Normal-superfluid interface for polarized fermion gases

B. Van Schaeybroeck; A. Lazarides

Normal-superfluid interface for polarized fermion gases

B. Van Schaeybroeck, A. Lazarides

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Abstract

Recent experiments on imbalanced fermion gases have proved the existence of a sharp interface between a superfluid and a normal phase. We show that, at the lowest experimental temperatures, a temperature difference between normal N and superfluid SF phases can appear as a consequence of the blocking of energy transfer across the interface. Such blocking is a consequence of the existence of a SF gap, which causes low-energy normal particles to be reflected from the N-SF interface. Our quantitative analysis is based on the Hartree- Fock–Bogoliubov–de Gennes formalism, which allows us to give analytical expressions for the thermodynamic properties and characterize the possible interface scattering regimes, including the case of unequal masses. Our central result is that the thermal conductivity is exponentially small at the lowest experimental temperatures.

Original language	Undefined/Unknown
Pages (from-to)	053612/1-053612/11
Number of pages	11
Journal	Physical review. A, Atomic, molecular and optical physics
Volume	79
Publication status	Published - 2009

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Cite this

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title = "Normal-superfluid interface for polarized fermion gases",

abstract = "Recent experiments on imbalanced fermion gases have proved the existence of a sharp interface between a superfluid and a normal phase. We show that, at the lowest experimental temperatures, a temperature difference between normal N and superfluid SF phases can appear as a consequence of the blocking of energy transfer across the interface. Such blocking is a consequence of the existence of a SF gap, which causes low-energy normal particles to be reflected from the N-SF interface. Our quantitative analysis is based on the Hartree- Fock–Bogoliubov–de Gennes formalism, which allows us to give analytical expressions for the thermodynamic properties and characterize the possible interface scattering regimes, including the case of unequal masses. Our central result is that the thermal conductivity is exponentially small at the lowest experimental temperatures.",

author = "{Van Schaeybroeck}, B. and A. Lazarides",

year = "2009",

language = "Undefined/Unknown",

volume = "79",

pages = "053612/1--053612/11",

journal = "Physical review. A, Atomic, molecular and optical physics",

issn = "1050-2947",

publisher = "American Physical Society",

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TY - JOUR

T1 - Normal-superfluid interface for polarized fermion gases

AU - Van Schaeybroeck, B.

AU - Lazarides, A.

PY - 2009

Y1 - 2009

N2 - Recent experiments on imbalanced fermion gases have proved the existence of a sharp interface between a superfluid and a normal phase. We show that, at the lowest experimental temperatures, a temperature difference between normal N and superfluid SF phases can appear as a consequence of the blocking of energy transfer across the interface. Such blocking is a consequence of the existence of a SF gap, which causes low-energy normal particles to be reflected from the N-SF interface. Our quantitative analysis is based on the Hartree- Fock–Bogoliubov–de Gennes formalism, which allows us to give analytical expressions for the thermodynamic properties and characterize the possible interface scattering regimes, including the case of unequal masses. Our central result is that the thermal conductivity is exponentially small at the lowest experimental temperatures.

AB - Recent experiments on imbalanced fermion gases have proved the existence of a sharp interface between a superfluid and a normal phase. We show that, at the lowest experimental temperatures, a temperature difference between normal N and superfluid SF phases can appear as a consequence of the blocking of energy transfer across the interface. Such blocking is a consequence of the existence of a SF gap, which causes low-energy normal particles to be reflected from the N-SF interface. Our quantitative analysis is based on the Hartree- Fock–Bogoliubov–de Gennes formalism, which allows us to give analytical expressions for the thermodynamic properties and characterize the possible interface scattering regimes, including the case of unequal masses. Our central result is that the thermal conductivity is exponentially small at the lowest experimental temperatures.

M3 - Article

SN - 1050-2947

VL - 79

SP - 053612/1-053612/11

JO - Physical review. A, Atomic, molecular and optical physics

JF - Physical review. A, Atomic, molecular and optical physics

ER -