Orbital-free density functional theory

Electronic structure methods
Valence bond theory
Coulson–Fischer theory Generalized valence bond Modern valence bond theory
Molecular orbital theory
Hartree–Fock method Semi-empirical quantum chemistry methods Møller–Plesset perturbation theory Configuration interaction Coupled cluster Multi-configurational self-consistent field Quantum chemistry composite methods Quantum Monte Carlo
Density functional theory
Time-dependent density functional theory Thomas–Fermi model Orbital-free density functional theory Adiabatic connection fluctuation dissipation theorem Görling-Levy pertubation theory Optimized effective potential method Linearized augmented-plane-wave method Projector augmented wave method
Electronic band structure
Nearly free electron model Tight binding Muffin-tin approximation k·p perturbation theory Empty lattice approximation GW approximation Korringa–Kohn–Rostoker method
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In computational chemistry, orbital-free density functional theory (OFDFT) is a quantum mechanical approach to electronic structure determination which is based on functionals of the electronic density. It is most closely related to the Thomas–Fermi model. Orbital-free density functional theory is, at present, less accurate than Kohn–Sham density functional theory models, but has the advantage of being fast, so that it can be applied to large systems.

The Hohenberg–Kohn theorems^[1] guarantee that, for a system of atoms, there exists a functional of the electron density that yields the total energy. Minimization of this functional with respect to the density gives the ground-state density from which all of the system's properties can be obtained. Although the Hohenberg–Kohn theorems tell us that such a functional exists, they do not give us guidance on how to find it. In practice, the density functional is known exactly except for two terms. These are the electronic kinetic energy and the exchange–correlation energy. The lack of the true exchange–correlation functional is a well known problem in DFT, and there exists a huge variety of approaches to approximate this crucial component.

In general, there is no known form for the interacting kinetic energy in terms of electron density. In practice, instead of deriving approximations for interacting kinetic energy, much effort was devoted to deriving approximations for non-interacting (Kohn–Sham) kinetic energy, which is defined as (in atomic units)

${\displaystyle T_{S}[\{\phi _{i}\}]=\sum _{i=1}^{N}\langle \phi _{i}|-{\frac {1}{2}}\nabla ^{2}|\phi _{i}\rangle ,}$

where ${\displaystyle |\phi _{i}\rangle }$ is the i-th Kohn–Sham orbital. The summation is performed over all the occupied Kohn–Sham orbitals.

One of the first attempts to do this (even before the formulation of the Hohenberg–Kohn theorem) was the Thomas–Fermi model (1927), which wrote the kinetic energy as^[2][3][4]

${\displaystyle T_{\text{TF}}[n]=\underbrace {{\frac {3}{10}}(3\pi ^{2})^{\frac {2}{3}}} _{C_{TF}}\int [n(\mathbf {r} )]^{\frac {5}{3}}\,d^{3}r.}$

This expression is based on the homogeneous electron gas (HEG) and a Local Density Approximation (LDA), thus, is not very accurate for most physical systems. By formulating Kohn–Sham kinetic energy in terms of electron density, one avoids diagonalizing the Kohn–Sham Hamiltonian for solving for the Kohn–Sham orbitals, therefore saving the computational cost. Since no Kohn–Sham orbital is involved in orbital-free density functional theory, one only needs to minimize the system's energy with respect to the electron density. An important bound for the TF kinetic energy is the Lieb-Thirring inequality.

A notable historical improvement of the Thomas-Fermi model is the von Weizsäcker (vW) kinetic energy (1935),^[5] which is exactly the kinetic energy for noninteracting bosons and can be regarded as a Generalized Gradient approximation (GGA).

${\displaystyle T_{\text{vW}}[n]={\frac {1}{8}}\int {\frac {\nabla n(\mathbf {r} )\cdot \nabla n(\mathbf {r} )}{n(\mathbf {r} )}}d^{3}r=\int {\sqrt {n(\mathbf {r} )}}(-{\frac {1}{2}}\Delta ){\sqrt {n(\mathbf {r} )}}d^{3}r}$

A conceptually really important quantity in OFDFT is the Pauli kinetic energy.^[6][7][8][9] As the Kohn-Sham correlation energy links the real system of interacting electrons to the artificial Kohn-Sham (KS) system of noninteracting electrons, the Pauli kinetic energy links the KS system to the fictitious system noninteracting model bosons. In the same way as the KS interacting energy it is highy KS-orbital dependent and must be in practice approximated.

${\displaystyle T_{\text{P}}[n]\equiv T_{\text{S}}[n]-T_{\text{vW}}[n]}$

The term Pauli comes from the fact, that the functional is related to the Pauli exclusion principle. ${\displaystyle T_{\text{P}}[n]=0}$ for an electron number of ${\displaystyle N\leq 2}$.

The exchange energy in orbital-free density functional theory (OFDFT) is the Dirac exchange^[10] as a Local Density Approximation (LDA) (1930) It is related to the homogeneous electron gas (HEG).

