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Biswas, P. K.; Guguchia, Zurab; Khasanov, R.; Chinotti, M.; Li, L.; Wang, Kefeng; Petrović, C.; Morenzoni, E.

doi:10.1103/physrevb.92.195122

Cited by 35 publications

(47 citation statements)

References 54 publications

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“…In the vicinity of the putative structural quantum critical point where T * extrapolates to 0 K, μSR [22] and specific heat [5] detected a strongly enhanced electron-phonon coupling strength, indicated by the enhancement in 2 (0)/k B T c and C/γ T c beyond the BCS weak-coupling values [35][36][37], where (0) is the size of the gap, C is the specific heat jump at T c and γ is the Sommerfeld coefficient. [23,24].…”

Section: Introductionmentioning

confidence: 99%

Second-order structural transition in the superconductorLa3Co4Sn13

et al. 2016

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The quasiskutterudite superconductor La 3 Co 4 Sn 13 undergoes a phase transition at T * = 152 K. By measuring the temperature dependence of heat capacity, electrical resistivity, and the superlattice reflection intensity using x rays, we explore the character of the phase transition at T * . Our lattice dynamic calculations found imaginary phonon frequencies around the M point when the high-temperature structure is used in the calculations, indicating that the structure is unstable at the zero-temperature limit. The combined experimental and computational results establish that T * is associated with a second-order structural transition with q = (0.5,0.5,0) (or the M point). Further electronic band structure calculations reveal Fermi surface sheets with low-curvature segments, which allow us to draw qualitative comparison with both Sr 3 Ir 4 Sn 13 and Sr 3 Rh 4 Sn 13 in which similar physics has been discussed recently.

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Section: Introductionmentioning

confidence: 99%

Second-order structural transition in the superconductorLa3Co4Sn13

et al. 2016

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“…Yet, in this case, it can easily be explained within the standard BCS-based theories: the gap associated with the CDW closes at the critical point, resulting in an increase of N ( F ), which, in turn, leads to an increase of the SC transition temperature T c . As a consequence, the dependence of T c on the tuning parameter is usually rather weak in the non-CDW regime beyond the critical point 16,17,[20][21][22][23] . There is currently no clear evidence that quantum critical fluctuations associated with the CDW QCP have any effect on the SC 24 .…”

Section: Substituting Pd For Pt Suppressesmentioning

confidence: 99%

“…There, T c shows only a very weak and very smooth dependence on composition or pressure, without any anomaly at the QCP 18,19 . Most of the superconducting properties evolve monotonously across the QCP 22,23 . One might argue that the sharp peak in T c (x) at the QCP in Lu(Pt 1−x Pd x ) 2 In can easily be accounted for within standard models for electron-phononmediated SC, since the vanishing frequency of the soft mode phonon can result in a peak in the electron-phonon coupling constant λ at the QCP.…”

Section: Substituting Pd For Pt Suppressesmentioning

confidence: 99%

Charge density wave quantum critical point with strong enhancement of superconductivity

et al. 2017

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led to a great interest in QCPs are the very unusual properties that are observed near a QCP, such as unconventional superconductivity (SC), non-Fermi-liquid or anomalous critical behaviour 3-6 . Quantum fluctuations are therefore suspected to cause these anomalous properties, but most aspects are far from being understood and are still the subject of active discussions. An issue that has attracted great interest is the appearance of unconventional SC observed at magnetic QCPs, that is where a magnetic ordered state is suppressed. Such unconventional SC states have been reported for very different kinds of compounds, for example heavy-fermion systems 3,7 , cuprates 8,9 and iron pnictides 10,11 . There is some evidence that backs up the hypothesis that the binding of electrons into the superconducting Cooper pairs is not mediated by phononic excitations as in classical superconductors, but by magnetic excitations connected to the disappearing magnetic order 12,13 . The fact that SC is observed only in the vicinity of the QCP and presents a strong dependence on the tuning parameter supports this hypothesis. It often results in a dome-like shape of the phase diagram of tuning parameter versus temperature.However, QCPs are not restricted to magnetic systems; they can be associated with any continuous phase transition. While searching for appropriate non-magnetic systems that show a QCP with associated SC, we looked at compounds that show a charge density wave (CDW) type of structural transition. CDW systems present an instability of the electronic states close to the Fermi level F , which results in a modulation of the electronic charges below a transition temperature T CDW (ref. 14). The modulation periodicity is usually associated with a nesting vector of the Fermi surface. Therefore, a gap opens in the electronic density of states (DOS) at F , N ( F ), below T CDW . In one-dimensional (1D) systems, for which such a transition was initially proposed, this effect changes the character of the system from metallic for T > T CDW to insulating for T < T CDW . In 2D or 3D systems, the gap opens only on a part of the Fermi surface and, therefore, the conductivity remains metallic below T CDW . The opening of the gap does, however, lead to a very characteristic upturn of the resistivity ρ(T ) at T CDW .Some CDW transitions can be tuned to a T = 0 critical point as well [15][16][17][18][19][20][21] . The appearance or a strengthening of a superconducting state is frequently found near the vanishing point of the CDW state, similar to magnetic QCPs. Yet, in this case, it can easily be explained within the standard BCS-based theories: the gap associated with the CDW closes at the critical point, resulting in an increase of N ( F ), which, in turn, leads to an increase of the SC transition temperature T c . As a consequence, the dependence of T c on the tuning parameter is usually rather weak in the non-CDW regime beyond the critical point 16,17,[20][21][22][23] . There is currently no clear evidence that quantum critical fluc...

