Free Energy Functionals for Superfluid 3He
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Keywords:
BCS theory
Cooper pair
Discontinuity (linguistics)
Microscopic theory
A new theory for Cooper pair formation and superconductivity is derived from quantum statistical mechanics. It is shown that zero momentum Cooper pairs have non-local permutations and behave as effective bosons with an internal weight close to unity when bound by a primary minimum in the potential of mean force. For a short-ranged, shallow, and highly curved minimum there is no thermodynamic barrier to condensation. The size of the condensing Cooper pairs found here is orders of magnitude smaller than those found in BCS theory. The new statistical theory is applicable to high temperature superconductors.
Cooper pair
BCS theory
Momentum (technical analysis)
Statistical Mechanics
Zero (linguistics)
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In framework of eigen-functional bosonization method, we introduce an imaginary phase field to uniquely represent electron correlation, and demonstrate that the Landau Fermi liquid theory and the Tomonaga-Luttinger liquid theory can be unified. It is very clear in this framework that the Tomonaga-Luttinger liquid behavior of one-dimensional interacting electron gases originates from their Fermi structure, and the non-Landau-Fermi liquid behavior of 2D interacting electron gases is induced by the long-range electron interaction, while 3D interacting electron gases generally show the Landau Fermi liquid behavior.
Bosonization
Luttinger liquid
Landau quantization
Landau theory
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We show how Fermi liquid theory can be applied to ultra-cold Fermi gases and propose a way to extract the position dependent effective mass and Landau parameters $F_{0}^{s}(r)$ and $F_{0}^{a}(r)$ from the experimental trap profiles, within the local density approximation. We outline the signatures for a Fermi liquid thereby addressing the recent claim that the normal state of a unitary gas is a Fermi liquid phase; this controversial claim counters other evidence for a non-Fermi liquid phase. Understanding these Fermi liquid signatures also bears on recent controversies over the nature of alternative ground states in a (possibly ferromagnetic) Fermi Hubbard gas.
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Abstract We have seen in the previous chapters that the concept of the macroscopic wave functionΨ(r), is central to understanding atomic Bose–Einstein condensates (BEC), superfluid He, and even superconductivity within the Ginzburg–Landau (GL) theory. But the connection between these ideas is not at all clear, since the atom condensates and He are bosonic systems, while super-conductivity is associated with the conduction electrons in metals which are fermions. The physical meaning of the GL order parameter was not explained until after 1957 when Bardeen Cooper and Schrieffer (BCS) published the first truly microscopic theory of superconductivity. Soon afterward the connection was finally established by Gor’ kov. He was able to show that, at least in the range of temperatures near Tc, the GL theory can indeed be derived from the BCS theory. Furthermore this provides a physical interpretation of the nature of the order parameter. Essentially it is describing a macroscopic wave function, or condensate, of Cooper pairs.
Cooper pair
Microscopic theory
BCS theory
Ginzburg–Landau theory
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Shubnikov–de Haas effect
Landau theory
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The Microscopic Theory of Superconductivity: Cooper Pairing and the Bardeen–Cooper–Schrieffer Theory
Abstract One of the important steps leading to the successful formulation of the microscopic theory of superconductivity was the model calculation performed by Cooper (1956) which showed that two electrons, interacting above a filled Fermi sea, had a bound state in the presence of an arbitrarily weak attractive interaction. This chapter first examines Cooper’s calculation. The success of the Cooper model calculation in producing a bound state, with its implication that a proper many-body theory would contain a gap in the excitation spectrum, strongly suggests that the ground state wave function should be constructed from pairs of electrons. However, it is difficult to perform calculations using the many-body pair wave function from Cooper’s model. The chapter then introduces the wave function proposed by Bardeen, Cooper, and Schrieffer (BCS) as an alternative.
Cooper pair
BCS theory
Microscopic theory
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Content (measure theory)
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Cooper pair
BCS theory
Microscopic theory
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In framework of eigen-functional bosonization method, we introduce an imaginary phase field to uniquely represent electron correlation, and demonstrate that the Landau Fermi liquid theory and the Tomonaga-Luttinger liquid theory can be unified. It is very clear in this framework that the Tomonaga-Luttinger liquid behavior of one-dimensional interacting electron gases originates from their Fermi structure, and the non-Landau-Fermi liquid behavior of 2D interacting electron gases is induced by the long-range electron interaction, while 3D interacting electron gases generally show the Landau Fermi liquid behavior.
Bosonization
Luttinger liquid
Landau quantization
Landau theory
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