New Chiral Phases of Superfluid 3He Stabilized by Anisotropic Silica

 Aerogel

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Abstract

A rich variety of Fermi systems condense by forming bound pairs, including high temperature [1] and heavy fermion [2] superconductors, Sr2RuO4 [3], cold atomic gases [4], and superfluid 3He [5]. Some of these form exotic quantum states having non-zero orbital angular momentum. We have discovered, in the case of 3He, that anisotropic disorder, engineered from highly porous silica aerogel, stabilizes a chiral superfluid state that otherwise would not exist. Additionally, we find that the chiral axis of this state can be uniquely oriented with the application of a magnetic field perpendicular to the aerogel anisotropy axis. At suffciently low temperature we observe a sharp transition from a uniformly oriented chiral state to a disordered structure consistent with locally ordered domains, contrary to expectations for a superfluid glass phase [6].

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Symmetry of the order parameter in the high-Tc superconductor YBa2Cu3O7- δ

M. Rupp, J Kirtley, C. C. Tsuei … (1995)

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Observation of the Pairing Gap in a Strongly Interacting Fermi Gas

R Grimm, J Denschlag, S. Jochim … (2004)

We study fermionic pairing in an ultracold two-component gas of \(^6\)Li atoms by observing an energy gap in the radio-frequency excitation spectra. With control of the two-body interactions via a Feshbach resonance we demonstrate the dependence of the pairing gap on coupling strength, temperature, and Fermi energy. The appearance of an energy gap with moderate evaporative cooling suggests that our full evaporation brings the strongly interacting system deep into a superfluid state.