Abstract
We present neutron scattering measurements of the phonon-roton and layer modes of liquid helium confined in 28 \AA{} diameter nanopores of FSM-16. The goal is to determine the energy, lifetime, and intensity of the modes as a function of temperature. It is particularly to determine the highest temperature, denoted ${T}_{PR}$, at which well-defined phonon-roton modes are observed at higher wave vector ($Qg0.8$ ${\AA{}}^{\ensuremath{-}1}$) in the nanopores. The temperature ${T}_{PR}$, which can be identified with loss of Bose-Einstein condensation (BEC), can be compared with the superfluid to normal liquid transition temperature, ${T}_{O}$, and other transition temperatures of $^{4}\mathrm{He}$ in the nanopores. The aim is to identify the nature of BEC in a narrow nanopore. Two pressures are investigated, saturated vapor pressure (SVP) and $p=26$ bars. We find that well-defined P-R modes are observed up to temperatures much higher than the conventional superfluid to normal liquid transition temperature, ${T}_{O}$, observed in torsional oscillator measurements, i.e., ${T}_{PR}g{T}_{O}$. At SVP, ${T}_{PR}=1.8$ K and ${T}_{O}=0.9$ K. This supports the interpretation that BEC exists in a localized or partially localized form in the temperature range ${T}_{O}lTl{T}_{PR}$; i.e., there is a localized BEC region lying between the superfluid and fully normal liquid phase, as observed in some other porous media. At close to full filling, the P-R mode energies in FSM-16 are similar to those in bulk liquid $^{4}\mathrm{He}$. However, a substantial P-R mode width at $T\ensuremath{\rightarrow}0$ K and at higher temperatures is observed.
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