Total Energy and Forces: Ver. 1.3

The OpenMX is based on density functional theories (DFT), the norm-conserving pseudopotentials, and local pseudo-atomic basis functions. The Kohn-Sham (KS) Bloch functions ${\psi }_{\mu }$ are expanded in a form of linear combination of pseudo-atomic basis functions (LCPAO) ${\varphi }_{i\alpha }$ centered on site ${\tau }_i$ by

${\psi }_{\sigma \mu }^{(𝐤)}(𝐫)={\displaystyle \frac{1}{\sqrt{N}}}{\displaystyle \sum _{\mathrm{n}}^N}{\mathrm{e}}^{\mathrm{i}{𝐑}_{\mathrm{n}}\cdot 𝐤}{\displaystyle \sum _{i\alpha }}{c}_{\sigma \mu ,i\alpha }^{(𝐤)}{\varphi }_{i\alpha }(𝐫-{\tau }_i-{𝐑}_{\mathrm{n}}),$

(1)

where $c$ and $\varphi$ are an expansion coefficient and pseudo-atomic function, ${𝐑}_{\mathrm{n}}$ a lattice vector, $i$ a site index, $\sigma$ $(\uparrow$ $\mathrm{or}$ $\downarrow )$ spin index, $\alpha \equiv (plm)$ an organized orbital index with a multiplicity index $p$, an angular momentum quantum number $l$, and a magnetic quantum number $m$. The charge density operator ${\widehat{n}}_{\sigma }$ for the spin index $\sigma$ is given by

${\widehat{n}}_{\sigma }={\displaystyle \frac{1}{V_{\mathrm{B}}}}{\displaystyle {\int }_{\mathrm{B}}}𝑑k^3{\displaystyle \sum _{\mu }^{\mathrm{occ}}}|{\psi }_{\sigma \mu }^{(𝐤)}⟩⟨{\psi }_{\sigma \mu }^{(𝐤)}|,$

(2)

where ${\int }_{\mathrm{B}}$ means the integration over the first Brillouin zone of which volume is $V_{\mathrm{B}}$, and ${\sum }^{\mathrm{occ}}$ means the summation over occupied states. The charge density $n_{\sigma }(𝐫)$ with the spin index $\sigma$ is found as

	$n_{\sigma }(𝐫)$	$=$	$⟨𝐫|{\widehat{n}}_{\sigma }|𝐫⟩,$		(3)
		$=$	${\displaystyle \frac{1}{V_{\mathrm{B}}}}{\displaystyle {\int }_{\mathrm{B}}}𝑑k^3{\displaystyle \sum _{\mu }^{\mathrm{occ}}}⟨𝐫|{\psi }_{\sigma \mu }^{(𝐤)}⟩⟨{\psi }_{\sigma \mu }^{(𝐤)}|𝐫⟩,$
		$=$	${\displaystyle \frac{1}{V_{\mathrm{B}}}}{\displaystyle {\int }_{\mathrm{B}}}𝑑k^3{\displaystyle \sum _{\mathrm{n}}^N}{\displaystyle \sum _{i\alpha ,j\beta }}{\displaystyle \sum _{\mu }^{\mathrm{occ}}}{\mathrm{e}}^{\mathrm{i}{𝐑}_{\mathrm{n}}\cdot 𝐤}{c}_{\sigma \mu ,i\alpha }^{(𝐤)*}{c}_{\sigma \mu ,j\beta }^{(𝐤)}{\varphi }_{i\alpha }(𝐫-{\tau }_i){\varphi }_{j\beta }(𝐫-{\tau }_j-{𝐑}_{\mathrm{n}}),$
		$=$	${\displaystyle \sum _{\mathrm{n}}^N}{\displaystyle \sum _{i\alpha ,j\beta }}{\rho }_{\sigma ,i\alpha j\beta }^{({𝐑}_{\mathrm{n}})}{\varphi }_{i\alpha }(𝐫-{\tau }_i){\varphi }_{j\beta }(𝐫-{\tau }_j-{𝐑}_{\mathrm{n}})$

with a density matrix defined by

${\rho }_{\sigma ,i\alpha j\beta }^{({𝐑}_{\mathrm{n}})}={\displaystyle \frac{1}{V_{\mathrm{B}}}}{\displaystyle {\int }_{\mathrm{B}}}𝑑k^3{\displaystyle \sum _{\mu }^{\mathrm{occ}}}{\mathrm{e}}^{\mathrm{i}{𝐑}_{\mathrm{n}}\cdot 𝐤}{c}_{\sigma \mu ,i\alpha }^{(𝐤)*}{c}_{\sigma \mu ,j\beta }^{(𝐤)}.$

(4)

Although it is assumed that the electronic temperature is zero in this notes, OpenMX uses the Fermi-Dirac function with a finite temperature in the practical implementation. Therefore, the force on atom becomes inaccurate for metallic systems or very high temperature. The total charge density $n$ is the sum of $n_{\uparrow }$ and $n_{\downarrow }$ as follows:

$n(𝐫)=n_{\uparrow }(𝐫)+n_{\downarrow }(𝐫).$

(5)

Also, it is convenient to define a difference charge density $\delta n(𝐫)$ for later discussion as

	$\delta n(𝐫)$	$=$	$n(𝐫)-n^{(\mathrm{a})}(𝐫),$		(6)
		$=$	$n(𝐫)-{\displaystyle \sum _i}{n}_i^{(\mathrm{a})}(𝐫),$

where $n_i^{(\mathrm{a})}(𝐫)$ is an atomic charge density evaluated by a confinement atomic calculations associated with the site $i$.

