Effects of the two-dimensional Coulomb interaction in both Fermi velocity and energy gap for Dirac-like electrons at finite temperature

Abstract

We describe both the Fermi velocity and the mass renormalization due to the two-dimensional Coulomb interaction in the presence of a thermal bath. To achieve this, we consider an anisotropic version of pseudo quantum electrodynamics (PQED), within a perturbative approach in the fine-structure constant α. Thereafter, we use the so-called imaginary-time formalism for including the thermal bath. In the limit T→ 0, we calculate the renormalized mass mR(p) and compare this result with the experimental findings for the energy band gap in monolayers of transition metal dichalcogenides, namely, WSe2 and MoS2. In these materials, the quasi-particle excitations behave as a massive Dirac-like particles in the low-energy limit, hence, its mass is related to the energy band gap of the material. In the low-temperature limit T vF p , where vF p is taken as the Fermi energy, we show that mR(p) decreases linearly on the temperature, i.e, mR(p,T)-mR(p,T→ 0)≈ -Aα T +O(T3), where Aα is a positive constant. On the other hand, for the renormalized Fermi velocity, we find that vRF(p,T)-vRF(p,T→ 0)≈ -Bα T3 +O(T5), where Bα is a positive constant. We also perform numerical tests which confirm our analytical results.