Dissipation signatures of the normal and superfluid phases in torsion pendulum experiments with 3He in aerogel

TL;DR

This study investigates energy dissipation in superfluid 3He confined in aerogel using torsion pendulum experiments, revealing phase-dependent dissipation behaviors and suggesting additional mechanisms beyond existing models.

Contribution

It provides new insights into dissipation signatures of superfluid phases in aerogel, highlighting phase-dependent dissipation and the influence of aerogel compression.

Findings

Q^{-1} above T_c is temperature independent with weak pressure dependence

Dissipation peaks at intermediate temperatures below T_c

ESP phase exhibits higher dissipation than B phase, proportional to superfluid density ratio

Abstract

We present data for energy dissipation factor (Q^{-1}) over a broad temperature range at various pressures of a torsion pendulum setup used to study 3He confined in a 98% open silica aerogel. Values for Q^{-1} above T_c are temperature independent and have a weak pressure dependence. Below T_c, a deliberate axial compression of the aerogel by 10% widens the range of metastability for a superfluid Equal Spin Pairing (ESP) state; we observe this ESP phase on cooling and the B phase on warming over an extended temperature region. While the dissipation for the B phase tends to zero as T goes to 0, Q^{-1} exhibits a peak value greater than that at T_c at intermediate temperatures. Values for Q^{-1} in the ESP phase are consistently higher than in the B phase and are proportional to \rho_s/\rho until the ESP to B phase transition is attained. We apply a viscoelastic collision-drag model, which couples the motion of the helium and the aerogel through a frictional relaxation time \tau_f. Our dissipation data is not sensitive to the damping due to the presumed small but non-zero value of \tau_f. The result is that an additional mechanism to dissipate energy not captured in the collision-drag model and related to the emergence of the superfluid order must exist. The extra dissipation below T_c is possibly associated with mutual friction between the superfluid phases and the clamped normal fluid. The pressure dependence of the measured dissipation in both superfluid phases is likely related to the pressure dependence of the gap structure of the "dirty" superfluid. The large dissipation in the ESP state is consistent with the phase being the A or the Polar with the order parameter nodes oriented in the plane of the cell and perpendicular to the aerogel anisotropy axis.