Within the local density approximation (LDA) and generalized gradient approximation (GGA), the total energy of the collinear case is given by the sum of the kinetic energy $E_{\mathrm{kin}}$, the electron-core Coulomb energy $E_{\mathrm{ec}}$, the electron-electron Coulomb energy $E_{\mathrm{ee}}$, the exchange-correlation energy $E_{\mathrm{xc}}$, and the core-core Coulomb energy $E_{\mathrm{cc}}$ as

$E_{\mathrm{tot}}=E_{\mathrm{kin}}+E_{\mathrm{ec}}+E_{\mathrm{ee}}+E_{\mathrm{xc}}+E_{\mathrm{cc}}.$

(7)

The kinetic energy $E_{\mathrm{kin}}$ is given by

	$E_{\mathrm{kin}}$	$=$	${\displaystyle \frac{1}{V_{\mathrm{B}}}}{\displaystyle {\int }_{\mathrm{B}}}𝑑k^3{\displaystyle \sum _{\sigma }}{\displaystyle \sum _{\mu }^{\mathrm{occ}}}⟨{\psi }_{\sigma \mu }^{(𝐤)}|\widehat{T}|{\psi }_{\sigma \mu }^{(𝐤)}⟩,$		(8)
		$=$	${\displaystyle \frac{1}{V_{\mathrm{B}}}}{\displaystyle {\int }_{\mathrm{B}}}𝑑k^3{\displaystyle \sum _{\sigma }}{\displaystyle \sum _{\mu }^{\mathrm{occ}}}{\displaystyle \sum _{\mathrm{n}}^N}{\displaystyle \sum _{i\alpha ,j\beta }}{\mathrm{e}}^{\mathrm{i}{𝐑}_{\mathrm{n}}\cdot 𝐤}{c}_{\sigma \mu ,i\alpha }^{(𝐤)*}{c}_{\sigma \mu ,j\beta }^{(𝐤)}⟨{\varphi }_{i\alpha }(𝐫-{\tau }_i)|\widehat{T}|{\varphi }_{j\beta }(𝐫-{\tau }_j-{𝐑}_{\mathrm{n}})⟩,$
		$=$	${\displaystyle \sum _{\sigma }}{\displaystyle \sum _{\mathrm{n}}^N}{\displaystyle \sum _{i\alpha ,j\beta }}{\rho }_{\sigma ,i\alpha j\beta }^{({𝐑}_{\mathrm{n}})}{h}_{i\alpha j\beta ,\mathrm{kin}}^{({𝐑}_{\mathrm{n}})}.$

The electron-core Coulomb energy $E_{\mathrm{ec}}$ is given by two contributions $E_{\mathrm{ec}}^{(\mathrm{L})}$ and $E_{\mathrm{ec}}^{(\mathrm{NL})}$ related to the local and non-local parts of pseudopotentials:

	$E_{\mathrm{ec}}$	$=$	$E_{\mathrm{ec}}^{(\mathrm{L})}+E_{\mathrm{ec}}^{(\mathrm{NL})},$		(9)
		$=$	${\displaystyle \frac{1}{V_{\mathrm{B}}}}{\displaystyle {\int }_{\mathrm{B}}}𝑑k^3{\displaystyle \sum _{\sigma }}{\displaystyle \sum _{\mu }^{\mathrm{occ}}}⟨{\psi }_{\sigma \mu }^{(𝐤)}|{\displaystyle \sum _I}\{V_{\mathrm{core},I}(𝐫-{\tau }_I)+V_{\mathrm{NL},I}(𝐫-{\tau }_I)\}|{\psi }_{\sigma \mu }^{(𝐤)}⟩,$
		$=$	${\displaystyle \frac{1}{V_{\mathrm{B}}}}{\displaystyle {\int }_{\mathrm{B}}}𝑑k^3{\displaystyle \sum _{\sigma }}{\displaystyle \sum _{\mu }^{\mathrm{occ}}}{\displaystyle \sum _{\mathrm{n}}^N}{\displaystyle \sum _{i\alpha ,j\beta }}{\mathrm{e}}^{\mathrm{i}{𝐑}_{\mathrm{n}}\cdot 𝐤}{c}_{\sigma \mu ,i\alpha }^{(𝐤)*}{c}_{\sigma \mu ,j\beta }^{(𝐤)}⟨{\varphi }_{i\alpha }(𝐫-{\tau }_i)|{\displaystyle \sum _I}{V}_{\mathrm{core},I}(𝐫-{\tau }_I)|{\varphi }_{j\beta }(𝐫-{\tau }_j-{𝐑}_{\mathrm{n}})⟩$
		$+$	${\displaystyle \frac{1}{V_{\mathrm{B}}}}{\displaystyle {\int }_{\mathrm{B}}}𝑑k^3{\displaystyle \sum _{\sigma }}{\displaystyle \sum _{\mu }^{\mathrm{occ}}}{\displaystyle \sum _{\mathrm{n}}^N}{\displaystyle \sum _{i\alpha ,j\beta }}{\mathrm{e}}^{\mathrm{i}{𝐑}_{\mathrm{n}}\cdot 𝐤}{c}_{\sigma \mu ,i\alpha }^{(𝐤)*}{c}_{\sigma \mu ,j\beta }^{(𝐤)}⟨{\varphi }_{i\alpha }(𝐫-{\tau }_i)|{\displaystyle \sum _I}{V}_{\mathrm{NL},I}(𝐫-{\tau }_I)|{\varphi }_{j\beta }(𝐫-{\tau }_j-{𝐑}_{\mathrm{n}})⟩$
		$=$	${\displaystyle \sum _{\sigma }}{\displaystyle \sum _{\mathrm{n}}^N}{\displaystyle \sum _{i\alpha ,j\beta }}{\rho }_{\sigma ,i\alpha j\beta }^{({𝐑}_{\mathrm{n}})}⟨{\varphi }_{i\alpha }(𝐫-{\tau }_i)|{\displaystyle \sum _I}{V}_{\mathrm{core},I}(𝐫-{\tau }_I)|{\varphi }_{j\beta }(𝐫-{\tau }_j-{𝐑}_{\mathrm{n}})⟩$
		$+$	${\displaystyle \sum _{\sigma }}{\displaystyle \sum _{\mathrm{n}}^N}{\displaystyle \sum _{i\alpha ,j\beta }}{\rho }_{\sigma ,i\alpha j\beta }^{({𝐑}_{\mathrm{n}})}⟨{\varphi }_{i\alpha }(𝐫-{\tau }_i)|{\displaystyle \sum _I}{V}_{\mathrm{NL},I}(𝐫-{\tau }_I)|{\varphi }_{j\beta }(𝐫-{\tau }_j-{𝐑}_{\mathrm{n}})⟩,$

where $V_{\mathrm{core},I}$ and $V_{\mathrm{NL},I}$ are the local and non-local parts of pseudopotential located on a site $I$. Thus, we have