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“…Data points of other materials were obtained from literatures, including β-Bi 2 Pd [109], layered transition metal dichalcogenides NbSe 2 [80], layered cobalt oxide Na 0.35 CoO 2 ·1.3H 2 O [82], quasi-skutteridite cubic superconductors Ca 3 Ir 4 Sn 13 and Sr 3 Ir 4 Sn 13[110,111], heavy fermions superconductors[80][81][82]112], A-15 superconductor V 3 Si[80], doped fullerene superconductor K 3 C 60[80], Chevrel-phase superconductors LaMo 6 S 8 , LaMo 6 Se 8 and PbMo 6 S 8[80,81], organic superconductors (BEDT-TTF) 2 Cu(NCS) 2 (BEDT) and (TMTSF) 2 ClO 4 (TMTSF)[80,81], bismuthates superconductors Ba 1−x K…”

mentioning

confidence: 99%

Unconventional superconductivity in Cu_xBi₂Se₃ from magnetic susceptibility and electrical transport

Fang

You

2020

New J. Phys.

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Although the Cu doped Bi 2 Se 3 topological insulator was discovered and intensively studied for almost a decade, its electrical and magnetic properties in normal state, and the mechanism of 'high-T c ' superconductivity regarding the relatively low-carrier density are still not addressed yet. In this work, we report a systematic investigation of magnetic susceptibility, critical fields, and electrical transport on the nominal Cu 0.20 Bi 2 Se 3 single crystals with T onset c = 4.18 K, the highest so far. The composition analysis yields the Cu stoichiometry of x = 0.09(1). The magnetic susceptibility shows considerable anisotropy and an obvious kink at around 96 K was observed in the magnetic susceptibility for H c, which indicates a charge density anomaly. The electrical transport measurements indicate the two-dimensional (2D) Fermi liquid behavior at low temperatures with a high Kadowaki-Woods ratio, A/γ 2 = 30.3a 0 . The lower critical field at 0 K limit was extracted to be 6.0 Oe for H ab. In the clean limit, the ratio of energy gap to T c was determined to be Δ 0 /k B T c = 2.029 ± 0.124 exceeding the standard BCS value 1.764, suggesting Cu 0.09 Bi 2 Se 3 is a strong-coupling superconductor. The in-plane penetration depth at 0 K was calculated to be 1541.57 nm, resulting in an unprecedented high ratio of T c /λ −2 (0) ∼ = 9.86. Moreover, the ratio of T c to Fermi temperature is estimated to be T c /T 2D F = 0.034. Both ratios fall into the region of unconventional superconductivity according to Uemura's regime, supporting the unconventional superconducting mechanism in Cu x Bi 2 Se 3 . Finally, the enhanced T c value higher than 4 K is proposed to arise from the increased density of states at Fermi energy and strong electron-phonon interaction induced by the charge density instability. 1 K, such as SrTiO 3 (T c ∼ 0.05-0.29 K, n e = 0.65 to 42.4 × 10 20 cm −3 ) [3,4], GeTe (T c ∼ 0.07-0.3 K, n e = 8.6 to 15.2 × 10 20 cm −3 ) [5], and SnTe (T c ∼ 0.034-0.214 K, n p = 7.5 to 20.0 × 10 20 cm −3 ) [6]. To compare with these systems, the T c value of Cu x Bi 2 Se 3 is relatively 'high' given it is a highly doped narrow semiconductor with lower carrier density. However, the mechanism of such anomalous enhanced T c phenomenon remains unclear despite nearly a decade of extensive research. © 2020 The Author(s). Published by IOP Publishing Ltd on behalf of the Institute of Physics and Deutsche Physikalische Gesellschaft New J. Phys. 22 (2020) 053026 Y Fang et alThe emergence and enhancement of superconductivity may occur in various cases by tailoring the ground states of quantum materials. For example, suppression of charge density wave (CDW) by chemical doping or pressure is observed in many systems [7-10], including low dimensional layered Cu x TiSe 2 and three dimensional (3D) alloys Lu(Pt 1−x Pd x ) 2 In and (Sr, Ca) 3 Ir 4 Sn 13 , 3D oxides Ba 1−x K x BiO 3 . Similarly, the magnetic ordering or spin density wave (SDW) have also been suppressed in strongly correlated heavy fermions materials, high-T c cuprates and i...

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Strong enhancement ofs-wave superconductivity near a quantum critical point ofCa3Ir4Sn13

Cited by 35 publications

References 54 publications

Second-order structural transition in the superconductorLa3Co4Sn13

Second-order structural transition in the superconductorLa3Co4Sn13

Charge density wave quantum critical point with strong enhancement of superconductivity

Unconventional superconductivity in Cu_xBi₂Se₃ from magnetic susceptibility and electrical transport

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Strong enhancement ofs-wave superconductivity near a quantum critical point ofCa3Ir4Sn13

Cited by 35 publications

References 54 publications

Second-order structural transition in the superconductorLa3Co4Sn13

Second-order structural transition in the superconductorLa3Co4Sn13

Charge density wave quantum critical point with strong enhancement of superconductivity

Unconventional superconductivity in CuxBi2Se3 from magnetic susceptibility and electrical transport

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Product

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Unconventional superconductivity in Cu_xBi₂Se₃ from magnetic susceptibility and electrical transport