Direct observation of roton emission from a single quantized vortex in superfluid 4He, with energy loss per cycle matching the roton gap energy and establishing it as the primary zero-temperature dissipation channel.
Observation of roton emission from a quantized vortex
1 Pith paper cite this work. Polarity classification is still indexing.
abstract
Turbulence in inviscid quantum fluids offers unparalleled access to the universal principles of non-equilibrium dynamics, spanning a vast range of length scales from macroscopic flow down to the individual vortex core. In the zero-temperature limit, the microscopic mechanism by which the turbulent energy cascade terminates in the absence of viscosity remains a foundational challenge in quantum hydrodynamics. While prevailing theoretical descriptions prioritize phonon emission, they fail to account for the strong interatomic correlations that give rise to the roton minimum in superfluid $^4\mathrm{He}$. Here, we report the direct observation of roton emission from a single quantized vortex using a high-quality-factor nanomechanical resonator at 10 mK. We identify a sharp onset of dissipation at a critical velocity, and measure the energy loss per cycle, which corresponds quantitatively to the roton gap energy. Our findings address the long-standing mystery of zero-temperature energy relaxation by establishing roton emission as the primary dissipation channel in strongly correlated quantum liquids.
fields
cond-mat.quant-gas 1years
2026 1verdicts
UNVERDICTED 1representative citing papers
citing papers explorer
-
Observation of roton emission from a quantized vortex
Direct observation of roton emission from a single quantized vortex in superfluid 4He, with energy loss per cycle matching the roton gap energy and establishing it as the primary zero-temperature dissipation channel.