	$E_{\mathrm{ec}}^{(\mathrm{L})}$	$=$	${\displaystyle \sum _{\sigma }}{\displaystyle \sum _{\mathrm{n}}^N}{\displaystyle \sum _{i\alpha ,j\beta }}{\rho }_{\sigma ,i\alpha j\beta }^{({𝐑}_{\mathrm{n}})}⟨{\varphi }_{i\alpha }(𝐫-{\tau }_i)|{\displaystyle \sum _I}{V}_{\mathrm{core},I}(𝐫-{\tau }_I)|{\varphi }_{j\beta }(𝐫-{\tau }_j-{𝐑}_{\mathrm{n}})⟩,$		(10)
		$=$	${\displaystyle \int 𝑑r^{3}n(𝐫)\sum _I{V}_{\mathrm{core},I}(𝐫-{\tau }_I)}.$

$E_{\mathrm{ec}}^{(\mathrm{NL})}$

$=$

${\displaystyle \sum _{\sigma }}{\displaystyle \sum _{\mathrm{n}}^N}{\displaystyle \sum _{i\alpha ,j\beta }}{\rho }_{\sigma ,i\alpha j\beta }^{({𝐑}_{\mathrm{n}})}⟨{\varphi }_{i\alpha }(𝐫-{\tau }_i)|{\displaystyle \sum _I}{V}_{\mathrm{NL},I}(𝐫-{\tau }_I)|{\varphi }_{j\beta }(𝐫-{\tau }_j-{𝐑}_{\mathrm{n}})⟩.$

(11)

The electron-electron Coulomb energy $E_{\mathrm{ee}}$ is given by

	$E_{\mathrm{ee}}$	$=$	${\displaystyle \frac{1}{2}}{\displaystyle \int \int 𝑑r^3𝑑r^{\prime 3}\frac{n(𝐫)n({𝐫}^{\prime })}{|𝐫-{𝐫}^{\prime }|}},$		(12)
		$=$	${\displaystyle \frac{1}{2}}{\displaystyle \int 𝑑r^{3}n(𝐫)V_{\mathrm{H}}(𝐫)},$
		$=$	${\displaystyle \frac{1}{2}}{\displaystyle \int 𝑑r^{3}n(𝐫)\{V_{\mathrm{H}}^{(\mathrm{a})}(𝐫)+\delta V_{\mathrm{H}}(𝐫)\}},$

where $V_{\mathrm{H}}$ is decomposed into two contributions $V_{\mathrm{H}}^{(\mathrm{a})}$ and $\delta V_{\mathrm{H}}(𝐫)$ coming from the superposition of atomic charge densities and the difference charge density $\delta n(𝐫)$ defined by

	$V_{\mathrm{H}}^{(\mathrm{a})}(𝐫)$	$=$	${\displaystyle \sum _I}{\displaystyle \int 𝑑r^{\prime 3}\frac{n_I^{(\mathrm{a})}(𝐫)}{|𝐫-{𝐫}^{\prime }|}},$		(13)
		$=$	${\displaystyle \sum _I}{V}_{\mathrm{H},I}^{(\mathrm{a})}(𝐫-{\tau }_I),$

$\delta V_{\mathrm{H}}(𝐫)$

$=$

${\displaystyle \int 𝑑r^{\prime 3}\frac{\delta n(𝐫)}{|𝐫-{𝐫}^{\prime }|}}.$

(14)

Within the LDA, the exchange-correlation energy $E_{\mathrm{xc}}$ is given by

$E_{\mathrm{xc}}={\displaystyle \int 𝑑r^3\{n_{\uparrow }(𝐫)+n_{\downarrow }(𝐫)+n_{\mathrm{pcc}}(𝐫)\}{ϵ}_{\mathrm{xc}}(n_{\uparrow }+\frac{1}{2}{n}_{\mathrm{pcc}},n_{\downarrow }+\frac{1}{2}{n}_{\mathrm{pcc}})},$

(15)

where $n_{\mathrm{pcc}}$ is a charge density used for a partial core correction (PCC). The core-core Coulomb energy $E_{\mathrm{cc}}$ is given as repulsive Coulomb interactions among effective core charge $Z_I$ considered in the generation of pseudopotentials by

$E_{\mathrm{cc}}={\displaystyle \frac{1}{2}}{\displaystyle \sum _{I,J}}{\displaystyle \frac{Z_I{Z}_J}{|{\tau }_I-{\tau }_J|}}.$

(16)

As discussed in the paper [1], for numerical accuracy and efficiency it is important to reorganize the sum of three terms $E_{\mathrm{ec}}^{(L)}$, $E_{\mathrm{ee}}$, and $E_{\mathrm{cc}}$, as follows:

