Metric-space approach to potentials and its relevance to density-functional theory

Metrics have been used to investigate the relationship between wavefunction distances and density distances for families of specific systems. We extend this research to look at random potentials for time-dependent single electron systems, and for ground-state two electron systems. We find that Fourier series are a good basis for generating random potentials. These random potentials also yield quasi-linear relationships between the distances of ground-state densities and wavefunctions, providing a framework in which Density Functional Theory can be explored.

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“…Some work in this direction has been done in Ref. [13] and using metrics for Kohn-Sham systems is currently being investigated.…”

Section: Non-interacting Systemsmentioning

confidence: 99%

Metrics for Two Electron Random Potential Systems

2018

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“…In metric space one can assign distances between wave functions, densities and external potentials of two systems, which quantify the closeness between the systems. Recently natural distances have been proposed for physical systems [8][9][10] and applied in several contexts [11][12][13][14][15][16][17][18].…”

Section: Introductionmentioning

confidence: 99%

Metric-Space Approach for Distinguishing Quantum Phase Transitions in Spin-Imbalanced Systems

2018

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Metric spaces are characterized by distances between pairs of elements. Systems that are physically similar are expected to present smaller distances (between their densities, wave functions and potentials) than systems that present different physical behaviors. For this reason metric spaces are good candidates for probing quantum phase transitions, since they could identify regimes of distinct phases. Here we apply metric space analysis to explore the transitions between the several phases in spin imbalanced systems. In particular we investigate the so-called FFLO (Fulde-Ferrel-Larkin-Ovchinnikov) phase, which is an intriguing phenomenon in which superconductivity and magnetism coexist in the same material. This is expected to appear for example in attractive fermionic systems with spin-imbalanced populations, due to the internal polarization produced by the imbalance. The transition between FFLO phase (superconducting phase) and the normal phase (non-superconducting) and their boundaries have been subject of discussion in recent years. We consider the Hubbard model in the attractive regime for which Density Matrix Renormalization Group calculations allow us to obtain the exact density function of the system. We then analyze the exact density distances as a function of the polarization. We find that our distances display signatures of the distinct quantum phases in spin-imbalanced fermionic systems: with respect to a central reference polarization, systems without FFLO present a very symmetric behavior, while systems with phase transitions are asymmetric.

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“…There is an increasing interest in the use of metrics to explore quantum mechanical systems [4][5][6][7][8][9][10], and appropriate ("natural") metrics for particle densities, wavefunctions, and external potentials [4,7] already shed light on (previously unknown) features of the mappings at the base of the Hohenberg-Kohn theorem, the cornerstone of DFT. Among the ultimate goals of DFT applications is the determination of properties such as total energies, ionization potentials, electron affinities, the fundamental gaps, and lattice distances of crystalline structures.…”

Section: Introductionmentioning

confidence: 99%

Fermionic correlations as metric distances: A useful tool for materials science

Marocchi

Pittalis

D’Amico

2017

Phys. Rev. Materials

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We introduce a rigorous, physically appealing, and practical way to measure distances between exchange-only correlations of interacting many-electron systems, which works regardless of their size and inhomogeneity. We show that this distance captures fundamental physical features such as the periodicity of atomic elements, and that it can be used to effectively and efficiently analyze the performance of density functional approximations. We suggest that this metric can find useful applications in high-throughput materials design.PACS numbers: 31.15. 71.15.Mb,

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Metric-space approach to potentials and its relevance to density-functional theory

Cited by 7 publications

References 22 publications

Metrics for Two Electron Random Potential Systems

Metrics for Two Electron Random Potential Systems

Metric-Space Approach for Distinguishing Quantum Phase Transitions in Spin-Imbalanced Systems

Fermionic correlations as metric distances: A useful tool for materials science

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