Energy-weighted density matrix embedding of open correlated chemical fragments

Edoardo Fertitta; George H. Booth

Energy-weighted density matrix embedding of open correlated chemical fragments

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Abstract

We present a multi-scale approach to efficiently embed an ab initio correlated chemical fragment described by its energy-weighted density matrices, and entangled with a wider mean-field many-electron system. This approach, first presented in Phys. Rev. B, 98, 235132 (2018), is here extended to account for realistic long-range interactions and broken symmetry states. The scheme allows for a systematically improvable description in the range of correlated fluctuations out of the fragment into the system, via a self-consistent optimization of a coupled auxiliary mean-field system. It is discussed that the method has rigorous limits equivalent to existing quantum embedding approaches of both dynamical mean-field theory, as well as density matrix embedding theory, to which this method is compared, and the importance of these correlated fluctuations is demonstrated. We derive a self-consistent local energy functional within the scheme, and demonstrate the approach for Hydrogen rings, where quantitative accuracy is achieved despite only a single atom being explicitly treated.

Original language	English
Journal	The Journal of chemical physics
Publication status	Accepted/In press - 6 Jul 2019

Keywords

Electronic Structure
Quantum Chemistry
Electron Correlation
Quantum Many-Body Physics
Computational Chemistry
Condensed Matter Physics

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Energy-weighted density matrix_FERTITTA_Accepted2019_GREEN AAMAccepted author manuscript, 458 KB

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title = "Energy-weighted density matrix embedding of open correlated chemical fragments",

abstract = "We present a multi-scale approach to efficiently embed an ab initio correlated chemical fragment described by its energy-weighted density matrices, and entangled with a wider mean-field many-electron system. This approach, first presented in Phys. Rev. B, 98, 235132 (2018), is here extended to account for realistic long-range interactions and broken symmetry states. The scheme allows for a systematically improvable description in the range of correlated fluctuations out of the fragment into the system, via a self-consistent optimization of a coupled auxiliary mean-field system. It is discussed that the method has rigorous limits equivalent to existing quantum embedding approaches of both dynamical mean-field theory, as well as density matrix embedding theory, to which this method is compared, and the importance of these correlated fluctuations is demonstrated. We derive a self-consistent local energy functional within the scheme, and demonstrate the approach for Hydrogen rings, where quantitative accuracy is achieved despite only a single atom being explicitly treated.",

keywords = "Electronic Structure, Quantum Chemistry, Electron Correlation, Quantum Many-Body Physics, Computational Chemistry, Condensed Matter Physics",

author = "Edoardo Fertitta and Booth, {George H.}",

year = "2019",

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language = "English",

journal = "The Journal of chemical physics",

issn = "0021-9606",

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TY - JOUR

T1 - Energy-weighted density matrix embedding of open correlated chemical fragments

AU - Fertitta, Edoardo

AU - Booth, George H.

PY - 2019/7/6

Y1 - 2019/7/6

N2 - We present a multi-scale approach to efficiently embed an ab initio correlated chemical fragment described by its energy-weighted density matrices, and entangled with a wider mean-field many-electron system. This approach, first presented in Phys. Rev. B, 98, 235132 (2018), is here extended to account for realistic long-range interactions and broken symmetry states. The scheme allows for a systematically improvable description in the range of correlated fluctuations out of the fragment into the system, via a self-consistent optimization of a coupled auxiliary mean-field system. It is discussed that the method has rigorous limits equivalent to existing quantum embedding approaches of both dynamical mean-field theory, as well as density matrix embedding theory, to which this method is compared, and the importance of these correlated fluctuations is demonstrated. We derive a self-consistent local energy functional within the scheme, and demonstrate the approach for Hydrogen rings, where quantitative accuracy is achieved despite only a single atom being explicitly treated.

AB - We present a multi-scale approach to efficiently embed an ab initio correlated chemical fragment described by its energy-weighted density matrices, and entangled with a wider mean-field many-electron system. This approach, first presented in Phys. Rev. B, 98, 235132 (2018), is here extended to account for realistic long-range interactions and broken symmetry states. The scheme allows for a systematically improvable description in the range of correlated fluctuations out of the fragment into the system, via a self-consistent optimization of a coupled auxiliary mean-field system. It is discussed that the method has rigorous limits equivalent to existing quantum embedding approaches of both dynamical mean-field theory, as well as density matrix embedding theory, to which this method is compared, and the importance of these correlated fluctuations is demonstrated. We derive a self-consistent local energy functional within the scheme, and demonstrate the approach for Hydrogen rings, where quantitative accuracy is achieved despite only a single atom being explicitly treated.

KW - Electronic Structure

KW - Quantum Chemistry

KW - Electron Correlation

KW - Quantum Many-Body Physics

KW - Computational Chemistry

KW - Condensed Matter Physics

M3 - Article

SN - 0021-9606

JO - The Journal of chemical physics

JF - The Journal of chemical physics

ER -

Energy-weighted density matrix embedding of open correlated chemical fragments

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Keywords

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