	$E_{\mathrm{ec}}^{(L)}+E_{\mathrm{ee}}+E_{\mathrm{cc}}$	$=$	${\displaystyle \int 𝑑r^{3}n(𝐫)\sum _I{V}_{\mathrm{core},I}(𝐫-{\tau }_I)}+{\displaystyle \int 𝑑r^{3}n(𝐫)V_{\mathrm{H}}^{(\mathrm{a})}(𝐫)}-{\displaystyle \int 𝑑r^{3}n(𝐫)V_{\mathrm{H}}^{(\mathrm{a})}(𝐫)}$		(17)
			$+{\displaystyle \frac{1}{2}}{\displaystyle \int 𝑑r^{3}n(𝐫)\{V_{\mathrm{H}}^{(\mathrm{a})}(𝐫)+\delta V_{\mathrm{H}}(𝐫)\}}+{\displaystyle \frac{1}{2}}{\displaystyle \int 𝑑r^3{n}^{(\mathrm{a})}(𝐫)V_{\mathrm{H}}^{(\mathrm{a})}(𝐫)}-{\displaystyle \frac{1}{2}}{\displaystyle \int 𝑑r^3{n}^{(\mathrm{a})}(𝐫)V_{\mathrm{H}}^{(\mathrm{a})}(𝐫)}$
			$+{\displaystyle \frac{1}{2}}{\displaystyle \sum _{I,J}}{\displaystyle \frac{Z_I{Z}_J}{|{\tau }_I-{\tau }_J|}},$
		$=$	${\displaystyle \int 𝑑r^{3}n(𝐫)\sum _I{V}_{\mathrm{na},I}(𝐫-{\tau }_I)}+{\displaystyle \frac{1}{2}}{\displaystyle \int 𝑑r^{3}n(𝐫)\delta V_{\mathrm{H}}(𝐫)}-{\displaystyle \frac{1}{2}}{\displaystyle \int 𝑑r^3\delta n(𝐫)V_{\mathrm{H}}^{(\mathrm{a})}(𝐫)}$
			$+{\displaystyle \frac{1}{2}}{\displaystyle \sum _{I,J}}\left[{\displaystyle \frac{Z_I{Z}_J}{|{\tau }_I-{\tau }_J|}}-{\displaystyle \int 𝑑r^3{n}_I^{(\mathrm{a})}(𝐫)V_{\mathrm{H},J}^{(\mathrm{a})}(𝐫)}\right],$
		$=$	${\displaystyle \int 𝑑r^{3}n(𝐫)\sum _I{V}_{\mathrm{na},I}(𝐫-{\tau }_I)}+{\displaystyle \frac{1}{2}}{\displaystyle \int \delta n(𝐫)\delta V_{\mathrm{H}}(𝐫)𝑑𝐫}$
			$+{\displaystyle \frac{1}{2}}{\displaystyle \sum _{I,J}}\left[{\displaystyle \frac{Z_I{Z}_J}{|{\tau }_I-{\tau }_J|}}-{\displaystyle \int n_I^{(\mathrm{a})}(𝐫)V_{\mathrm{H},J}^{(\mathrm{a})}(𝐫)𝑑𝐫}\right],$

where

$V_{\mathrm{na},I}(𝐫-{\tau }_I)$

$=$

$V_{\mathrm{core},I}(𝐫-{\tau }_I)+V_{\mathrm{H},I}^{(\mathrm{a})}(𝐫-{\tau }_I).$

(18)

Therefore, we can reorganize these three terms as follows:

$E_{\mathrm{ec}}^{(L)}+E_{\mathrm{ee}}+E_{\mathrm{cc}}=E_{\mathrm{na}}+E_{\delta \mathrm{ee}}+E_{\mathrm{scc}},$

(19)

	$E_{\mathrm{na}}$	$=$	${\displaystyle \int 𝑑r^{3}n(𝐫)\sum _I{V}_{\mathrm{na},I}(𝐫-{\tau }_I)},$		(20)
		$=$	${\displaystyle \sum _{\sigma }}{\displaystyle \sum _{\mathrm{n}}^N}{\displaystyle \sum _{i\alpha ,j\beta }}{\rho }_{\sigma ,i\alpha j\beta }^{({𝐑}_{\mathrm{n}})}{\displaystyle \sum _I}⟨{\varphi }_{i\alpha }(𝐫-{\tau }_i)|V_{\mathrm{na},I}(𝐫-{\tau }_I)|{\varphi }_{j\beta }(𝐫-{\tau }_j-{𝐑}_{\mathrm{n}})⟩,$
	$E_{\delta \mathrm{ee}}$	$=$	${\displaystyle \frac{1}{2}}{\displaystyle \int 𝑑r^3\delta n(𝐫)\delta V_{\mathrm{H}}(𝐫)},$		(21)
	$E_{\mathrm{scc}}$	$=$	${\displaystyle \frac{1}{2}}{\displaystyle \sum _{I,J}}\left[{\displaystyle \frac{Z_I{Z}_J}{|{\tau }_I-{\tau }_J|}}-{\displaystyle \int 𝑑r^3{n}_I^{(\mathrm{a})}(𝐫)V_{\mathrm{H},J}^{(\mathrm{a})}(𝐫)}\right].$		(22)

Following the reorganization of energy terms, the total energy can be given by

$E_{\mathrm{tot}}=E_{\mathrm{kin}}+E_{\mathrm{na}}+E_{\mathrm{ec}}^{(\mathrm{NL})}+E_{\delta \mathrm{ee}}+E_{\mathrm{xc}}+E_{\mathrm{scc}}.$

(23)

Considering the orthogonality relation among one-particle wave functions, let us introduce a functional $F$ with Lagrange’s multipliers ${\epsilon }_{\sigma \nu {\sigma }^{\prime }{\nu }^{\prime }}$:

$F=E_{\mathrm{tot}}+{\displaystyle \sum _{𝐤}}{\displaystyle \sum _{\sigma }}{\displaystyle \sum _{\nu {\nu }^{\prime }}}{\epsilon }_{\sigma \nu \sigma {\nu }^{\prime }}^{(𝐤)}\left({\delta }_{\sigma \nu \sigma {\nu }^{\prime }}^{(𝐤)}-⟨{\psi }_{\sigma \nu }^{(𝐤)}|{\psi }_{\sigma {\nu }^{\prime }}^{(𝐤)}⟩\right).$

