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= \mel{ \chi_{\purple{i}}(\blue{1}) \chi_{\green{j}}(\red{2}) }{r_{\blue{1}\red{2}}^{-1}}{ \chi_{\purple{i}}(\blue{1}) \chi_{\green{j}}(\red{2})}
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\\
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\\
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& = \iint \chi_{\green{i}}^*(\blue{\bx_1}) \chi_{\purple{j}}^*(\red{\bx_2}) r_{\blue{1}\red{2}}^{-1} \chi_{\green{i}}(\blue{\bx_1}) \chi_{\green{i}}(\red{\bx_2}) d\blue{\bx_1} d\red{\bx_2}
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& = \iint \chi_{\purple{i}}^*(\blue{\bx_1}) \chi_{\green{j}}^*(\red{\bx_2}) r_{\blue{1}\red{2}}^{-1} \chi_{\purple{i}}(\blue{\bx_1}) \chi_{\green{j}}(\red{\bx_2}) d\blue{\bx_1} d\red{\bx_2}
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\end{split}
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\end{split}
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\end{equation}
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\end{equation}
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\item \violet{(non-local) Exchange operator}
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\item \violet{(non-local) Exchange operator}
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\begin{equation}
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\begin{equation}
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\cK_{\green{i}}(\blue{1}) \ket{ \chi_{\purple{j}}(\red{2}) }
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\cK_{\green{j}}(\blue{1}) \ket{ \chi_{\purple{i}}(\blue{1}) }
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= \mel{ \chi_{\green{i}}(\blue{1}) }{ r_{\blue{1}\red{2}}^{-1} }{ \chi_{\purple{j}}(\blue{1}) } \ket{ \chi_{\green{i}}(\red{2}) }
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= \mel{ \chi_{\green{j}}(\red{2}) }{ r_{\blue{1}\red{2}}^{-1} }{ \chi_{\purple{i}}(\red{2}) } \ket{ \chi_{\green{j}}(\blue{1}) }
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= \qty[ \int \chi_{\green{i}}^*(\blue{\bx_1}) r_{\blue{1}\red{2}}^{-1} \chi_{\purple{j}}(\blue{\bx_1}) d\blue{\bx_1} ] \ket{ \chi_{\green{i}}(\red{\bx_2}) }
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= \qty[ \int d\red{\bx_2} \chi_{\green{j}}^*(\red{\bx_2}) r_{\blue{1}\red{2}}^{-1} \chi_{\purple{i}}(\red{\bx_2}) ] \ket{ \chi_{\green{j}}(\blue{\bx_2}) }
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\end{equation}
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\end{equation}
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\item \violet{Exchange matrix elements}
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\item \violet{Exchange matrix elements}
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\begin{equation}
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\begin{equation}
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\begin{split}
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\begin{split}
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\cK_{\green{i}\purple{j}}
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\cK_{\green{i}\purple{j}}
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& = \mel{\chi_{\purple{j}}(\red{2})}{\cK_{\green{i}}(\blue{1})}{\chi_{\purple{j}}(\red{2})}
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& = \mel{\chi_{\purple{i}}(\blue{1})}{\cK_{\green{j}}(\blue{1})}{\chi_{\purple{i}}(\blue{1})}
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= \mel{ \chi_{\green{i}}(\blue{1}) \chi_{\purple{j}}(\red{2})}{ r_{\blue{1}\red{2}}^{-1} }{ \chi_{\purple{j}}(\blue{1}) \chi_{\green{i}}(\red{2}) }
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= \mel{ \chi_{\purple{i}}(\blue{1}) \chi_{\green{j}}(\red{2}) }{r_{\blue{1}\red{2}}^{-1}}{ \chi_{\green{j}}(\blue{1}) \chi_{\purple{i}}(\red{2})}
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\\
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\\
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& = \iint \chi_{\green{i}}^*(\blue{\bx_1}) \chi_{\purple{j}}^*(\red{\bx_2}) r_{\blue{1}\red{2}}^{-1} \chi_{\purple{j}}(\blue{\bx_1}) \chi_{\green{i}}(\red{\bx_2}) d\blue{\bx_1} d\red{\bx_2}
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& = \iint \chi_{\purple{i}}^*(\blue{\bx_1}) \chi_{\green{j}}^*(\red{\bx_2}) r_{\blue{1}\red{2}}^{-1} \chi_{\green{j}}(\blue{\bx_1}) \chi_{\purple{i}}(\red{\bx_2}) d\blue{\bx_1} d\red{\bx_2}
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\end{split}
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\end{split}
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\end{equation}
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\end{equation}
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\end{itemize}
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\end{itemize}
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@ -634,19 +634,27 @@
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\end{frame}
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\end{frame}
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\begin{frame}{Permutation symmetry}
