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Zr-based quaternary half-Heusler alloy systems ZrNimX0.5Sb1.5−m (X]Fe/ In): Studies on phase evolution, crystal structures and electronic properties

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dc.contributor.author kumar, Dipanjan
dc.contributor.author Legese, Surafel Shiferaw
dc.contributor.author Mukherjee, Shriparna
dc.contributor.author Femi, Olu Emmanuel
dc.contributor.author Narayanan, Ravishankar
dc.contributor.author Chattopadhyay, Kamanio
dc.date.accessioned 2022-05-16T07:52:54Z
dc.date.available 2022-05-16T07:52:54Z
dc.date.issued 2022-03-16
dc.identifier.uri https://repository.ju.edu.et//handle/123456789/7266
dc.description.abstract Half Heusler(hH) compounds have demonstrated exceptional capability in a wide range of functional ap plications as semiconductors. Although there are theoretical predictions about newer compounds and their thermodynamic stability, experimental validation is often missing. In this study, we report two quaternary multicomponent Zr-based hH alloy systems, namely ZrNi0.5Fe0.5Sb and ZrNiIn0.5Sb0.5, designed by com bining 19 and 17 VEC (valence electron count) alloy systems. The structural features, including the crystal structures and compositions, were established using multiple techniques like X-ray diffraction, scanning and transmission electron microscopy. Both these systems crystallized in signature hH cubic structure (F4 3 m) having lattice parameters 0.6091 nm and 0.6104 nm, respectively. The measurement of Seebeck coefficients over a wide temperature range showed p-to n-type semiconductor transition in ZrNi0.5Fe0.5Sb at around 888 K due to bipolar conduction. Subsequently, the partial substitution of Co for Fe sites (ZnNi0.5Fe0.3Co0.2Sb) completely suppressed the bipolar conductivity, making it a n-type semiconductor and increased the absolute value of Seebeck coefficient, by an order of magnitude, to − 133μV/K. The alloy ZrNiIn0.5Sb0.5 showed n-type semiconductor behavior throughout the measurement temperature range. This study conducts an in-depth examination of the microstructural phase evolution, chemical environment of the elements forming the novel hH phase and demonstrates the tunability of electronic properties through aliovalent substitutions at various lattice sites. en_US
dc.language.iso en_US en_US
dc.subject Half-Heusler alloys en_US
dc.subject Quaternary en_US
dc.subject Disordered en_US
dc.subject TEM en_US
dc.subject Aliovalent substitutions en_US
dc.subject Semiconductor en_US
dc.title Zr-based quaternary half-Heusler alloy systems ZrNimX0.5Sb1.5−m (X]Fe/ In): Studies on phase evolution, crystal structures and electronic properties en_US
dc.type Article en_US


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