2016
DOI: 10.1103/physrevb.94.064511
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Electron bubbles and Weyl fermions in chiral superfluidHe3A

Abstract: Electrons embedded in liquid 3 He form mesoscopic bubbles with radii large compared to the interatomic distance between 3 He atoms, voids of N bubble ≈ 200 3 He atoms, generating a negative ion with a large effective mass that scatters thermal excitations. Electron bubbles in chiral superfluid 3 He-A also provide a local probe of the ground state. We develop scattering theory of Bogoliubov quasiparticles by negative ions embedded in 3 He-A that incorporates the broken symmetries of 3 He-A, particularly broken … Show more

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Cited by 22 publications
(48 citation statements)
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“…Although longitudinal conductivity at temperature T ∆ mf is hardly affected by the impurity size or chiral order, the Hall conductivity depends strongly on both. When impurities are smaller than the inverse Fermi wavelength k f R 1 and impurity scattering is predominantly s-wave, the thermal Hall conductivity is severely suppressed for chiral states with ν = 2 but remains finite for ν = 5. Hall transport vanishes in the dirty limit due to the loss of chiral pairing, and bulk transport is absent in the clean limit due to the loss of impurityinduced states at ε = 0.…”
Section: Thermal Conductivity and Anomalous Hall Effectmentioning
confidence: 99%
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“…Although longitudinal conductivity at temperature T ∆ mf is hardly affected by the impurity size or chiral order, the Hall conductivity depends strongly on both. When impurities are smaller than the inverse Fermi wavelength k f R 1 and impurity scattering is predominantly s-wave, the thermal Hall conductivity is severely suppressed for chiral states with ν = 2 but remains finite for ν = 5. Hall transport vanishes in the dirty limit due to the loss of chiral pairing, and bulk transport is absent in the clean limit due to the loss of impurityinduced states at ε = 0.…”
Section: Thermal Conductivity and Anomalous Hall Effectmentioning
confidence: 99%
“…The A-phase of superfluid 3 He was definitively identified as a chiral p-wave superfluid by the observation of anomalous Hall transport of electrons moving through a quasiparticle fluid of chiral Fermions. 4,5 In 2D materials, chiral d-wave superconductivity is predicted for doped graphene 6,7 , while a chiral p-wave state is proposed for MoS. 8 For the 3D pnictide SrPtAs, where there is evidence from µSR of broken time-reversal symmetry onsetting at the superconducting transition, 9 a chiral d-wave state has been proposed theoretically as the ground state.…”
Section: Introductionmentioning
confidence: 99%
“…[42,43] for reviews. Small objects have been extensively studied using the quantum approach, modeling the scattering of quasiparticles from the object by scattering phase shifts [44][45][46][47][48]. We are interested in the motion of the object at velocities exceeding the Landau critical velocity.…”
Section: A Small Objectmentioning
confidence: 99%
“…Thus, ion studies probe excitations of pure 3 He. 20,21 The intrinsic properties of normal and the superfluid phases is rich, well studied and quantitatively understood theoretically. For these reasons superfluid 3 He has been widely thought of as unique compared to electronic superconductors in that BCS pairing occurs in essentially a pristine material free of defects and impurity disorder.…”
Section: Impurities and Disorder In Superfluid 3 Hementioning
confidence: 99%