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      Temperature dependence of resistivity at the transition to a charge density wave state in rare-earth tritellurides

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          Abstract

          About a half of the Fermi surface in rare-earth tritellurides RT e3 becomes gapped below the transition to a charge-density-wave (CDW) state, as revealed by ARPES data. However, the observed jump in resistivity during the CDW transition is less than 20%. Previously this phenomenon was explained by hypothesizing a very slow evolution of CDW energy gap below transition temperature in RTe3 compounds, which contradicts the X-ray measurements. Here we show that this weak change in resistivity can be explained in the framework of standard mean-field temperature dependence of the CDW energy gap in agreement with X-ray data. The change of resistivity caused by CDW is weak because the decrease in conducting electron density at the Fermi level is almost compensated by the decrease in their scattering rate. We calculate resistivity in RTe3 compounds using the Boltzmann transport equation and the mean-field description of the CDW state, and obtain a good agreement with experimental data.

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          Electronic crystals: an experimental overview

          This article reviews the static and dynamic properties of spontaneous superstructures formed by electrons. Representations of such electronic crystals are charge density waves and spin density waves in inorganic as well as organic low dimensional materials. A special attention is paid to the collective effects in pinning and sliding of these superstructures, and the glassy properties at low temperature. Charge order and charge disproportionation which occur in organic materials resulting from correlation effects are analysed. Experiments under magnetic field, and more specifically field-induced charge density waves are discussed. Properties of meso- and nanostructures of charge density waves are also reviewed.
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            Author and article information

            Journal
            16 December 2018
            Article
            1812.06497
            c8ea3870-b5cd-4541-b17c-afdc79619e43

            http://arxiv.org/licenses/nonexclusive-distrib/1.0/

            History
            Custom metadata
            6 Pages, 2 Figures, To be published in IOP Journal of Physics Conference Series
            cond-mat.supr-con

            Condensed matter
            Condensed matter

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