First-order phase transition driven by competing charge-order fluctuations in 1T'-TaTe2
Abstract
First-order phase transitions, characterized by a discontinuous change in the order parameter, are intriguing phenomena in condensed matter physics. However, the underlying, material-specific, microscopic mechanisms often remain unclear. Here, we unveil a high-temperature incommensurate charge-order precursor with the wave vector q* = (0, 14+δ, 12) in the 1T' phase of TaTe2, which competes with fluctuating high-temperature Ta trimer bonding states at qCO =(0, 13, 0). The precursor state follows the temperature dependence of the hidden incommensurability of the quasi-1D nested Fermi surface. In contrast, the low-temperature commensurate charge order at qCO, characterized by a charge disproportionation of the inequivalent Ta sites, appears to be driven by local chemical bonding. Dynamical lattice calculations identify an imaginary optical mode at q*, involving an in-plane vibration of the Ta atoms forming a chain-like structure that renormalizes below TCO. Our experimental and theoretical observations suggest that the controversial first-order phase transition, as captured by phenomenological Ginzburg-Landau theory, results from the competition between two order parameters: one involving Fermi surface nesting and the other involving local chemical bonding.
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