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\begin{frame}{Permutation symmetry}
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\begin{block}{Permutation symmetry in physicist notation}
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\begin{block}{Permutation symmetry in physicts' notations}
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\begin{equation}
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\begin{equation}
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\braket{ij}{kl}
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\braket{ij}{kl}
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= \braket{\chi_i \chi_j}{\chi_k \chi_l}
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= \braket{\chi_i \chi_j}{\chi_k \chi_l}
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= \iint \chi_i^*(\bx_1) \chi_j^*(\bx_2) \frac{1}{r_{12}} \chi_k(\bx_1) \chi_l(\bx_2) d\bx_1 d\bx_2
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= \iint \chi_i^*(\bx_1) \chi_j^*(\bx_2) \frac{1}{r_{12}} \chi_k(\bx_1) \chi_l(\bx_2) d\bx_1 d\bx_2
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\end{equation}
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\end{equation}
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\begin{align}
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\begin{equation}
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\qq*{\red{Complex-valued integrals:}} &
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\qq*{\red{Complex-valued integrals:}}
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\braket{ij}{kl} = \braket{ji}{lk} = \braket{kl}{ij}^*
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\braket{ij}{kl} = \braket{ji}{lk} = \braket{kl}{ij}^* = \braket{lk}{ji}^*
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\\
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\end{equation}
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\qq*{\green{Real-valued integrals:}} &
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\end{block}
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\braket{ij}{kl} = \braket{ji}{kl} = \braket{ij}{lk} = \braket{ji}{lk} = \braket{kl}{ij} = \braket{lk}{ij} = \braket{kl}{ji} = \braket{lk}{ji}
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\begin{block}{Permutation symmetry in chemists' notations}
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\end{align}
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\begin{equation}
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[ij|kl]
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= [\chi_i \chi_j|\chi_k \chi_l]
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= \iint \chi_i^*(\bx_1) \chi_j(\bx_1) \frac{1}{r_{12}} \chi_k^*(\bx_2) \chi_l(\bx_2) d\bx_1 d\bx_2
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\end{equation}
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\begin{equation}
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\qq*{\green{Real-valued integrals:}}
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[ij|kl] = [ji|kl] = [ij|lk] = [ji|lk] = [kl|ij] = [lk|ij] = [kl|ji] = [lk|ji]
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\end{equation}
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\end{block}
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\end{block}
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\end{frame}
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\end{frame}
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@ -664,7 +672,7 @@
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\end{block}
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\end{block}
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\begin{block}{\orange{Case 2 = differ by one spinorbital}: $\ket{K} = \ket{\ldots m n \ldots}$ and $\ket{L} = \ket{\ldots p n \ldots}$}
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\begin{block}{\orange{Case 2 = differ by one spinorbital}: $\ket{K} = \ket{\ldots m n \ldots}$ and $\ket{L} = \ket{\ldots p n \ldots}$}
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\begin{equation}
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\begin{equation}
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\mel{K}{\cO_1}{L} = \sum_m \mel{m}{h}{p}
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\mel{K}{\cO_1}{L} = \mel{m}{h}{p}
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\end{equation}
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\end{equation}
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\end{block}
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\end{block}
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\begin{block}{\red{Case 3 = differ by two spinorbitals}: $\ket{K} = \ket{\ldots m n \ldots}$ and $\ket{L} = \ket{\ldots p q \ldots}$}
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\begin{block}{\red{Case 3 = differ by two spinorbitals}: $\ket{K} = \ket{\ldots m n \ldots}$ and $\ket{L} = \ket{\ldots p q \ldots}$}
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