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Development and application of computational quantum many-body methods for strongly correlated models and materials

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dc.contributor.advisor Vidhyadhiraja, N.S.
dc.contributor.author Dasari, Nagamalleswara Rao
dc.date.accessioned 2021-01-29T11:33:45Z
dc.date.available 2021-01-29T11:33:45Z
dc.date.issued 2015
dc.identifier.citation Dasari, Nagamalleswara Rao. 2015, Development and application of computational quantum many-body methods for strongly correlated models and materials, Ph.D thesis, Jawaharlal Nehru Centre for Advanced Scientific Research, Bengaluru en_US
dc.identifier.uri https://libjncir.jncasr.ac.in/xmlui/handle/123456789/3079
dc.description.abstract DFT, however, fails to explain the spectral properties of solids which have partially lled d and f shells. For this class of compounds, DFT quite often predicts a metallic ground state but experiments show that they are insulators. Due to the localized nature of d and f orbitals in space, screening of Coulomb interaction between electrons in those orbitals is poor. Thus, the electrons in d and f orbitals experience a much higher Coulomb repulsion than in the s/p orbitals, leading to strong correlation e ects, which in turn imply the break down of any effective one particle picture where the ground state wavefunction of the system is a combination of Slater determinants, and there are no well de ned one electron excitations in the system. Because of strong correlations, these systems exhibit interesting properties and phases. The materials which come under this category are termed as strongly correlated electronic systems (SCES). Typical examples of SCES[10] include cuprates, rare-earth compounds, actinides and transition metal oxides. Some of the features of strong correlation e ects include metal to Mott transition in V2O3[11{16], itinerant magnetism in transition metal oxides[17], giant magneto-resistance in manganites[18, 19], and hightemperature superconductivity in cuprates[20]. Theoretical studies of SCES require quantum many-body methods which are capable of handling strong correlations between electrons. Traditionally, these methods have been applied to studying model Hamiltonian's, that ignore material speci c information. With the advent of dynamical mean- eld theory (DMFT), en_US
dc.language.iso English en_US
dc.publisher Jawaharlal Nehru Centre for Advanced Scientific Research en_US
dc.rights © 2015 JNCASR
dc.subject Computational methods en_US
dc.subject Many-body problem en_US
dc.subject Quantum field theory en_US
dc.title Development and application of computational quantum many-body methods for strongly correlated models and materials en_US
dc.type Thesis en_US
dc.type.qualificationlevel Doctoral en_US
dc.type.qualificationname Ph.D. en_US
dc.publisher.department Theoretical Sciences Unit (TSU) en_US


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