${\displaystyle E_{x}^{\text{LDA}}[n]=-\underbrace {{\frac {3}{4}}{\bigg (}{\frac {3}{\pi }}{\bigg )}^{1/3}} _{C_{x}}\int [n(\mathbf {r} )]^{\frac {4}{3}}d^{3}r}$

An important bound for the LDA exchange energy is the Lieb-Oxford inequality.

State of the art kinetic energy density functionals for orbital-free density functional theory and still subject to ongoing research are the so called nonlocal (NL) kinetic energy density functionals such as e.g. the Huang-Carter (HC) functional ^[11][12] (2010), the Mi-Genova-Pavenello (MGP) functional ^[13] (2018) or the Wang-Teter (WT) functional ^[14] (1992). They admit the general form

${\displaystyle T_{\text{NL}}[n]=C_{\text{NL}}\iint d^{3}rd^{3}r'n(\mathbf {r} )^{\alpha }K[n](r,r')n(\mathbf {r} ')^{\beta }}$

where ${\displaystyle \alpha }$ and ${\displaystyle \beta }$ are arbitrary fractional exponents, ${\displaystyle K[n](r,r')}$ is a nonlocal KEDF kernel and ${\displaystyle C_{\text{NL}}}$ some constant.

The analogue to the Kohn-Sham (KS) equations (1965) in Orbital-free density functional theory (OFDFT) is the Levy-Perdew-Sahni (LPS) equation ^[15][16] (1984), an effectively bosonic Schrödinger equation

${\displaystyle {\bigg (}-{\frac {1}{2}}\Delta +v_{S}(\mathbf {r} )+v_{P}(\mathbf {r} ){\bigg )}{\sqrt {n(\mathbf {r} )}}=\mu {\sqrt {n(\mathbf {r} )}}}$

where ${\displaystyle v_{S}(\mathbf {r} )}$ is the Kohn-Sham (KS) potential, ${\displaystyle v_{P}(\mathbf {r} )}$ the Pauli potential, ${\displaystyle \mu }$ the highest occupied KS orbital and ${\displaystyle {\sqrt {n(\mathbf {r} )}}}$ the square root of the density. One big benefit of the LPS equation being so intimately related to the KS equations is, that an existing KS code can be easily modified in an OF code with ejecting all orbitals except for one in the Self-Consitent-Field (SCF) cycle.

Starting from Euler-Lagrange equation of density functional theory ${\displaystyle {\frac {\delta T_{S}[n]}{\delta n(\mathbf {r} )}}+v_{S}(\mathbf {r} )=\mu }$, simultaneously adding and subtracting the von Weizsäcker potential, i.e. the functional derivative of the vW functional and acknowleding the definition of the Pauli kinetic energy, while the functional derivative of the Pauli kinetic energy with respect to the density is the Pauli potential ${\displaystyle \underbrace {\frac {\delta T_{vW}[n]}{\delta n(\mathbf {r} )}} _{v_{vW}(\mathbf {r} )}+v_{S}(\mathbf {r} )+\underbrace {\frac {\delta T_{P}[n]}{\delta n(\mathbf {r} )}} _{v_{P}(\mathbf {r} )}=\mu }$. Expanding the functional derivative via chain rule ${\displaystyle \underbrace {\frac {\delta {\sqrt {n(\mathbf {r} )}}}{\delta n(\mathbf {r} )}} _{1/{\sqrt {n(\mathbf {r} )}}}\underbrace {{\frac {\delta }{\delta {\sqrt {n(\mathbf {r} )}}}}\int {\sqrt {n(\mathbf {r} )}}(-{\frac {1}{2}}\Delta ){\sqrt {n(\mathbf {r} )}}d^{3}r} _{-{\frac {1}{2}}\Delta {\sqrt {n(\mathbf {r} )}}}+v_{S}(\mathbf {r} )+v_{P}(\mathbf {r} )=\mu }$ and as a last step multiplying both sides by the square root of the density ${\displaystyle {\sqrt {n(\mathbf {r} )}}}$ yields the LPS equation.

With the linear transformation ${\displaystyle {\sqrt {n(\mathbf {r} )}}\mapsto {\frac {1}{\sqrt {N}}}\phi _{B}(\mathbf {r} )}$ and by defining the bosonic potential as ${\displaystyle v_{B}(\mathbf {r} )\equiv v_{S}(\mathbf {r} )+v_{P}(\mathbf {r} )}$ the LPS equation evolves to the bosonic Schrödinger equation

${\displaystyle {\bigg (}-{\frac {1}{2}}\Delta +v_{B}(\mathbf {r} ){\bigg )}\phi _{B}(\mathbf {r} )=\mu \phi _{B}(\mathbf {r} )}$.

Note that the normalization constraint in Bra–ket notation ${\displaystyle \langle \phi _{B}|\phi _{B}\rangle =1}$ holds, since ${\displaystyle N[n]=\int n(\mathbf {r} )d^{3}r}$.

Quite recently also a time-dependent version of OFDFT has been developed.^[17] It is also implemented in DFTpy.

As a free open-source software package for OFDFT DFTpy has been developed by the Pavanello Group. [1] [2]. It has been launched in 2020.^[18] The most recent version is 2.1.1.