Superconductivity at 161 K in thorium hydride ThH10: Synthesis and properties

Semenok, Dmitrii V.; Kvashnin, Alexander G.; Иванова, А. Г.; Svitlyk, Volodymyr; Fominski, V. Yu.; Sadakov, A. V.; Sobolevskiy, O. A.; Pudalov, V. M.; Troyan, I. A.; Oganov, Artem R.

doi:10.1016/j.mattod.2019.10.005

Cited by 228 publications

(227 citation statements)

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“…Semenok et al [44] also reported on the discovery of another high-temperature superconducting phase of ThH 10 at P=174 GPa, which exhibitsFm m 3 crystallographic symmetry and superconducting transition temperature of T c =159 K. In figure 3 we show raw upper critical field, B c2 (T), data for this phase [44] and data fit to equations (3)- (6).…”

Section: Thh 10 (P=174 Gpa) In Uemura Plotmentioning

confidence: 87%

“…Semenok et al [44] reported the discovery of a high-temperature superconducting phase of ThH 9 at P=170 GPa which exhibits P6 3 /mmc crystallographic symmetry and superconducting transition temperature of T c =146 K. They also performed first principles calculations and deduced the effective mass in this superconductor: As we mentioned in our previous papers [12,13,46,47], first principles calculations [39,48,49] always provide α-values near 5, which is the very strong-coupling limit for s-wave symmetry (also note that other superconducting gap symmetries have weak-coupling limits of α∼5 [50][51][52]). Despite the orthodox view, several new, alternative, approaches were developed to explain NRT superconductivity in compressed hydrides: Hirsch and Marsiglio [53], Souza and Marsiglio [54], Harshman and Fiory [55], as well as Kaplan and Imry [56].…”

Section: Thh 9 (P=170 Gpa) In Uemura Plotmentioning

confidence: 99%

“…Assuming all hydrogen-rich superconductors have the same primary mechanism for the superconductivity, the value of α=3.53 was taken as the lower bound for our calculations. 6)) for ThH 10 superhydride compressed at pressure P=174 GPa (raw data is from [44] Semenok et al [44] measured B c2 (T) for ThH 9 at P=170 GPa, which we fit to equations (3)-(6) in figure 2. This give T c /T F ratios that are within usual range of unconventional superconductors band, see figure 1.…”

Section: Thh 9 (P=170 Gpa) In Uemura Plotmentioning

confidence: 99%

“…Superconducting upper critical field, B c2 (T), data and fits to three different models (equations (3)-(6)) for ThH 9 superhydride compressed at pressure P=170 GPa (raw data is from[44]). (a) Fit to WHH and B-WHH models, for latter the fit quality is R=0.998.…”

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Classifying superconductivity in ThH-ThD superhydrides/superdeuterides

Talantsev

Mataira

2020

Mater. Res. Express

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Satterthwaite and Toepke (1970 Phys. Rev. Lett. 25 741) discovered that Th 4 H 15 -Th 4 D 15 superhydrides are superconducting but exhibit no isotope effect. As the isotope effect is a fundamental prediction of electron-phonon mediated superconductivity described by Bardeen, Cooper, and Schrieffer (BCS) its absence alludes to some other mechanism. Soon after this work, Stritzker and Buckel (1972 Zeitschrift für Physik A Hadrons and nuclei 257 1-8) reported that superconductors in the PdH x -PdD x system exhibit the reverse isotope effect. Yussouff et al (1995 Solid State Communications 94 549) extended this finding in PdH x -PdD x -PdT x systems. Renewed interest in hydrogen-and deuterium-rich superconductors is driven by the discovery of near-room-temperature superconductivity in highlycompressed H 3 S (Drozdov et al 2015 Nature 525 73) and LaH 10 (Somayazulu et al 2019 Phys. Rev. Lett. 122 027001).Here we attempt to reaffirm or disprove our primary idea that the mechanism for nearroom-temperature superconductivity in hydrogen-rich superconductors is not BCS electron-phonon mediated. To that end, we analyse the upper critical field data, B c2 (T), in Th 4 H 15 -Th 4 D 15 (Satterthwaite and Toepke 1970 Phys. Rev. Lett. 25 741) as well as two recently discovered highpressure hydrogen-rich phases of ThH 9 and ThH 10 (Semenok et al 2019 Materials Today,

