Toward a predictive theory of correlated materials

Kent, Paul; Kotliar, Gabriel

doi:10.1126/science.aat5975

Cited by 62 publications

(59 citation statements)

References 97 publications

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“…Rather than continuing to speculate on the origins of the unusual colors exhibited in these systems—and their possible connection with 5f-electron covalency,—here we calculate the electronic structure of PuW 2 O 7 and AmWO 4 employing the local density approximation (LDA)57 to density functional theory (DFT)58,59 in combination with dynamical mean field theory (LDA + DMFT)60–62 and in combination with the Gutzwiller approximation (LDA + GA),63–67 which are techniques specifically designed to capture the electron correlations beyond the single-particle picture underlining classic approximations to DFT 68–70…”

Section: Resultsmentioning

confidence: 99%

Origins of the odd optical observables in plutonium and americium tungstates

et al. 2019

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Section: Resultsmentioning

confidence: 99%

Origins of the odd optical observables in plutonium and americium tungstates

et al. 2019

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“…The third is the (so-far increasing) power of massively parallel supercomputers, which made actual calculations possible in practice. All this gave birth to the DFT+DMFT approach [41,75,101,107,[109][110][111][112][113], described in a schematic way in Fig. 8.…”

Section: Dmft and Dft+dmftmentioning

confidence: 99%

“…A representative, although not exhaustive, list of success stories can be found, e.g., in Refs. [41,101,107,[110][111][112][113]. As an example we show in Fig.…”

Section: Dmft and Dft+dmftmentioning

confidence: 99%

Solving the strong-correlation problem in materials

Pavarini

2021

Riv. Nuovo Cim.

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This article is a short introduction to the modern computational techniques used to tackle the many-body problem in materials. The aim is to present the basic ideas, using simple examples to illustrate strengths and weaknesses of each method. We will start from density-functional theory (DFT) and the Kohn–Sham construction—the standard computational tools for performing electronic structure calculations. Leaving the realm of rigorous density-functional theory, we will discuss the established practice of adopting the Kohn–Sham Hamiltonian as approximate model. After recalling the triumphs of the Kohn–Sham description, we will stress the fundamental reasons of its failure for strongly-correlated compounds, and discuss the strategies adopted to overcome the problem. The article will then focus on the most effective method so far, the DFT+DMFT technique and its extensions. Achievements, open issues and possible future developments will be reviewed. The key differences between dynamical (DFT+DMFT) and static (DFT+U) mean-field methods will be elucidated. In the conclusion, we will assess the apparent dichotomy between first-principles and model-based techniques, emphasizing the common ground that in fact they share.

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“…This approach takes into account the nonsphericity of the impurity, and has so far produced good agreement with the experiment (36,47), possibly concluding the discussion over the different DC approaches. Another area where there is need for new developments is the numerical impurity solvers, which solve the AIM to calculate the self energy Σ(ω) from the hybridization ∆(ω) (8). The state of the art is the continuous time quantum Monte Carlo methods introduced for this purpose (48,49,50) which are in principle exact, and efficiently parallelizable over a large number of processors.…”

Section: First Principles Dft+dmftmentioning

confidence: 99%

Applications of DFT + DMFT in Materials Science

Paul

Birol

2019

Annu. Rev. Mater. Res.

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First principles methods can provide insight into materials that otherwise is impossible to acquire. Density Functional Theory (DFT) has been the first principles method of choice for numerous applications, but it falls short of predicting the properties of correlated materials. First principles Density Functional Theory + Dynamical Mean Field Theory (DFT+DMFT) is a powerful tool that can address these shortcomings of DFT when applied to correlated metals. In this brief review, which is aimed at non-experts, we review the basics and some applications of DFT+DMFT.

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Toward a predictive theory of correlated materials

Cited by 62 publications

References 97 publications

Origins of the odd optical observables in plutonium and americium tungstates

Origins of the odd optical observables in plutonium and americium tungstates

Solving the strong-correlation problem in materials

Applications of DFT + DMFT in Materials Science

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