Dust Clustering in Inductively Heated Plasma Jet
POSTER
Abstract
Here we investigate the interaction between micron-sized dust particles and a low-temperature
plasma jet produced in an inductively heated plasma generator IPG6-B, located at Baylor
University. In our experiments, 20-micron-diameter aluminum oxide spheres are introduced in
the plasma jet, and their dynamics are recorded with a high-speed camera. Particle tracking
techniques are used to decompose the dust motion into drift and diffusion components, allowing
for the assessment of individual forces acting on the dust grains. The observed plasma-dust
interactions are compared against experiments where the dust is introduced in a neutral gas jet to
determine the role of plasma-driven effects. Interestingly, we observe that at low gas volume
flows, the dust particles tend to form cluster structures when plasma is present, and this effect is
enhanced by increasing plasma power. This presentation will discuss the possible physical
mechanisms driving such clustering, including charging, adhesive forces, and plasma dynamics.
plasma jet produced in an inductively heated plasma generator IPG6-B, located at Baylor
University. In our experiments, 20-micron-diameter aluminum oxide spheres are introduced in
the plasma jet, and their dynamics are recorded with a high-speed camera. Particle tracking
techniques are used to decompose the dust motion into drift and diffusion components, allowing
for the assessment of individual forces acting on the dust grains. The observed plasma-dust
interactions are compared against experiments where the dust is introduced in a neutral gas jet to
determine the role of plasma-driven effects. Interestingly, we observe that at low gas volume
flows, the dust particles tend to form cluster structures when plasma is present, and this effect is
enhanced by increasing plasma power. This presentation will discuss the possible physical
mechanisms driving such clustering, including charging, adhesive forces, and plasma dynamics.
*Work supported by US DOE under DE-SC0021338, DE-SC0021620.
Presenters
-
Evdokiya Kostadinova
- Auburn University