Kinetic Simulations of the Dissipation Range of Solar Wind Turbulence from Ion to Electron Scales

Gregory Howes; Jason TenBarge; Steven Cowley; William Dorland; Eliot Quataert; Alexander Schekochihin; Ryusuke Numata; Tomoya Tatsuno

Kinetic Simulations of the Dissipation Range of Solar Wind Turbulence from Ion to Electron Scales

POSTER

Abstract

The first nonlinear kinetic simulation of the dissipation range of plasma turbulence resolving both the characteristic ion and electron scales with a realistic mass ratio is presented. The resulting energy spectra are qualitatively consistent with nearly power-law spectra observed in recent satellite measurements of the solar wind dissipation range. This result demonstrates that a kinetic Alfven wave cascade can reach the electron scales and disproves a recent claim to the contrary. A weakened cascade model for the kinetic turbulent cascade is presented that explains the spectra by accounting for nonlocal contributions to the energy cascade rate.

Authors

Gregory Howes
- University of Iowa
Jason TenBarge
- University of Iowa
Steven Cowley
- Euratom/CCFE Fusion Association, Culham Science Centre, Abingdon, UK
- Imperial College
- EURATOM/CCFE Association, Culham
William Dorland
- University of Maryland, College Park
- University of Maryland
Eliot Quataert
- UC Berkeley
- University of California, Berkeley
Alexander Schekochihin
- Rudolf Peierls Centre for Theoretical Physics, University of Oxford, Oxford, UK
- University of Oxford
- Univ. Oxford
- Oxford University
Ryusuke Numata
- University of Maryland
Tomoya Tatsuno
- University of Maryland, College Park
- University of Maryland