Evidence for Superconductivity above 260 K in Lanthanum Superhydride at Megabar Pressures

Somayazulu, Maddury; Ahart, Muhtar; Mishra, Ajay K.; Geballe, Zachary M.; Baldini, Maria; Meng, Yue; Struzhkin, Viktor V.; Hemley, Russell J.

doi:10.1103/physrevlett.122.027001

Cited by 1,057 publications

(893 citation statements)

References 43 publications

(48 reference statements)

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“…The present findings have several implications for various types of solids. For example, in semi-crystalline amorphous superconductors, it is known that the excess of vibrational modes (above the Debye level) gives a large contribution to the Eliashberg function and hence to the electron-phonon coupling, thus enhancing the critical temperature T c [44][45][46]. This effect is proportional to the amount of disorder but vanishes as the material becomes completely amorphous.…”

Section: Discussionmentioning

confidence: 99%

Low-energy optical phonons induce glassy-like vibrational and thermal anomalies in ordered crystals

Baggioli

Zaccone

2019

J. Phys. Mater.

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It is widely accepted that structural glasses and disordered crystals exhibit anomalies in their thermal, mechanical and acoustic properties as manifestations of the breakdown of the long-wavelength approximation in a disordered dissipative environment. However, the same type of glassy-like anomalies (i.e. boson peak in the vibrational density of states (VDOS) above the Debye level, peak in the normalized specific heat at T;10 K etc) have been recently observed also in perfectly ordered crystals, including thermoelectric compounds. Here we present a theory that predicts these surprising effects in perfectly ordered crystals as a result of low-lying (soft) optical phonons. In particular, it is seen that a strong boson peak anomaly (low-energy excess of modes) in the VDOS can be due almost entirely to the presence of low-energy optical phonons, provided that their energy is comparable to that of the acoustic modes at the Brillouin zone boundary. The boson peak is predicted also to occur in the heat capacity at low T. In presence of strong damping (which might be due to anharmonicities in the ordered crystals), these optical phonons contribute to the low-T deviation from Debye's T 3 law, producing a linear-in-T behavior which is typical of glasses, even though no assumptions of disorder whatsoever are made in the model. These findings are relevant for understanding and tuning thermal transport properties of thermoelectric compounds, and possibly for the enhancement of electron-phonon superconductivity.

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Section: Discussionmentioning

confidence: 99%

Low-energy optical phonons induce glassy-like vibrational and thermal anomalies in ordered crystals

Baggioli

Zaccone

2019

J. Phys. Mater.

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“…The error for predicting T cr has been shown to be within 1 K in some elemental systems, ranging from weak‐coupling (Mo,Al,Ta) to strong‐coupling (Nb,Pb) superconductors . This has led to the successful prediction and confirmation of new superconductors, including high pressure Si and Li, FeB 4 , H 2 S (or H 3 S), SnBi 2 Se 4 and PbBi 2 Te 4 , and recently NaH 10 . These successes, coupled with the development of databases of superconductors, have made ML an interesting new tool in the search of novel superconductors, particularly since the mechanisms for superconducting behavior differ from system to system .…”

Section: Applicationmentioning

confidence: 99%

A Critical Review of Machine Learning of Energy Materials

Chen

Zuo

et al. 2020

Advanced Energy Materials

373

281

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Machine learning (ML) is rapidly revolutionizing many fields and is starting to change landscapes for physics and chemistry. With its ability to solve complex tasks autonomously, ML is being exploited as a radically new way to help find material correlations, understand materials chemistry, and accelerate the discovery of materials. Here, an in‐depth review of the application of ML to energy materials, including rechargeable alkali‐ion batteries, photovoltaics, catalysts, thermoelectrics, piezoelectrics, and superconductors, is presented. A conceptual framework is first provided for ML in materials science, with a broad overview of different ML techniques as well as best practices. This is followed by a critical discussion of how ML is applied in energy materials. This review is concluded with the perspectives on major challenges and opportunities in this exciting field.

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“…A. Abrikosov proposed a new mechanism of producing the high-temperature superconductivity based on the formation of metallic excitonium, a so-called hypothetical electron-hole crystal, in semiconductors and semi-metals with m eff+ /m − > 50 , that had favourable to superconductivity properties, such as metallic hydrogen, which is realized in CuCl at high pressures and high T c = 100 K. [4] Later, such crystals were predicted by quantum calculations. Drosdov et al, reaching T c = 203 K in H 2 S [6] and later by M. Somayazulu et al -T c = 260 K in Lanthanum Superhydride in 2019 [7] at high pressures. Drosdov et al, reaching T c = 203 K in H 2 S [6] and later by M. Somayazulu et al -T c = 260 K in Lanthanum Superhydride in 2019 [7] at high pressures.…”

Section: Introductionmentioning

confidence: 89%

The electric field of an electron in an electron–hole plasma with degenerate electrons: Possibility of formation of a superconductivity state

Sadykova

Rukhadze

2019

Contributions to Plasma Physics

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We consider the possibility of the formation of a superconductivity state either in a semiconductor or in an electron-hole plasma with degenerate electrons due to the attractive forces between the electrons as a result of the exchange effects through the electron-hole sound wave by an analogy to the phonon waves in a solid state.We have determined an interaction potential between two electrons in a degenerate electron-hole plasma. The potential appears to be attractive at distances much larger than the Debye radius and decreases as 1/r 3 . We discuss the conditions in which the bound electron state, the so-called "Cooper Pair," in a such field can be formed. K E Y W O R D SCooper pair, degenerate plasma, electron, electron-hole plasma, field of the point charge 1 † To the Great memory of Prof. A.A. Rukhadze.

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Evidence for Superconductivity above 260 K in Lanthanum Superhydride at Megabar Pressures

Cited by 1,057 publications

References 43 publications

Low-energy optical phonons induce glassy-like vibrational and thermal anomalies in ordered crystals

Low-energy optical phonons induce glassy-like vibrational and thermal anomalies in ordered crystals

A Critical Review of Machine Learning of Energy Materials

The electric field of an electron in an electron–hole plasma with degenerate electrons: Possibility of formation of a superconductivity state

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