(24)

The variation of the functional $F$ with respect to the LCPAO coefficients $c_{\sigma \mu ,i\alpha }^{(𝐤)*}$ yields the following matrix equation:

$H_{\sigma }^{(𝐤)}{c}_{\sigma }^{(𝐤)}=S^{(𝐤)}{c}_{\sigma }^{(𝐤)}{\epsilon }_{\sigma \sigma }^{(𝐤)}.$

(25)

Moreover, noting that the matrix ${\epsilon }_{\sigma \sigma }^{(𝐤)}$ for Lagrange’s multipliers is Hermitian, and introducing $V$ diagonalizing the matrix, we can transform above equation as:

$H_{\sigma }^{(𝐤)}{c}_{\sigma }^{(𝐤)}V=S^{(𝐤)}{c}_{\sigma }^{(𝐤)}V{V}^{†}{\epsilon }_{\sigma \sigma }^{(𝐤)}V.$

(26)

By renaming $c_{\sigma }^{(𝐤)}V$ by $c_{\sigma }^{(𝐤)}$, and defining the diagonal element of $V^{†}{\epsilon }_{\sigma \sigma }^{(𝐤)}V$ to be ${\epsilon }_{\sigma \mu }^{(𝐤)}$, we have a well known Kohn-Sham equation in a matrix form as a generalized eigenvalue problem:

$H_{\sigma }^{(𝐤)}{c}_{\sigma \mu }^{(𝐤)}={\epsilon }_{\sigma \mu }^{(𝐤)}{S}^{(𝐤)}{c}_{\sigma \mu }^{(𝐤)},$

(27)

where the Hamiltonian and overlap matrices are given by

	$H_{\sigma ,i\alpha j\beta }^{(𝐤)}$	$=$	${\displaystyle \sum _{\mathrm{n}}}{\mathrm{e}}^{\mathrm{i}{𝐑}_{\mathrm{n}}\cdot 𝐤}⟨{\varphi }_{i\alpha }(𝐫-{\tau }_i)|{\widehat{H}}_{\sigma }|{\varphi }_{j\beta }(𝐫-{\tau }_j-{𝐑}_{\mathrm{n}})⟩,$		(28)
		$=$	${\displaystyle \sum _{\mathrm{n}}}{\mathrm{e}}^{\mathrm{i}{𝐑}_{\mathrm{n}}\cdot 𝐤}{h}_{\sigma ,i\alpha j\beta }^{({𝐑}_{\mathrm{n}})}.$

	$S_{i\alpha j\beta }^{(𝐤)}$	$=$	${\displaystyle \sum _{\mathrm{n}}}{\mathrm{e}}^{\mathrm{i}{𝐑}_{\mathrm{n}}\cdot 𝐤}⟨{\varphi }_{i\alpha }(𝐫-{\tau }_i)|{\varphi }_{j\beta }(𝐫-{\tau }_j-{𝐑}_{\mathrm{n}})⟩,$		(29)
		$=$	${\displaystyle \sum _{\mathrm{n}}}{\mathrm{e}}^{\mathrm{i}{𝐑}_{\mathrm{n}}\cdot 𝐤}{s}_{\sigma ,i\alpha j\beta }^{({𝐑}_{\mathrm{n}})}.$

with a Kohn-Sham Hamiltonian operator

${\widehat{H}}_{\sigma }=\widehat{T}+V_{\mathrm{eff},\sigma },$

(30)

and the effective potential

$V_{\mathrm{eff},\sigma }={\displaystyle \sum _k}{V}_{\mathrm{NL},k}+{\displaystyle \sum _k}{V}_{\mathrm{na},k}+\delta V_{\mathrm{H}}+V_{\mathrm{xc},\sigma }.$

(31)

The neutral atom potential $V_{\mathrm{na},I}$ is spherical and defined within the finite range determined by the cutoff radius $r_{c,I}$ of the confinement potential. Therefore, the potential $V_{\mathrm{na},I}$ can be expressed by a projector expansion as follows:

${\widehat{V}}_{\mathrm{na},I}={\displaystyle \sum _{lm}^{L_{\max }}}{\displaystyle \sum _{\zeta }^{N_{\mathrm{rad}}}}|V_{\mathrm{na},I}{\overline{R}}_{l\zeta }{Y}_{lm}⟩{\displaystyle \frac{1}{c_{l\zeta }}}⟨Y_{lm}{\overline{R}}_{l\zeta }{V}_{\mathrm{na},I}|,$

(32)

where a set of radial functions $\{{\overline{R}}_{l\zeta }\}$ is an orthonormal set defined by a norm $\int r^2𝑑rR{V}_{\mathrm{na},k}{R}^{\prime }$ for radial functions $R$ and $R^{\prime }$, and is calculated by the following Gram-Schmidt orthogonalization [4]:

	${\overline{R}}_{l\zeta }$	$=$	$R_{l\zeta }-{\displaystyle \sum _{\eta }^{\zeta -1}}{\overline{R}}_{l\eta }{\displaystyle \frac{1}{c_{l\eta }}}{\displaystyle \int r^2𝑑r{\overline{R}}_{l\eta }{V}_{\mathrm{na},k}{R}_{l\zeta }},$		(33)
	$c_{l\zeta }$	$=$	${\displaystyle \int r^2𝑑r{\overline{R}}_{l\zeta }{V}_{\mathrm{na},k}{\overline{R}}_{l\zeta }}.$		(34)

The radial function $R_{l\zeta }$ used is pseudo wave functions for both the ground and excited states under the same confinement potential as used in the calculation of the atomic electron density $n_i^{(a)}$ [2, 3]. The most important feature in the projector expansion is that the deep neutral atom potential is expressed by a separable form, and thereby we only have to evaluate the two-center integrals to construct the matrix elements for the neutral atom potential. As discussed later, the two-center integrals can be accurately evaluated in momentum space. For details of the projector expansion method, see also the reference [1].

