Influence of spherical inclusions on effective thermoelectric properties of thermoelectric composite materials

Abstract: A homogenization theory is developed to predict the influence of spherical inclusions on the effective thermoelectric properties of thermoelectric composite materials based on the general principles of thermodynamics and Mori–Tanaka method. The closed-form solutions of effective Seebeck coefficient, electric conductivity, heat conductivity, and figure of merit for such thermoelectric materials are obtained by solving the nonlinear coupled transport equations of electricity and heat. It is found that the effect… Show more

“…During the past decade, topological states of matter have emerged as a major area of research in condensed matter physics. − With inspiration from earlier work on topological insulators, − the research focus is now shifting toward gapless topological phases, particularly topological semimetals (TSMs). − TSMs exhibit nontrivial band crossings (BCs) between valence and conduction bands in momentum space protected by certain symmetries, such that the quasiparticles behave drastically different from the conventional Schrödinger-type fermions. For instance, in Dirac − and Weyl semimetals, − the zero-dimension (0D) BCs between conduction and valence bands, accompanied by fourfold and twofold degeneracies, occur at isolated k points around which the low-energy quasiparticles resemble relativistic Dirac and Weyl fermions, allowing high-energy physics to be simulated in a desktop setting.…”

Topological Nodal Surface and Quadratic Dirac Semimetal States and van Hove Singularities in ScH₃ and LuH₃ Superconductors

“…During the past decade, topological states of matter have emerged as a major area of research in condensed matter physics. − With inspiration from earlier work on topological insulators, − the research focus is now shifting toward gapless topological phases, particularly topological semimetals (TSMs). − TSMs exhibit nontrivial band crossings (BCs) between valence and conduction bands in momentum space protected by certain symmetries, such that the quasiparticles behave drastically different from the conventional Schrödinger-type fermions. For instance, in Dirac − and Weyl semimetals, − the zero-dimension (0D) BCs between conduction and valence bands, accompanied by fourfold and twofold degeneracies, occur at isolated k points around which the low-energy quasiparticles resemble relativistic Dirac and Weyl fermions, allowing high-energy physics to be simulated in a desktop setting.…”

Topological Nodal Surface and Quadratic Dirac Semimetal States and van Hove Singularities in ScH₃ and LuH₃ Superconductors

“…To summarize, nanocompositing is one of the best strategies for attaining an ultralow κ as it offers the combined effects of interfaces, fine grain boundaries, and complex structural defects. ,, An optimum concentration of nanoinclusions with excellent σ and thermal resistivity higher than that of the matrix will be the best choice to produce a high ZT . , In this Review, we try to summarize the advantages of nanocomposites experienced in various thermoelectric host materials. We also emphasize this technique as a facile way to improve their power conversion efficiencies irrespective of their inherited properties.…”

Insights into the Classification of Nanoinclusions of Composites for Thermoelectric Applications

Frictional contact analysis of a rigid solid with periodic surface sliding on the thermoelectric material