Compressed sodalite-like MgH<sub>6</sub> as a potential high-temperature superconductor

Feng, Xiaolei; Zhang, Jurong; Gao, Guoying; Liu, Hanyu; Wang, Hui

doi:10.1039/c5ra11459d

Cited by 171 publications

(164 citation statements)

References 36 publications

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“…Calculations have predicted that hydrogenic sodalite-like lattices will also be found in MgH 6 around 260 GPa [34] and YH 6 at 120 GPa [61].…”

Section: How To Metallize With An Electropositive Elementmentioning

confidence: 99%

“…Therefore, building on Ashcroft's proposals, density functional theory (DFT) calculations were carried out to predict the structures of hydrides with stoichiometries that are not stable at atmospheric conditions, in the hopes of uncovering hitherto unknown superconductors [19]. Since then, numerous theoretical studies have been performed that investigate the phase diagrams of hydrogen doped with the electropositive alkali metals or alkaline earth metals [20][21][22][23][24][25][26][27][28][29][30][31][32][33][34], as well as the electronegative element iodine [35,36] under pressure. Experimental work on the hydrides of lithium and sodium confirmed that species with unique stoichiometries such as NaH 3 and NaH 7 can be synthesized in diamond anvil cells, but the phases that have been reported to date do not exhibit superconductivity [21,37].…”

Section: Introductionmentioning

confidence: 99%

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Superconductivity in Hydrides Doped with Main Group Elements Under Pressure

Shamp¹,

Zurek²

2017

Novel Superconducting Materials

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A priori crystal structure prediction techniques have been used to explore the phase diagrams of hydrides of main group elements under pressure. A number of novel phases with the chemical formulas MHn, n > 1 and M = Li, Na, K, Rb, Cs; MHn, n > 2 and M= Mg, Ca, Sr, Ba; HnI with n > 1 and PH, PH 2 , PH 3 have been predicted to be stable at pressures achievable in diamond anvil cells. The hydrogenic lattices within these phases display a number of structural motifs including H δ− 2 , H − , H − 3 , as well as one-dimensional and three-dimensional extended structures. A wide range of superconducting critical temperatures, Tcs, are predicted for these hydrides. The mechanism of metallization and the propensity for superconductivity are dependent upon the structural motifs present in these phases, and in particular on their hydrogenic sublattices. Phases that are thermodynamically unstable, but dynamically stable, are accessible experimentally. The observed trends provide insight on how to design hydrides that are superconducting at high temperatures.

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“…Calculations have predicted that hydrogenic sodalite-like lattices will also be found in MgH 6 around 260 GPa [34] and YH 6 at 120 GPa [61].…”

Section: How To Metallize With An Electropositive Elementmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Superconductivity in Hydrides Doped with Main Group Elements Under Pressure

Shamp¹,

Zurek²

2017

Novel Superconducting Materials

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“…This group made several other interesting predictions, which are waiting their future confirmations (Peng et al,2017;see the review by Zhang et al,2017). They predicted the high T c superconducting state for calcium hydride (T c ≈240K; Wang et al,2014) and for YH 6 (T c ≈264K; Li et al,2015).Note that the compound MgH 6 ,similar to CaH 6 was also studied (Feng et al,2015) and the values of Tc ≈ 260K at P ! > 300GPa were predicted.…”

Section: Other Hydridesmentioning

confidence: 99%

Colloquium : High pressure and road to room temperature superconductivity

Gor’kov¹,

Kresin²

2018

Rev. Mod. Phys.

133

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High pressure serves as a path finding tool towards novel structures, including those with very high Tc. The superconductivity in sulfur hydrides with record value of Tc =203 K (!) is caused by the phonon mechanism. However, the picture differs from the conventional one in important ways. The phonon spectrum in sulfur hydride is both broad and has a complex structure. High value of T c is mainly due to strong coupling to the high-frequency optical modes, although the acoustic phonons also make a noticeable contribution. New approach is described; it generalizes the standard treatment of the phonon mechanism and makes it possible to obtain an analytical expression for Tc . It turns out that, unlike in the conventional case, the value of the isotope coefficient varies with the pressure and reflects the impact of the optical modes. The phase diagram, that is the pressure dependence of Tc, is rather peculiar. A crucial feature is that increasing pressure results in a series of structural transitions, including the one, which yields the superconducting phase with the record Tc . In a narrow region near P≈150 GPa the critical temperature rises sharply from Tc ≈120K to Tc ≈200K. The sharp structural transition, which produces the high Tc phase, is a first-order phase transition caused by interaction between the order parameter and lattice deformations. A remarkable feature of the electronic spectrum in the high Tc phase is the appearance of small pockets at the Fermi level. Their presence leads to a two-gap spectrum, which 2 can, in principle, be observed, with the future use of tunneling spectroscopy. This feature leads to non-monotonic and strongly asymmetric pressure dependence of Tc. Other hydrides can be expected to display even higher values of Tc, up to room temperature. The fundamental challenge lays in creation a structure capable of displaying high Tc at ambient pressure.

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“…Wherein the measured critical temperature (T C ) of 203 K in hydrogen sulfide is among the highest over allknown superconductors [5]. The theoretical studies have revealed a significantly more superconducting hydrogenrich materials such as PtH [7,8], H 2 S [9], GaH 3 [10,11], ScH 3 [12,13], SnH 4 [14], GeH 4 [15,16], NbH 4 [17,18], CaH 6 [19], MgH 6 [20] of which the highest critical temperature equal to 263−271 K was estimated for MgH 6 compound at a pressure range from 300 to 400 GPa [20]. As it turns out pressure (p) can have a very large impact on the critical temperature and thermodynamics of superconducting state.…”

Section: Introductionmentioning

confidence: 99%

Detailed study of the superconducting properties in compressed germane

Szczȩśniak

Durajski

2015

Eur. Phys. J. B

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Abstract. Hydrogen-rich compounds under extreme pressure are the most promising systems for searching a high-temperature superconductivity. In presented paper, we report analysis of the thermodynamic properties of hydrogenated germanium (germane, GeH4) at 220 GPa obtained within the framework of the Migdal-Eliashberg theory. We observe that together with the increase of Coulomb pseudopotential from 0.1 to 0.3 the critical temperature decreases from 92.36 K to 52.80 K. A similar trend is also well-visible in the case of other thermodynamic properties. Moreover, we study the influence of external pressure on the superconducting state of GeH4. On this basis we conclude that increase of pressure from 20 to 220 GPa has a pronounced effect on the thermodynamic stability of germane. Finally, it is proved that the properties of the superconducting state of GeH4 differ markedly from predictions of the Bardeen-Cooper-Schrieffer (BCS) theory.

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Compressed sodalite-like MgH₆ as a potential high-temperature superconductor

Cited by 171 publications

References 36 publications

Superconductivity in Hydrides Doped with Main Group Elements Under Pressure

Superconductivity in Hydrides Doped with Main Group Elements Under Pressure

Colloquium : High pressure and road to room temperature superconductivity

Detailed study of the superconducting properties in compressed germane

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Compressed sodalite-like MgH6 as a potential high-temperature superconductor

Cited by 171 publications

References 36 publications

Superconductivity in Hydrides Doped with Main Group Elements Under Pressure

Superconductivity in Hydrides Doped with Main Group Elements Under Pressure

Colloquium : High pressure and road to room temperature superconductivity

Detailed study of the superconducting properties in compressed germane

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Product

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About

Compressed sodalite-like MgH₆ as a potential high-temperature superconductor