The overlap integrals, matrix elements for the non-local potentials, for the neutral atom potentials in a separable form discussed in the Sec. 3, and for the kinetic operator consist of two-center integrals. In this section, the evaluation of the two-center integrals is discussed. The pseudo-atomic function ${\varphi }_{i\alpha }(𝐫)$ in Eq. (1) is given by a product of a real spherical harmonic function ${\overline{Y}}_{lm}$ and a radial wave function $R_{pl}$:

${\varphi }_{i\alpha }(𝐫)={\overline{Y}}_{lm}(\widehat{𝐫})R_{pl}(r),$

(35)

where $\widehat{𝐫}$ means Euler angles, $\theta$ and $\varphi$, for $𝐫$, and $r$ radial coordinate. Although the real function is used for the spherical harmonic function in OpenMX instead of the complex function $Y_{lm}(\widehat{𝐫})$, firstly we consider the case with the complex function $Y_{lm}(\widehat{𝐫})$ as

${\varphi }_{i\alpha }(𝐫)=Y_{lm}(\widehat{𝐫})R_{pl}(r).$

(36)

After the evaluation of two-center integrals related to the complex function, they are transformed into two-center integrals for the real function ${\overline{Y}}_{lm}(\widehat{𝐫})$ by matrix operations. Then, the pseudo-atomic function ${\varphi }_{i\alpha }(𝐫)$ given by Eq. (36) can be Fourier-transformed as follows:

${\tilde{\varphi }}_{i\alpha }(𝐤)={\left({\displaystyle \frac{1}{\sqrt{2\pi }}}\right)}^3{\displaystyle \int 𝑑r^3{\varphi }_{i\alpha }(𝐫){\mathrm{e}}^{-\mathrm{i}𝐤\cdot 𝐫}}.$

(37)

The back transformation is defined by

${\varphi }_{i\alpha }(𝐫)={\left({\displaystyle \frac{1}{\sqrt{2\pi }}}\right)}^3{\displaystyle \int 𝑑k^3{\tilde{\varphi }}_{i\alpha }(𝐤){\mathrm{e}}^{\mathrm{i}𝐤\cdot 𝐫}}.$

(38)

Noting the Rayleigh expansion

	${\mathrm{e}}^{\mathrm{i}𝐤\cdot 𝐫}$	$=$	$4\pi {\displaystyle \sum _{L=0}^{\mathrm{\infty }}}{\displaystyle \sum _{M=-L}^L}{\mathrm{i}}^L{j}_L(kr)Y_{LM}^{*}(\widehat{𝐤})Y_{LM}(\widehat{𝐫}),$		(39)
	${\mathrm{e}}^{-\mathrm{i}𝐤\cdot 𝐫}$	$=$	$4\pi {\displaystyle \sum _{L=0}^{\mathrm{\infty }}}{\displaystyle \sum _{M=-L}^L}{(-\mathrm{i})}^L{j}_L(kr)Y_{LM}(\widehat{𝐤})Y_{LM}^{*}(\widehat{𝐫}),$		(40)

and putting Eqs. (36) and (40) into Eq. (37), we have

	${\tilde{\varphi }}_{i\alpha }(𝐤)$	$=$	${\left({\displaystyle \frac{1}{\sqrt{2\pi }}}\right)}^3{\displaystyle \int 𝑑r^3{Y}_{lm}(\widehat{𝐫})R_{pl}(r)\left\{4\pi \sum _{L=0}^{\mathrm{\infty }}\sum _{M=-L}^L{(-\mathrm{i})}^L{j}_L(kr)Y_{LM}(\widehat{𝐤})Y_{LM}^{*}(\widehat{𝐫})\right\}},$		(41)
		$=$	${\left({\displaystyle \frac{1}{\sqrt{2\pi }}}\right)}^{3}4\pi {\displaystyle \sum _{L=0}^{\mathrm{\infty }}}{\displaystyle \sum _{M=-L}^L}{(-\mathrm{i})}^L{Y}_{LM}(\widehat{𝐤}){\displaystyle \int 𝑑r{r}^2{R}_{pl}(r)j_L(kr)\int 𝑑\theta 𝑑\varphi \sin (\theta )Y_{lm}(\widehat{𝐫})Y_{LM}^{*}(\widehat{𝐫})},$
		$=$	$\left[{\left({\displaystyle \frac{1}{\sqrt{2\pi }}}\right)}^{3}4\pi {(-\mathrm{i})}^l{\displaystyle \int 𝑑r{r}^2{R}_{pl}(r)j_l(kr)}\right]Y_{lm}(\widehat{𝐤}),$
		$=$	${\tilde{R}}_{pl}(k)Y_{lm}(\widehat{𝐤}),$

where we defined

${\tilde{R}}_{pl}(k)=\left[{\left({\displaystyle \frac{1}{\sqrt{2\pi }}}\right)}^{3}4\pi {(-\mathrm{i})}^l{\displaystyle \int 𝑑r{r}^2{R}_{pl}(r)j_L(kr)}\right].$

(42)

Using Eqs. (38), (40), and (41), the overlap integral is evaluated as follows:

