Interested in particle acceleration and energy transport in laboratory and space plasmas.

Study how supersonically moving charged objects generate precursor solitons.

Study how magnetic fields, source geometry, alignment, charge, and electron–ion temperature ratios affect soliton dynamics.

Apply these studies to both space and laboratory plasmas, with potential applications in debris detection and mitigation.

Simulate and control the fall of charged dust particles, applying the results to minimize particulate contamination in processes such as semiconductor manufacturing.

Study collective dynamics, viscoelastic effects, and transverse shear waves in dusty plasmas.

Interested in sculpted ultracold neutral plasmas to study nonlinear waves, transport phenomena, and strong Coulomb coupling.

Interested in molecular dynamics studies of defects, dislocations, and microstructural evolution in solids under extreme conditions.

Interested in simulating laser-produced plasmas and beam–plasma interactions to study heating, shocks, and wave excitation.