Superconductivity of hydrogen superoxide under high pressure

Ishikawa, Takahiro

doi:10.1088/1361-6668/abb207

Cited by 2 publications

(3 citation statements)

References 58 publications

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“…Recently, Snider et al [11] reported on the observation that ternary compound Hx(S,C)y exhibits the transition temperature within a range of Tc = 275-287 K (at P = 258-270 GPa), which is by about 5 K higher than previous record of Tc = 280 K, reported by Somayazulu et al [8] in highly-compressed LaH10. While detailed phase/structural and phonon spectrum and other physical properties measurements [1][2][3][4][5][6][7]9,[12][13][14], as well as the first-principle calculation studies [2,6,[15][16][17][18][19][20][21][22][23][24][25][26][27] are on-going tasks for Hx(S,C)y compound [28], in this paper we report results of the analysis of temperature dependent magnetoresistance, R(T,B), from which we deduced:…”

Section: Introductionmentioning

confidence: 99%

The electron-phonon coupling constant, Fermi temperature and unconventional superconductivity in the carbonaceous sulfur hydride 190 K superconductor

Talantsev

2021

Supercond. Sci. Technol.

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Recently, Snider et al (2020 Nature 586 373) reported on the observation of superconductivity in highly compressed carbonaceous sulfur hydride, H x (S,C) y . The highest critical temperature in H x (S,C) y exceeds the previous record of T c = 280 K by 5 K, as reported by Somayazulu et al (2019 Phys. Rev. Lett. 122 027001) for highly compressed LaH10. In this paper, we analyze experimental temperature-dependent magnetoresistance data, R(T,B), reported by Snider et al. The analysis shows that H x (S,C) y compound exhibited T c = 190 K (P = 210 GPa), has the electron–phonon coupling constant λ e−ph = 2.0 and the ratio of critical temperature, T c, to the Fermi temperature, T F, in the range of 0.011 ⩽ T c/T F ⩽ 0.018. These deduced values are very close to the ones reported for H3S at P = 155–165 GPa (Drozdov et al 2015 Nature 525 73). This means that in all considered scenarios the carbonaceous sulfur hydride 190 K superconductor falls into the unconventional superconductor band in the Uemura plot, where all other highly compressed super-hydride/deuterides are located. It should be noted that our analysis shows that all raw R(T,B) data sets for H x (S,C) y samples, for which Snider et al (2020 Nature 586 373) reported T c > 200 K, cannot be characterized as reliable data sources. Thus, independent experimental confirmation/disproof for high-T c values in the carbonaceous sulfur hydride are required.

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Section: Introductionmentioning

confidence: 99%

The electron-phonon coupling constant, Fermi temperature and unconventional superconductivity in the carbonaceous sulfur hydride 190 K superconductor

Talantsev

2021

Supercond. Sci. Technol.

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“…where * is the Coulomb pseudopotential parameter (ranging from * = 0.10-0.16 [43][44][45][46][47][48][49][50][51][52][53][54]).…”

Section: Utilized Modelmentioning

confidence: 99%

“…4-6 have a single solution in respect of 𝜆 𝑒−𝑝ℎ , for given T, Tc and *. Due to * is varying within a range of 0.10-0.16 [43][44][45][46][47][48][49][50][51][52][53][54], in this work we used the mean value of * = 0.13 in all calculations. There is a need to clarify, that we define Tc in Eqs.…”

Section: Utilized Modelmentioning

confidence: 99%

The electron–phonon coupling constant and the Debye temperature in polyhydrides of thorium, hexadeuteride of yttrium, and metallic hydrogen phase III

Talantsev

2021

Journal of Applied Physics

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Milestone experimental discovery of superconductivity above 200 K in highly-compressed sulphur hydride by Drozdov et al (Nature 525, 73 (2015)) sparked experimental and theoretical investigations of metallic hydrides. Since then, a dozen of superconducting binary and ternary polyhydrides have been discovered. For instance, there are three superconducting polyhydrides of thorium: Th4H15, ThH9, and ThH10 and four polyhydrides of yttrium: YH4, YH6, YH7, YH9. In addition to binary and ternary hydrogen-based metallic compounds, recently Eremets et al (arXiv:2109.11104) reported on the metallization of hydrogen, which is in remarkable agreement with first-principles calculated e-ph(174 GPa) = 1.75 (Semenok et al, Materials Today 33, 36 (2020)). Deduced e-ph(172 GPa) = 1.90 ± 0.02 for Im-3m-YD6 is also in excellent agreement with first-principles calculated e-ph(165 GPa) = 1.80 (Troyan et al, Advanced Materials 33, 2006832 (2021)). And finally, we deduced T(402 GPa) = 727 ± 6 K for hydrogen phase III which implies that e-ph(402 GPa) ≤ 1.7 in this metal.The electron-phonon coupling constant and the Debye temperature in polyhydrides of thorium, hexadeuteride of yttrium, and metallic hydrogen phase III

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Superconductivity of hydrogen superoxide under high pressure

Cited by 2 publications

References 58 publications

The electron-phonon coupling constant, Fermi temperature and unconventional superconductivity in the carbonaceous sulfur hydride 190 K superconductor

The electron-phonon coupling constant, Fermi temperature and unconventional superconductivity in the carbonaceous sulfur hydride 190 K superconductor

The electron–phonon coupling constant and the Debye temperature in polyhydrides of thorium, hexadeuteride of yttrium, and metallic hydrogen phase III

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