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Section: Thh 10 (P=174 Gpa) In Uemura Plotmentioning

confidence: 87%

Section: Thh 9 (P=170 Gpa) In Uemura Plotmentioning

confidence: 99%

Section: Thh 9 (P=170 Gpa) In Uemura Plotmentioning

confidence: 99%

mentioning

confidence: 99%

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Classifying superconductivity in ThH-ThD superhydrides/superdeuterides

Talantsev

Mataira

2020

Mater. Res. Express

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Characterization of Near-Room-Temperature Superconductivity in Yttrium Superhydrides

Talantsev¹

2019

Preprint

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Recently, Troyan et al (2019 arXiv:1908 and Kong et al (2019 arXiv:1909 extended near-room-temperature superconductors family by new yttrium superhydride polymorphs, YHn (n = 4,6,7,9), which exhibit superconducting transition temperatures in the range of Tc = 210-243 K at pressure of P = 160-255 GPa. In this paper, temperature dependent upper critical field data, Bc2(T), for highly-compressed mixture of YH4+YH6 phases (reported by Kong et al 2019 arXiv:1909) is analysed to deduce the ratio of Tc to the Fermi temperature, TF. Our analysis shows that in all considered scenarios the YH4+YH6 mixture has the ratio 0.01 ≤ Tc/TF ≤ 0.04. As the result, YH4+YH6 falls in the unconventional superconductors band in the Uemura plot. It is also found that the characteristic temperature of the order parameter amplitude fluctuations, Tfluc, in the YH4+YH6 mixture is only several percent above observed Tc, and thus the superconducting transition in yttrium superhydride polymorphs is fundamentally limited by thermodynamics fluctuations.

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Few‐Hydrogen Metal‐Bonded Perovskite Superconductor MgHCu₃ with a Critical Temperature of 42 K under Atmospheric Pressure

Tian,

He,

Zhu

et al. 2023

Adv Funct Materials

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Since the prediction of multi‐hydrogen high‐temperature superconductor by Ashcroft in 2004, many possible candidates have been proposed, e.g., LaH10 showing the highest superconducting transition temperature (Tc) around 250–260 K at 170‐200 GPa hitherto. However, this pressure is too large to be taken into practical use. To address this challenge, it proposes a few‐hydrogen metal‐bonded perovskite superconductor, MgHCu3, by combining a novel design idea with first‐principles calculations. Different from multi‐hydrogen hydrides, whose high Tc relies on extreme pressure, the metallic bond in few‐hydrogen superconductor MgHCu3 improves the structural stability and ductility at atmospheric pressure. Here, the small amount of hydrogen is found to be vital for Tc. After the incorporation of hydrogen, the electron–phonon coupling constant of MgHCu3 is increased to 0.83, which is larger than that of the well‐known MgB2. Moreover, the anisotropy of MgHCu3 also plays an important role in enhancing Tc. Based on the Migdal‐Eliashberg theory, it predicts that the phonon‐mediated metal‐bonded perovskite MgHCu3 is a superconductor with Tc of 42 K. The first predicted ternary metal‐bonded perovskite, MgHCu3, enriches the family of perovskite and will promote further investigation on few‐hydrogen superconductors under atmospheric pressure.

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Superconductivity at 161 K in thorium hydride ThH10: Synthesis and properties

Cited by 228 publications

References 54 publications

Classifying superconductivity in ThH-ThD superhydrides/superdeuterides

Classifying superconductivity in ThH-ThD superhydrides/superdeuterides

Characterization of Near-Room-Temperature Superconductivity in Yttrium Superhydrides

Few‐Hydrogen Metal‐Bonded Perovskite Superconductor MgHCu₃ with a Critical Temperature of 42 K under Atmospheric Pressure

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Superconductivity at 161 K in thorium hydride ThH10: Synthesis and properties

Cited by 228 publications

References 54 publications

Classifying superconductivity in ThH-ThD superhydrides/superdeuterides

Classifying superconductivity in ThH-ThD superhydrides/superdeuterides

Characterization of Near-Room-Temperature Superconductivity in Yttrium Superhydrides

Few‐Hydrogen Metal‐Bonded Perovskite Superconductor MgHCu3 with a Critical Temperature of 42 K under Atmospheric Pressure

Contact Info

Product

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Superconductivity at 161 K in thorium hydride ThH10: Synthesis and properties

Few‐Hydrogen Metal‐Bonded Perovskite Superconductor MgHCu₃ with a Critical Temperature of 42 K under Atmospheric Pressure