Bhardwaj, A. and Chauhan, N. S. and Sancheti, Bhagyashree and Pandey, G. N. and Senguttuvan, T. D. and Misra, D. K. (2015) Panoscopically optimized thermoelectric performance of a half-Heusler/full-Heusler based in situ bulk composite Zr0.7Hf0.3Ni1+xSn: an energy and time efficient way. Physical Chemistry Chemical Physics, 17 (44). pp. 30090-30101. ISSN 1463-9076
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Abstract
All scale hierarchical architecturing, matrix/inclusion band alignment and intra-matrix electronic structure engineering, the so called panoscopic approach for thermoelectric materials has been demonstrated to be an effective paradigm for optimizing high ZT. To achieve such hierarchically organized microstructures, composition engineering has been considered to be an efficient strategy. In this work, such a panoscopic concept has been extended to demonstrate for the first time in the case of half-Heusler based thermoelectric materials via a composition engineering route. A series of new off-stoichiometric n-type Zr0.7Hf0.3Ni1+xSn (0 <= x <= 0.10) HH compositions have been modified to derive HH(1 - x)/full-Heusler (FH)(x) composite with an all scale hierarchically modified microstructure with FH inclusions within the matrix to study the temperature dependent thermoelectric properties. The structural analysis employing XRD, FE-SEM and HR-TEM of these materials reveal a composite of HH and FH, with hierarchically organized microstructures. In such a submicron/nano-composite, the electronic properties are observed to be well optimized yielding a large power factor; alpha(2)sigma (similar to 30.7 x 10(-4) W m(-1) K-2 for Zr0.7Hf0.3Ni1.03Sn) and reduced thermal conductivity (similar to 2.4 W m(-1) K-1 for Zr0.7Hf0.3Ni1.03Sn) yielding a high ZT similar to 0.96 at 773 K for composition Zr0.7Hf0.3Ni1.03Sn which is similar to 250% larger than the normal HH Zr0.7Hf0.3NiSn (ZT B 0.27 at 773 K). The enhancement in ZT of these composites has been discussed in terms of primary electron filtering, electron injection and several phonon scattering mechanisms such as alloy scattering, point defect scattering, and grain boundary scattering. The Bergman and Fel model is used to calculate effective thermoelectric parameters of these composites for comparing the experimental results.
Item Type: | Article |
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Subjects: | Chemistry > Physical Chemistry Physics > Atomic and Molecular Physics |
Divisions: | UNSPECIFIED |
Depositing User: | Dr. Rajpal Walke |
Date Deposited: | 06 Oct 2016 06:05 |
Last Modified: | 06 Oct 2016 06:05 |
URI: | http://npl.csircentral.net/id/eprint/1939 |
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