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Local Potential Functional Embedding Theory of Molecular Systems: Localized Orbital-Based Embedding from an Exact

Wafa Makhlouf1, Bruno Senjean2, Emmanuel Fromager1,3

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This study revisits localized orbital quantum embedding, developing a new theory that precisely relates embedding potentials to local density functional theory potentials. This approach enhances the description of density profiles in strongly correlated systems.

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Area of Science:

  • Quantum Chemistry
  • Condensed Matter Physics
  • Computational Materials Science

Background:

  • Density Matrix Embedding Theory (DMET) provides a framework for localized orbital-based quantum embedding.
  • Accurate description of strongly correlated systems remains a challenge in electronic structure theory.
  • Lattice Density Functional Theory (DFT) offers an alternative perspective for electronic structure calculations.

Purpose of the Study:

  • To reformulate localized orbital-based quantum embedding from a lattice DFT perspective.
  • To derive an in-principle exact formulation for any electronic Hamiltonian.
  • To develop a practical embedding theory for strongly correlated systems.

Main Methods:

  • Developed an exact formulation where localized orbital occupations act as the density.
  • Derived an exact relationship between the local Hartree-exchange-correlation (Hxc) potential and the embedding chemical potential.
  • Applied density-functional approximations to derive a self-consistent Local Potential Functional Embedding Theory (LPFET).

Main Results:

  • Established a novel connection between the Hxc potential and fragment-specific embedding chemical potentials.
  • Introduced LPFET, a practical embedding theory utilizing the local Hxc potential as the primary variable.
  • Demonstrated LPFET's ability to significantly improve density profile descriptions in strongly correlated systems.

Conclusions:

  • The developed LPFET offers a more accurate description of density profiles compared to previous embedding methods.
  • The fragment-dependent embedding chemical potential expression is a key innovation of LPFET.
  • This work provides a promising new avenue for studying strongly correlated electronic systems.