Nearly isotropic superconductivity in the layered Weyl semimetal WTe2 at 98.5 kbar

Abstract: Layered transition metal dichalcogenide WTe2 has recently attracted significant attention due to the discovery of an extremely large magnetoresistance, a predicted type-II Weyl semimetallic state, and the pressure-induced superconducting state. By a careful measurement of the superconducting upper critical fields as a function of the magnetic field angle at a pressure as high as 98.5 kbar, we provide the first detailed examination of the dimensionality of the superconducting condensate in WTe2. Despite the lay… Show more

“…The nature of H C2 (θ) is in sharp contrast to pressure-induced two-dimensional superconductivity though the γ value is comparable [40]. Similar type of feature in H C2 (θ) has observed in 3D-anisotropic superconductor 2H-NbSe 2 [37][38][39], WTe 2 [41], and gated MoS 2 [42]. Furthermore, the in-plane, ξ GL and out-of-plane coherence lengths ξ ⊥ GL at T = 1.8 K can be extracted from the H C2 data, giving 247 and 166 Å.…”

Superconductivity in doped Weyl semimetal Mo$_{0.9}$Ir$_{0.1}$Te$_{2}$ with broken inversion symmetry

“…The nature of H C2 (θ) is in sharp contrast to pressure-induced two-dimensional superconductivity though the γ value is comparable [40]. Similar type of feature in H C2 (θ) has observed in 3D-anisotropic superconductor 2H-NbSe 2 [37][38][39], WTe 2 [41], and gated MoS 2 [42]. Furthermore, the in-plane, ξ GL and out-of-plane coherence lengths ξ ⊥ GL at T = 1.8 K can be extracted from the H C2 data, giving 247 and 166 Å.…”

Superconductivity in doped Weyl semimetal Mo$_{0.9}$Ir$_{0.1}$Te$_{2}$ with broken inversion symmetry

“…Actually, the rebuilding of the Fermi surface depends on the anisotropy of lattice, and the a-axis, b-axis, and c-axis are compressed by 0.6%, 3.3% and 6.5% respectively. An interesting thing is that the anisotropy of superconductivity becomes very weak at 98.5 kpa by changing the magnetic field angle [ 39 ]. The critical temperature of superconductivity can also be enhanced by in-plane magnetic fields, although it may suppress the superconductivity because of the competition between thermodynamic and magnetic energies [ 40 ].…”

A Review of the Characteristics, Synthesis, and Thermodynamics of Type-II Weyl Semimetal WTe2

“…The integration and the sum in Eqs. (20) and (21) are taken over all the allowed channels specified by the energies E N (X k y , k z ). The reflection probabilities of electronlike and holelike quasiparticle states at the left and the right interfaces of WSM/SWSMs are given by R (e) N,X ky ,k z ,AL = T (he) N,X ky ,k z ,LD , R (e) N,X ky ,k z ,AR = T (he) N,X ky ,k z ,RU , R (h) N,X ky ,k z ,AL = T (eh) N,X ky ,k z ,LD , and R (h) N,X ky ,k z ,AR = T (eh) N,X ky ,k z ,RU , respectively, where T (ab) N,X ky ,k z ,ij is the transmission probability of the mode (N, X k y , k z ) from the type b quasiparticles in terminal j to the type a quasiparticles in terminal i, a and b represent the electronlike (e) and the holelike (h) quasiparticles, and i, j (= L, R, U, D) note the left, right, up, and down terminals, respectively.…”

“…Besides UPt 3 , the unconventional superconductivity is also discovered by hard point contact on the WSM TaAs crystals [16,17]. Experimentally, the superconducting states in the WSM have also been studied in other SWSMs, such as MoTe 2 , WTe 2 , TaP, and TaIrTe 4 [18][19][20][21][22][23].…”

Transverse conductance in a three-dimensional Weyl semimetal and Weyl superconductor hybrid under a strong magnetic field