	$⟨{\varphi }_{i\alpha }(𝐫)|{\varphi }_{j\beta }(𝐫-\tau )⟩$	$=$	${\displaystyle \int 𝑑r^3{\varphi }_{i\alpha }^{*}(𝐫){\varphi }_{j\beta }(𝐫-\tau )},$		(43)
		$=$	${\displaystyle \int 𝑑r^3{\left(\frac{1}{\sqrt{2\pi }}\right)}^3\int 𝑑k^3{\tilde{R}}_{pl}^{*}(k)Y_{lm}^{*}(\widehat{𝐤}){\mathrm{e}}^{-\mathrm{i}𝐤\cdot 𝐫}{\left(\frac{1}{\sqrt{2\pi }}\right)}^3\int 𝑑k^{\prime 3}{\tilde{R}}_{p^{\prime }{l}^{\prime }}(k^{\prime })Y_{l^{\prime }{m}^{\prime }}({\widehat{𝐤}}^{\prime }){\mathrm{e}}^{\mathrm{i}{𝐤}^{\prime }\cdot (𝐫-\tau )}},$
		$=$	${\left({\displaystyle \frac{1}{2\pi }}\right)}^3{\displaystyle \int 𝑑k^3\int 𝑑k^{\prime 3}{\mathrm{e}}^{-\mathrm{i}{𝐤}^{\prime }\cdot \tau }{\tilde{R}}_{pl}^{*}(k)Y_{lm}^{*}(\widehat{𝐤}){\tilde{R}}_{p^{\prime }{l}^{\prime }}(k^{\prime })Y_{l^{\prime }{m}^{\prime }}({\widehat{𝐤}}^{\prime })\int 𝑑r^3{\mathrm{e}}^{\mathrm{i}({𝐤}^{\prime }-𝐤)\cdot 𝐫}},$
		$=$	${\displaystyle \int 𝑑k^3{\mathrm{e}}^{-\mathrm{i}𝐤\cdot \tau }{\tilde{R}}_{pl}^{*}(k)Y_{lm}^{*}(\widehat{𝐤}){\tilde{R}}_{p^{\prime }{l}^{\prime }}(k)Y_{l^{\prime }{m}^{\prime }}(\widehat{𝐤})},$
		$=$	${\displaystyle \int 𝑑k^3\left[4\pi \sum _{L=0}^{\mathrm{\infty }}\sum _{M=-L}^L{(-\mathrm{i})}^L{j}_L(k\tau )Y_{LM}(\widehat{𝐤})Y_{LM}^{*}(\widehat{\tau })\right]{\tilde{R}}_{pl}^{*}(k)Y_{lm}^{*}(\widehat{𝐤}){\tilde{R}}_{p^{\prime }{l}^{\prime }}(k)Y_{l^{\prime }{m}^{\prime }}(\widehat{𝐤})},$
		$=$	$4\pi {\displaystyle \sum _{L=0}^{\mathrm{\infty }}}{\displaystyle \sum _{M=-L}^L}{(-\mathrm{i})}^L{Y}_{LM}^{*}(\widehat{\tau })C_{l(-m),l^{\prime }{m}^{\prime },LM}{\displaystyle \int 𝑑k{k}^2{j}_L(k|\tau |){\tilde{R}}_{pl}^{*}(k){\tilde{R}}_{p^{\prime }{l}^{\prime }}(k)},$

where an integral in the third line was evaluated as

${\displaystyle \int 𝑑r^3{\mathrm{e}}^{\mathrm{i}({𝐤}^{\prime }-𝐤)\cdot 𝐫}}$

$=$

${(2\pi )}^3\delta ({𝐤}^{\prime }-𝐤),$

(44)

and one may notice Gaunt coefficients defined by

$C_{l(-m),l^{\prime }{m}^{\prime },LM}={\displaystyle \int 𝑑\theta 𝑑\varphi \sin (\theta )Y_{lm}^{*}(\widehat{𝐤})Y_{l^{\prime }{m}^{\prime }}(\widehat{𝐤})Y_{LM}(\widehat{𝐤})}.$

(45)

The matrix element for the kinetic operator can be easily found in the same way as for the overlap integral as follows:

	$⟨{\varphi }_{i\alpha }(𝐫)|\widehat{T}|{\varphi }_{j\beta }(𝐫-\tau )⟩$	$=$	${\displaystyle \int 𝑑r^3{\varphi }_{i\alpha }^{*}(𝐫)\left\{-\frac{1}{2}(\frac{d^2}{d{x}^2}+\frac{d^2}{d{y}^2}+\frac{d^2}{d{z}^2})\right\}{\varphi }_{j\beta }(𝐫-\tau )},$		(46)
		$=$	$2\pi {\displaystyle \sum _{L=0}^{\mathrm{\infty }}}{\displaystyle \sum _{M=-L}^L}{(-\mathrm{i})}^L{C}_{l(-m),l^{\prime }{m}^{\prime },LM}{\displaystyle \int 𝑑k{k}^4{j}_L(kr){\tilde{R}}_{pl}^{*}(k){\tilde{R}}_{p^{\prime }{l}^{\prime }}(k)}.$

The two energy terms $E_{\delta \mathrm{ee}}$ and $E_{\mathrm{xc}}$ are discretized by a regular mesh $\{{𝐫}_{𝐩}\}$ in real space [5], while the integrations in $E_{\mathrm{kin}}$, $E_{\mathrm{na}}$, $E_{\mathrm{scc}}$, and $E_{\mathrm{ec}}^{(\mathrm{NL})}$ can be reduced to two center integrals which can be evaluated in momentum space. The regular mesh $\{{𝐫}_{𝐩}\}$ in real space is generated by dividing the unit cell with a same interval which is characterized by the cutoff energies $E_{\mathrm{cut}}^{(1)}$, $E_{\mathrm{cut}}^{(2)}$, and $E_{\mathrm{cut}}^{(3)}$:

$E_{\mathrm{cut}}^{(1)}$

$=$

${\displaystyle \frac{1}{2}}{\mathrm{𝐠𝐛}}_1\cdot {\mathrm{𝐠𝐛}}_1,E_{\mathrm{cut}}^{(2)}={\displaystyle \frac{1}{2}}{\mathrm{𝐠𝐛}}_2\cdot {\mathrm{𝐠𝐛}}_2,E_{\mathrm{cut}}^{(3)}={\displaystyle \frac{1}{2}}{\mathrm{𝐠𝐛}}_3\cdot {\mathrm{𝐠𝐛}}_3,$

