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Theoretical modelling of nano-structured (Hf,Zr)N/(Sc,Y)N metal/semiconductor superlattices for thermoelectric energy conversion

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dc.contributor.advisor Waghmare, Umesh V.
dc.contributor.author Saha, Bivas
dc.date.accessioned 2020-07-21T14:45:09Z
dc.date.available 2020-07-21T14:45:09Z
dc.date.issued 2010
dc.identifier.citation Saha, Bivas. 2010, Theoretical modelling of nano-structured (Hf,Zr)N/(Sc,Y)N metal/semiconductor superlattices for thermoelectric energy conversion, MS thesis, Jawaharlal Nehru Centre for Advanced Scientific Research, Bengaluru en_US
dc.identifier.uri https://libjncir.jncasr.ac.in/xmlui/handle/10572/2889
dc.description Open access en_US
dc.description.abstract Thermoelectric materials that convert heat flux into electrical energy are a topic of great scientific interest because of their potential to deal with the present day energy challenges. Wide range applications and commercialization of these materials though critically depends on our ability to improve their efficiency by at least two to three folds from the present day laboratory value. The present thesis work deals with modelling how electrons and phonons behave in nano-structured metal/semiconductor superlattices based on (Hf,Zr)N/(Sc,Y)N system, using first-principles density functional theory based calculations. Electronic structure, vibrational spectra, and thermal properties of these nitrides in bulk form are determined. The superlattices, made of these nitrides are simulated to understand their potential and suitability for thermoelectric applications. The first chapter of the thesis provides a brief introduction to thermoelectric materials, and related research. Starting from basic concepts like Seebeck and Peltier effect, we have invoked modern concepts like Mahan & Sofo theory, and Boltzmann transport theory to present the theoretical basis of advanced thermoelectric materials. The conflicting design challenges that prevent us from developing highly efficient thermoelectric materials are also discussed. Insightful pictures about the metal/semiconductor superlattices are given, and their working principle is discussed. In the second chapter, we present the electronic structure, vibrational spectra, and thermal properties of bulk ScN, ZrN, and HfN. Hubbard U correction is used to fit the band gap with the experimental values and to connect it with the transport related effective mass calculations. Vibrational spectra, lattice specific heat, and lattice thermal conductivity are also estimated to understand their potential to be used as component materials for metal/semiconductor superlattices. In the third chapter, we have used a combination of (1) generalised gradient approximation (GGA), (2) A Hubbard U correction along with GGA, and (3) GW approximation to estimate band gaps, effective masses, and volume deformation potentials of YN. Vibrational spectra, and thermal properties are estimated to understand its potential and suitability for alloying with other nitrides for thermoelectric applications. The last chapter of this thesis contains extensive theoretical analysis of ZrN/ScN and HfN/ScN metal/semiconductor superlattices for thermoelectric applications. The crystal structure, interface energy density, and inter planer distances are discussed. Electronic structures of these superlattices are calculated, and enhancement of Seebeck coefficient along the growth direction is discussed. Vibrational spectrum, lattice thermal conductivity, and its dependence on temperature, and contribution of phonons as a function of frequency is analysed. Finally we comment on the relative superiority of HfN based systeM.S. over ZrN ones. en_US
dc.language.iso English en_US
dc.publisher Jawaharlal Nehru Centre for Advanced Scientific Research en_US
dc.rights © 2010 JNCASR en_US
dc.subject Nano structure en_US
dc.subject Thermoelectric energy conversion en_US
dc.title Theoretical modelling of nano-structured (Hf,Zr)N/(Sc,Y)N metal/semiconductor superlattices for thermoelectric energy conversion en_US
dc.type Thesis en_US
dc.type.qualificationlevel Master en_US
dc.type.qualificationname MS en_US
dc.publisher.department Chemistry and Physics of Materials Unit (CPMU) en_US


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