Your search keyword '"Serhiienko, Illia"' showing total 3 results

1. Record‐High Thermoelectric Performance in Al‐Doped ZnO via Anderson Localization of Band Edge States.

Author

Serhiienko, Illia, Novitskii, Andrei, Garmroudi, Fabian, Kolesnikov, Evgeny, Chernyshova, Evgenia, Sviridova, Tatyana, Bogach, Aleksei, Voronin, Andrei, Nguyen, Hieu Duy, Kawamoto, Naoyuki, Bauer, Ernst, Khovaylo, Vladimir, and Mori, Takao

Subjects

*ANDERSON localization, *THERMAL conductivity, *SEEBECK coefficient, *DEBYE temperatures, *CONDUCTION bands, *ZINC oxide, *BISMUTH telluride

Abstract

Oxides are of interest for thermoelectrics due to their high thermal stability, chemical inertness, low cost, and eco‐friendly constituting elements. Here, adopting a unique synthesis route via chemical co‐precipitation at strongly alkaline conditions, one of the highest thermoelectric performances for ZnO ceramics (PFmax=$PF_{\text{max}} =$ 21.5 µW cm−1 K−2 and zTmax=$zT_{\text{max}} =$ 0.5 at 1100 K in Zn0.96Al0.04O${\rm Zn}_{0.96} {\rm Al}_{0.04}{\rm O}$) is achieved. These results are linked to a distinct modification of the electronic structure: charge carriers become trapped at the edge of the conduction band due to Anderson localization, evidenced by an anomalously low carrier mobility, and characteristic temperature and doping dependencies of charge transport. The bi‐dimensional optimization of doping and carrier localization enable a simultaneous improvement of the Seebeck coefficient and electrical conductivity, opening a novel pathway to advance ZnO thermoelectrics. [ABSTRACT FROM AUTHOR]

Published

2024

2. Defect Engineering of Bi2SeO2 Thermoelectrics.

Author

Novitskii, Andrei, Toriyama, Michael Y., Serhiienko, Illia, Mori, Takao, Snyder, G. Jeffrey, and Gorai, Prashun

Subjects

*THERMODYNAMIC control, *ELECTRON mobility, *CARRIER density, *ELECTRON scattering, *CRYSTAL grain boundaries

Abstract

Bi2SeO2 is a promising n‐type semiconductor to pair with p‐type BiCuSeO in a thermoelectric (TE) device. The TE figure of merit zT and, therefore, the device efficiency must be optimized by tuning the carrier concentration. However, electron concentrations in self‐doped n‐type Bi2SeO2 span several orders of magnitude, even in samples with the same nominal compositions. Such unsystematic variations in the electron concentration have a thermodynamic origin related to the variations in native defect concentrations. In this study, first‐principles calculations are used to show that the selenium vacancy, which is the source of n‐type conductivity in Bi2SeO2, varies by 1–2 orders of magnitude depending on the thermodynamic conditions. It is predicted that the electron concentration can be enhanced by synthesizing under more Se‐poor conditions and/or at higher solid‐state reaction temperatures (TSSR), which promote the formation of selenium vacancies without introducing extrinsic dopants. The computational predictions are validated through solid‐state synthesis of Bi2SeO2. More than two orders of magnitude increase are observed in the electron concentration simply by adjusting the synthesis conditions. Additionally, a significant effect of grain boundary scattering on the electron mobility in Bi2SeO2 is revealed, which can also be controlled by adjusting TSSR. By simultaneously optimizing the electron concentration and mobility, a zT of ≈0.2 is achieved at 773 K for self‐doped n‐type Bi2SeO2. The study highlights the need for careful control of thermodynamic growth conditions and demonstrates TE performance improvement by varying synthesis parameters according to thermodynamic guidelines. [ABSTRACT FROM AUTHOR]

Published

2024

3. Ultralow Thermal Conductivity in Dual‐Doped n‐Type Bi2Te3 Material for Enhanced Thermoelectric Properties.

Author

Musah, Jamal‐Deen, Guo, Chen, Novitskii, Andrei, Serhiienko, Illia, Adesina, Ayotunde Emmanuel, Khovaylo, Vladimir, Wu, Chi‐Man Lawrence, Zapien, Juan Antonio, and Roy, Vellaisamy A. L.

Subjects

THERMOELECTRIC materials, THERMAL conductivity, ELECTRIC conductivity, ELECTRON density, PHONON scattering, ACOUSTIC phonons, SEEBECK coefficient

Abstract

Bismuth chalcogenides are promising materials for thermoelectric (TE) application due to their high power factor (product of the square of the Seebeck coefficient and electrical conductivity). However, their high thermal conductivity is an issue of concern. Single doping has proven to be useful in improving TE performance in recent years. Here, it is shown that dual isovalent doping shows the synergistic effect of thermal conductivity reduction and electron density control. The insertion of large atoms in the layered Bi2Te3 structure distorts the crystal lattice and contributes significantly to phonon scattering. The ultralow thermal conductivity (KT = 0.35 W m−1 K−1 at 473 K) compensates for the low power factor and thus enhances TE performance. The density functional theory electronic structure calculation results reveal deep defects states in the valence band, which influences the electronic transport properties of the system. Therefore, the dual dopants (indium and antimony) show a coupled effect of improvement in the density of state near the Fermi level and reduction in the conduction band minimum, thus enhancing electron density. Numerically, it is demonstrated that the dual doping favors acoustic phonon scattering and thus drastically reduces the thermal conductivity. [ABSTRACT FROM AUTHOR]

Published

2021