(47)

${\mathrm{𝐠𝐚}}_1$

$=$

${\displaystyle \frac{{𝐚}_1}{N_1}},{\mathrm{𝐠𝐚}}_2={\displaystyle \frac{{𝐚}_2}{N_2}},{\mathrm{𝐠𝐚}}_3={\displaystyle \frac{{𝐚}_3}{N_3}},$

(48)

${\mathrm{𝐠𝐛}}_1$

$=$

$2\pi {\displaystyle \frac{{\mathrm{𝐠𝐚}}_2\times {\mathrm{𝐠𝐚}}_3}{\mathrm{\Delta }V}},{\mathrm{𝐠𝐛}}_2=2\pi {\displaystyle \frac{{\mathrm{𝐠𝐚}}_3\times {\mathrm{𝐠𝐚}}_1}{\mathrm{\Delta }V}},{\mathrm{𝐠𝐛}}_3=2\pi {\displaystyle \frac{{\mathrm{𝐠𝐚}}_1\times {\mathrm{𝐠𝐚}}_2}{\mathrm{\Delta }V}},$

(49)

$\mathrm{\Delta }V$

$=$

${\mathrm{𝐠𝐚}}_1\cdot \left({\mathrm{𝐠𝐚}}_2\times {\mathrm{𝐠𝐚}}_3\right),$

(50)

where ${𝐚}_1$, ${𝐚}_2$, and ${𝐚}_3$ are unit cell vectors of the whole system, and $N_1$, $N_2$, and $N_3$ are the number of division for ${𝐚}_1$, ${𝐚}_2$, and ${𝐚}_3$-axes, respectively. $N_1$, $N_2$, and $N_3$ are determined so that the differences among $E_{\mathrm{cut}}^{(1)}$, $E_{\mathrm{cut}}^{(2)}$, and $E_{\mathrm{cut}}^{(3)}$ can be minimized starting from the given cutoff energy. Using the regular mesh $\{{𝐫}_{𝐩}\}$, the Hartree energy $E_{\delta \mathrm{ee}}$ associated with the difference charge density $\delta n(𝐫)$ is discretized as

$E_{\delta \mathrm{ee}}={\displaystyle \frac{1}{2}}\mathrm{\Delta }V{\displaystyle \sum _{𝐩}}\delta n({𝐫}_{𝐩})\delta V_{\mathrm{H}}({𝐫}_{𝐩}).$

(51)

The same regular mesh $\{{𝐫}_{𝐩}\}$ is also applied to the solution of Poisson’s equation to find $\delta V_{\mathrm{H}}$. Then, the charge density is Fourier transformed by

	$\delta \tilde{n}(𝐪)$	$=$	${\displaystyle \frac{1}{N_1{N}_2{N}_3}}{\displaystyle \sum _{n_1}^{N_1-1}}{\displaystyle \sum _{n_2}^{N_2-1}}{\displaystyle \sum _{n_3}^{N_3-1}}\delta n({𝐫}_{n_1{n}_2{n}_3}){\mathrm{e}}^{-i𝐪\cdot {𝐫}_{n_1{n}_2{n}_3}},$		(52)
		$=$	${\displaystyle \frac{1}{N_1{N}_2{N}_3}}{\displaystyle \sum _{𝐩}}\delta n({𝐫}_{𝐩}){\mathrm{e}}^{-i𝐪\cdot {𝐫}_{𝐩}}.$

From $\{\delta \tilde{n}(𝐪)\}$, we can evaluate $\delta {\tilde{V}}_{\mathrm{H}}(𝐪)$ by

$\delta {\tilde{V}}_{\mathrm{H}}(𝐪)={\displaystyle \frac{4\pi }{{|𝐪|}^2}}\delta \tilde{n}(𝐪).$

(53)

Thus, we see that $\delta V_{\mathrm{H}}(𝐫)$ is also written in a discretized form with the regular mesh as follows:

	$\delta V_{\mathrm{H}}(𝐫)$	$=$	${\displaystyle \sum _{𝐪}}\delta {\tilde{V}}_{\mathrm{H}}(𝐪){\mathrm{e}}^{i𝐪\cdot 𝐫},$		(54)
		$=$	${\displaystyle \frac{4\pi }{N_1{N}_2{N}_3}}{\displaystyle \sum _{𝐪}}{\displaystyle \frac{1}{{|𝐪|}^2}}{\displaystyle \sum _{𝐩}}\delta n({𝐫}_{𝐩}){\mathrm{e}}^{i𝐪\cdot (𝐫-{𝐫}_{𝐩})}.$

Within the LDA, $E_{\mathrm{xc}}$ can be easily discretized as well as $E_{\delta \mathrm{ee}}$ by

$E_{\mathrm{xc}}$

$=$

$\mathrm{\Delta }V{\displaystyle \sum _{𝐩}}\{n_{\uparrow }({𝐫}_{𝐩})+n_{\downarrow }({𝐫}_{𝐩})+n_{\mathrm{pcc}}({𝐫}_{𝐩})\}{ϵ}_{\mathrm{xc}}(n_{\uparrow }({𝐫}_{𝐩})+{\displaystyle \frac{1}{2}}{n}_{\mathrm{pcc}}({𝐫}_{𝐩}),n_{\downarrow }({𝐫}_{𝐩})+{\displaystyle \frac{1}{2}}{n}_{\mathrm{pcc}}({𝐫}_{𝐩})).$

(55)

For the GGA, $E_{\mathrm{xc}}$ is discretized with the gradient of charge density evaluated with a finite difference scheme in the same way in the LDA.