Ivan N. Katamanin scite author profile

The temperature dependences of the electrical conductivity (T), Seebeck coefficient (T), and heat capacity C p (T) of polycrystalline samples of Bi 2 Te 3 , Bi 2 Te 3 +1%CuI, and Bi 2 Te 3 +1%(CuI+1/2Pb) are investigated in the temperature range below room temperature. Based on the temperature dependences of all investigated physical properties, it is discovered that phase transition occurs at 120-200 K. Investigation of single crystals shows that anomalies in the electrical resistivity ( (T) = 1∕ (T)) occur only across the crystal growth axis (across the well-conducting Bi-Te plane).Investigation of the low-temperature dependence of electrical conductivity shows that all polycrystalline samples exhibit quasi-two-dimensional electron transport. Additionally, quasi-two-dimensional transport is detected in single crystals based on anisotropy analysis ⊥ (T)∕ ‖ (T): 10 (where ‖ (T) is the resistivity along the crystal growth axis, and ⊥ (T) is resistivity across the crystal growth axis) and temperature dependence (T): T 2 below 50 K. The Fermi energy E F is estimated using the temperature dependence of S(T). It is discovered that an increase in E F at T > 200 K is associated with the phase transition. For single-crystal samples, the maximum thermoelectric figure of merit ZT, as observed along the crystal growth axis, increases with doping. A maximum ZT value of ~1.1 is observed for the Bi 2 Te 3 +1%(CuI+1/2Pb) sample at room temperature (T = 300 K).

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Enhanced thermoelectric properties of polycrystalline CuCrS_2−xSe_x (x = 0, 0.5, 1.0, 1.5, 2) samples by replacing chalcogens and sintering

Романенко¹,

Chebanova²,

Katamanin³

et al. 2021

J. Phys. D: Appl. Phys.

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The optimization of thermoelectric properties of the CuCrS2-xSex (x = 0, 0.5, 1.0, 1.5, 2) samples was achieved by substitution in anionic sublattice and sintering at high temperature. The maximum power factor PF ~ 0.3 mW/m•K^2 among a series of samples with chalcogen substitution was obtained for CuCrS0.5Se1.5 sample at T=300 K. The sintering made it possible to obtain the maximum value PF ~ 2.1 mW/m•K2 for CuCrSe2 sample. This is due to a more than threefold increase in the thermoelectric power S(T) in CuCrSe2 sample with a spin-orbital interaction in comparison with CuCrS0.5Se1.5 sample with the same optimal electrical conductivity σ (σ300K ~ 100 S/cm), but without spin-orbital interaction. In CuCrSe2 sample, sintering effectively reduced the s to an optimal value, suppressed of the magnetic phase transition in the range of 50-100 K, and the weak localization were replaced by weak antilocalization indicating the appearance of strong spin-orbit interaction below 20 K. As a result, an additional contribution to the S(T) appeared due to the filtration of current carriers caused by the strong spin-orbit interaction. The effect of grain boundaries on the properties σ(T) and S(T) of the samples was investigated. It was established that polycrystalline samples with a high sulfur content were low-conductivity materials consisting of high-conductivity crystallites with the charge carriers concentration n ~ 1020 cm-3 separated by low-conductivity grain boundaries with fluctuation-induced tunneling conductivity. Both the replacement of sulfur with selenium and sintering led to a decrease in the energy barriers connecting grain boundaries. Selenium-dominated samples (CuCrS0.5Se1.5 and CuCrSe2) had high electrical conductivity with negligible energy barriers between grain boundaries. Logarithmic quantum corrections to the electrical conductivity was observed below 20 K, which indicated a quasi-two-dimensional electron transport in these samples.

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Ivan N. Katamanin

Thermoelectric properties and phase transition of doped single crystals and polycrystals of Bi₂Te₃

Enhanced thermoelectric properties of polycrystalline CuCrS_2−xSe_x (x = 0, 0.5, 1.0, 1.5, 2) samples by replacing chalcogens and sintering

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Ivan N. Katamanin

Thermoelectric properties and phase transition of doped single crystals and polycrystals of Bi2Te3

Enhanced thermoelectric properties of polycrystalline CuCrS2−x Se x (x = 0, 0.5, 1.0, 1.5, 2) samples by replacing chalcogens and sintering

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Thermoelectric properties and phase transition of doped single crystals and polycrystals of Bi₂Te₃

Enhanced thermoelectric properties of polycrystalline CuCrS_2−xSe_x (x = 0, 0.5, 1.0, 1.5, 2) samples by replacing chalcogens and sintering