COOLING BY DUST IN LEVITATION EXPERIMENTS AND ITS EFFECT ON DUST CLOUD EQUILIBRIUM PROFILES

The thermophoretic force on dust particles is caused by a temperature gradient in the background gas. This force can be important in experim ents or production processes and in other environments where dust occu rs. We discuss the local cooling of the neutral gas by levitated dust clouds and how this affects the temperature gradient and the equilibri um dust density profile. Dust is heated through neutral gas particle i mpacts while it loses energy by either reemitting impacting particles or by thermal radiation at the particle temperature. The dust particle temperature can be considerably lower than that of the ambient gas an d can therefore lead to a local cooling of the gas. Changes in the tem perature gradient and the thermophoretic force can be large enough to affect the equilibrium density profile of levitated dust. We find that the equilibrium profile with the thermophoretic force calculated from the temperature profile without dust cooling is closer to the electro de but with much the same shape as the profile calculated without the thermophoretic force. The profile where local cooling is included in t he thermophoretic force is more compressed compared to the profile wit hout local cooling and it often has a pronounced peak closest to the e lectrode. Since radiation cooling of a dust particle is proportional t o the fourth power of its temperature, the cooling effect is largest a t comparatively high gas (and dust) temperatures. We show examples of levitated dust layer profiles with and without the dust cooling effect . (C) 1996 American Vacuum Society.