Your search keyword '"Jin Ni"' showing total 5 results

1. Chemical Modification and Energetically Favorable Atomic Disorder of a Layered Thermoelectric Material TmCuTe2Leading to High Performance

Author

Li-Ming Wu, Hua Lin, Jin-Ni Shen, Hong Chen, and Ling Chen

Subjects

Chemistry, Organic Chemistry, Nanotechnology, General Chemistry, Electronic structure, Crystal structure, Thermoelectric materials, Catalysis, Thermal conductivity, Chemical physics, Vacancy defect, Seebeck coefficient, Thermoelectric effect, Substructure

Abstract

Thermoelectric (TE) materials have continuously attracted interest worldwide owing to their capability of converting heat into electricity. However, discovery and design of new TE material system remains one of the greatest difficulties. A TE material, TmCuTe2 , has been designed by a substructure approach and successfully synthesized. The structure mainly features CuTe4 -based layers stacking along the c axis that are separated by Tm(3+) cations. Such an intrinsic Cu site vacancy structure undergoes a first-order phase transition at around 606 K driven by the energetically favorable uniform Cu atom re-distribution on the covalent CuTe4 -based layer substructure, as shown by crystal structure simulations and variable-temperature XRD data. Featured with very low thermal conductivity (ca. 0.6 W m(-1) K(-1) ), large Seebeck coefficient (+185 μV K(-1) ), and moderate electrical conductivity (220 S cm(-1) ), TmCuTe2 has a maximum ZT of 0.81 at 745 K, which is nine times higher than the value of 0.09 for binary Cu2 Te, thus making it a promising candidate for mid-temperature TE applications. Theoretical studies uncover the electronic structure modifications from the metallic Cu2 Te to the narrow gap semiconductor TmCuTe2 that lead to such a remarkable performance enhancement.

Published

2014

2. Supercubooctahedron (Cs6Cl)2Cs5[Ga15Ge9Se48] Exhibiting Both Cation and Anion Exchange

Author

Huang-Fu, Shang-Xiong, primary, Shen, Jin-Ni, additional, Lin, Hua, additional, Chen, Ling, additional, and Wu, Li-Ming, additional

Published

2015

3. Chemical Modification and Energetically Favorable Atomic Disorder of a Layered Thermoelectric Material TmCuTe2 Leading to High Performance

Author

Lin, Hua, primary, Chen, Hong, additional, Shen, Jin‐Ni, additional, Chen, Ling, additional, and Wu, Li‐Ming, additional

Published

2014

4. Supercubooctahedron (Cs6Cl)2Cs5[Ga15Ge9Se48] Exhibiting Both Cation and Anion Exchange.

Author

Huang ‐ Fu , Shang ‐ Xiong, Shen , Jin ‐ Ni, Lin, Hua, Chen, Ling, and Wu, Li ‐ Ming

Subjects

*SINGLE crystals, *CRYSTAL whiskers, *X-rays, *IONIZING radiation, *X-ray spectra, *ENERGY-band theory of solids, *ELECTRONIC structure

Abstract

A novel type of supertetrahedral connectivity is exhibited by the 72-atom discrete supercubooctahedron in (Cs6Cl)2Cs5[Ga15Ge9Se48] ( 1), which undergoes both cation and anion exchange, as revealed by unambiguous single-crystal X-ray diffraction data. Electronic-structure studies helped to understand the Ge/Ga distribution. [ABSTRACT FROM AUTHOR]

Published

2015

5. Chemical Modification and Energetically Favorable Atomic Disorder of a Layered Thermoelectric Material TmCuTe2 Leading to High Performance.

Author

Lin, Hua, Chen, Hong, Shen, Jin ‐ Ni, Chen, Ling, and Wu, Li ‐ Ming

Subjects

THERMOELECTRIC materials, THERMOELECTRICITY, PERFORMANCES, THERMAL conductivity, PHASE transitions

Abstract

Thermoelectric (TE) materials have continuously attracted interest worldwide owing to their capability of converting heat into electricity. However, discovery and design of new TE material system remains one of the greatest difficulties. A TE material, TmCuTe2, has been designed by a substructure approach and successfully synthesized. The structure mainly features CuTe4-based layers stacking along the c axis that are separated by Tm3+ cations. Such an intrinsic Cu site vacancy structure undergoes a first-order phase transition at around 606 K driven by the energetically favorable uniform Cu atom re-distribution on the covalent CuTe4-based layer substructure, as shown by crystal structure simulations and variable-temperature XRD data. Featured with very low thermal conductivity (ca. 0.6 W m−1 K−1), large Seebeck coefficient (+185 μV K−1), and moderate electrical conductivity (220 S cm−1), TmCuTe2 has a maximum ZT of 0.81 at 745 K, which is nine times higher than the value of 0.09 for binary Cu2Te, thus making it a promising candidate for mid-temperature TE applications. Theoretical studies uncover the electronic structure modifications from the metallic Cu2Te to the narrow gap semiconductor TmCuTe2 that lead to such a remarkable performance enhancement. [ABSTRACT FROM AUTHOR]

Published

2014