Detailed dual-doppler structure of kelvin-helmholtz waves from an airborne profiling radar over complex terrain. Part II: Evidence for precipitation enhancement from observations and modeling

Coltin Grasmick, Bart Geerts, Xia Chu, Jeffrey R. French, Robert M. Rauber

Research output: Contribution to journalArticlepeer-review

Abstract

Kelvin-Helmholtz (KH) waves are a frequent source of turbulence in stratiform precipitation systems over mountainous terrain. KH waves introduce large eddies into otherwise laminar flow, with updrafts and downdrafts generating small-scale turbulence. When they occur in cloud, such dynamics influence microphysical processes that impact precipitation growth and fallout. Part I of this paper used dual-Doppler, 2D wind and reflectivity measurements from an airborne cloud radar to demonstrate the occurrence of KH waves in stratiform orographic precipitation systems and identified four mechanisms for triggering KH waves. In Part II, we use similar observations to explore the effects of KH wave updrafts and turbulence on cloud microphysics. Measurements within KH wave updrafts reveal the production of liquid water in otherwise ice-dominated clouds, which can contribute to snow generation or enhancement via depositional and accretional growth. Fallstreaks beneath KH waves contain higher ice water content, composed of larger and more numerous ice particles, suggesting that KH waves and associated turbulence may also increase ice nucleation. A large-eddy simulation (LES), designed to model the microphysical response to the KH wave eddies in mixed-phase cloud, shows that depositional and accretional growth can be enhanced in KH waves, resulting in more precipitation when compared to a baseline simulation. While sublimation and evaporation occur in KH downdrafts, persistent supersaturation with respect to ice allows for a net increase in ice mass. These modeling results and observations suggest that KH waves embedded in mixed-phase stratiform clouds may increase precipitation, although the quantitative impact remains uncertain.

Original languageEnglish (US)
Pages (from-to)3445-3472
Number of pages28
JournalJournal of the Atmospheric Sciences
Volume78
Issue number11
DOIs
StatePublished - Nov 2021

Keywords

  • Eddies
  • Gravity waves
  • Kelvin-Helmholtz instabilities
  • Large eddy simulations
  • Mountain waves
  • Orographic effects
  • Radars/Radar observations
  • Remote sensing
  • Snowfall
  • Tmospheric
  • Turbulence
  • Vertical motion
  • Wave breaking
  • Waves
  • Wind shear

ASJC Scopus subject areas

  • Atmospheric Science

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