Electron-hole response function of transition metal trichalcogenides NbSe3 and monoclinic-TaS3

Abstract

NbSe3 and monoclinic-TaS3 (m-TaS3) are quasi-1D metals containing three different types of chains and undergoing two different charge density wave (CDW) Peierls transitions at TP1 and TP2. The nature of these transitions is discussed on the basis of first-principles DFT calculation of their electron-hole Lindhard response function. As a result of stronger inter-chain interactions the Fermi surface (FS) and Lindhard function of NbSe3 are considerably more complex than those for m-TaS3; however a common scenario can be put forward to rationalize the results. The intra-chain inter-band nesting processes dominate the strongest response for both type I and type III chains of the two compounds. Two well-defined maxima of the Lindhard response for NbSe3 are found with the (0a*, 0c*) and (1/2a*, 1/2c*) transverse components at TP1 and TP2, respectively, whereas the second maximum is not observed for m-TaS3 at TP2. Analysis of the different inter-chain coupling mechanisms leads to the conclusion that FS nesting effects are only relevant to set the transverse a* components in NbSe3. For the transverse coupling along c* in NbSe3 and along both a* and c* for m-TaS3, one must take into account the strongest inter-chain Coulomb coupling mechanism. Phonon spectrum calculations show the formation of a giant 2kF Kohn anomaly in m-TaS3. All these results support the weak coupling scenario for the Peierls transition of transition metal trichalcogenides.