Dense Low-Coordination Phases of Lithium

Pickard, Chris J.; Needs, R. J.

doi:10.1103/physrevlett.102.146401

Cited by 109 publications

(82 citation statements)

References 25 publications

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“…4 Crystal structure of this semiconducting phase has attracted numerous attentions. 4,25,28,[127][128][129][130][131] The observed insulation seems in accordance with earlier prediction of pairing mechanism, 128 which however is unlikely in view of the proposed energetically much preferred metallic Cmca-24 (24 atoms/cell) structure. 127 Using CALYPSO method on structure prediction, a complex orthorhombic Aba2-40 structure (Fig.…”

Section: Methods Based On Particle Swarm Optimization Algorithmsupporting

confidence: 89%

“…127 Using CALYPSO method on structure prediction, a complex orthorhombic Aba2-40 structure (Fig. 3(b), 40 atom/cell, Pearson symbol, oC40) was predicted to be energetically more stable than all earlier proposed structures [127][128][129][130] in the pressure range 60-80 GPa. 25 Band structure calculation of Aba2-40 structure reveals indeed a semiconducting behavior with a band gap >0.8 eV at 70 GPa.…”

Section: Methods Based On Particle Swarm Optimization Algorithmmentioning

confidence: 96%

See 1 more Smart Citation

Perspective: Crystal structure prediction at high pressures

Wang

2014

The Journal of Chemical Physics

161

125

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Crystal structure prediction at high pressures unbiased by any prior known structure information has recently become a topic of considerable interest. We here present a short overview of recently developed structure prediction methods and propose current challenges for crystal structure prediction. We focus on first-principles crystal structure prediction at high pressures, paying particular attention to novel high pressure structures uncovered by efficient structure prediction methods. Finally, a brief perspective on the outstanding issues that remain to be solved and some directions for future structure prediction researches at high pressure are presented and discussed. © 2014 AIP Publishing LLC.

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Section: Methods Based On Particle Swarm Optimization Algorithmsupporting

confidence: 89%

Section: Methods Based On Particle Swarm Optimization Algorithmmentioning

confidence: 96%

Perspective: Crystal structure prediction at high pressures

Wang

2014

The Journal of Chemical Physics

161

125

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“…3B reveals that at 100 GPa LiH 2 is just metallic, and the small density of states at the Fermi energy (g(E F )/valence electron ϭ 0.001 eV Ϫ1 ) is reminiscent of the DOS calculated for compressed Li (19)(20)(21), rising only a little to 0.007 eV Ϫ1 at 300 GPa. For elemental Li, the 1s cores start to overlap with increasing pressure, and the valence electrons are pushed into the interstitial regions (19).…”

Section: Lih 2 Hydrides and Hydrogen Moleculesmentioning

confidence: 99%

A little bit of lithium does a lot for hydrogen

Zurek

Hoffmann²,

Ashcroft³

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

265

247

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From detailed assessments of electronic structure, we find that a combination of significantly quantal elements, six of seven atoms being hydrogen, becomes a stable metal at a pressure approximately 1/4 of that required to metalize pure hydrogen itself. The system, LiH6 (and other LiHn), may well have extensions beyond the constituent lithium. These hypothetical materials demonstrate that nontraditional stoichiometries can considerably expand the view of chemical combination under moderate pressure.high pressure ͉ hydrogen metallization ͉ lithium chemistry T hree lines of thought-call them obsessions-impelled this investigation: (i) thinking of new pathways to promote and enhance the metallization of hydrogen, (ii) more generally the potential stability of new compounds with unusual stoichiometries under high pressures, and (iii) proposals for the design of new superconductors. As will be seen, we find two surprising ways (making good chemical sense) for the first, as well as sound theoretical evidence for the second. Based upon what is already known about possible superconductivity in metallic hydrogen, we find indications for the third.LiH, crystallizing in the NaCl structure with a band gap of 4.99 eV (1), is one stable point in the Li/H phase diagram, the only one other than the elements at ambient conditions. It remains stable at higher pressures; the reaction Li ϩ 1 2 H 2 3 LiH is computed to be exothermic at all of the pressures we have considered. Calculations predict that pressure-induced metallization and transformation to the CsCl structure occur simultaneously at approximately 329 GPa (2). The results of our density functional theory (DFT) calculations on LiH are given in the supporting information (SI).Hydrogen also vehemently resists metallization.

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“…Conceptually, we describe these materials as electrides. 1,[7][8][9][10][11][12] A canonical example is the completely reduced mayenite, [Ca 12 Al 14 O 32 ] 2+ :2e -which exhibits remarkably rich chemistries. [13][14][15][16] Of particular note is the observation of a superconducting transition (T c~0 .4 K) intimately related to the anionic electrons in this electride, thereby opening a new frontier in the field of superconductors.…”

Section: Introductionmentioning

confidence: 99%

Electride and superconductivity behaviors in Mn5Si3-type intermetallics

et al. 2017

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Electrides are unique in the sense that they contain localized anionic electrons in the interstitial regions. Yet they exist with a diversity of chemical compositions, especially under extreme conditions, implying generalized underlying principles for their existence. What is rarely observed is the combination of electride state and superconductivity within the same material, but such behavior would open up a new category of superconductors. Here, we report a hexagonal Nb 5 Ir 3 phase of Mn 5 Si 3 -type structure that falls into this category and extends the electride concept into intermetallics. The confined electrons in the one-dimensional cavities are reflected by the characteristic channel bands in the electronic structure. Filling these free spaces with foreign oxygen atoms serves to engineer the band topology and increase the superconducting transition temperature to 10.5 K in Nb 5 Ir 3 O. Specific heat analysis indicates the appearance of low-lying phonons and two-gap s-wave superconductivity. Strong electron-phonon coupling is revealed to be the pairing glue with an anomalously large ratio between the superconducting gap Δ 0 and T c , 2Δ 0 /k B T c = 6.12. The general rule governing the formation of electrides concerns the structural stability against the cation filling/extraction in the channel site.

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Dense Low-Coordination Phases of Lithium

Cited by 109 publications

References 25 publications

Perspective: Crystal structure prediction at high pressures

Perspective: Crystal structure prediction at high pressures

A little bit of lithium does a lot for hydrogen

Electride and superconductivity behaviors in Mn5Si3-type intermetallics

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