Pressure induced superconductive 10-fold coordinated TaS2: a first-principles study.

By crystal structure prediction and first-principles calculations, we researched the structure transformation and electronic states for a typical transition metal dichalcogenides (TMDs): 1T-TaS2 under hydrostatic pressure. The layered 1T-TaS2 will first transform to an 8-fold monoclinic C2/m phase and then to a 10-fold coordinated tetragonal I4/mmm phase which has 3D covalent bond network linked in space. Our calculations suggest that the lone pair electrons of S in 1T-TaS2, which keep the stablity of the layered structure, will be activated by pressure and participate the chemical bonding with Ta, to form the high-pressure C2/m and I4/mmm phases. Additionally, collective electronic states of superconductivity also retains in the I4/mmm phase and the critical transition temperature of superconductivity is 9 K at 100 GPa.

Doping single transition metal atom into PtTe sheet for catalyzing nitrogen reduction and hydrogen evolution reactions.

We systematically explored the catalytic performance of a novel two dimensional material PtTe sheet for nitrogen reduction reaction (NRR) and hydrogen evolution reaction (HER) by using first-principles calculation. Although pristine PtTe shows poor NRR and HER activity, doping transition metal (TM) atoms into the lattice could effectively enhance the catalytic performance. Calculations show that four TM doped structures, including W-Pt18Te17, Ru-Pt18Te17, Mo-Pt18Te17, and Cr-Pt18Te17, are promising NRR catalysts on the prerequisite of whose HER activities are effectively suppressed. Moreover, the HER performance of the PtTe sheet could also be significantly improved with introduced TM atoms. In particular, Cu, Cr, Co, Ni, Mo, Rh, Ru, and Tc atoms supported by the PtTe sheet with Te-vacancy are promising HER electrocatalysts. The improved HER performance is attributed to the reduced adsorption free energy of the H atom. Both the doped TM atoms and the adjacent Pt atoms are effective active sites. Among all considered structures, Mo-, Cr-, and Ru-Pt18Te17 sheets boost catalytic activity for both NRR and HER. This study provides new design strategies to enhance the catalytic performance of the PtTe sheet for the NRR/HER.

Strain tuning of electronic properties of various dimension elemental tellurium with broken screw symmetry.

We present a systematical study of atomic structures and electronic properties of various dimension tellurium (Te) with broken intrinsical screw symmetry by applying reasonable strain. It is demonstrated that (i) bulk trigonal Te has degenerate Weyl nodes around the H point near the Fermi energy, and this degeneracy will be broken by introducing the selenium (Se) atom through creating the inner unsymmetrical strain, instead of external shear strain. (ii) 2D structures of tetragonal Te (t-Te) and 1T-MoS2-like Te (1T-Te) show direct and indirect band gap, respectively. Under the uniform biaxial compressive (BC) strain, monolayer of t-Te shows the direct-to-indirect band gap transition, while 1T-Te monolayer has a band gap transition firstly from indirect to direct and then from direct to indirect. Their effective masses of hole and electron can be effectively tuned by BC strain. (iii) One-dimensional (1D) structures of single helix, triangular Te and hexagonal Te nanowires display the obvious quantum confinement effect on the band structure and different sensitivity to the effect of uniaxial compressive strain.