Abstract
We report the controlled injection of near-isolated micron-sized liquid droplets into a low temperature He-Ne steady-state rf plasma at atmospheric pressure. The H2O droplet stream is constrained within a 2 mm diameter quartz tube. Imaging at the tube exit indicates a log-normal droplet size distribution with an initial count mean diameter of 15 μm falling to 13 μm with plasma exposure. The radial velocity profile is approximately parabolic indicating near laminar flow conditions with the majority of droplets travelling at >75% of the local gas speed and having a plasma transit time of <100 μs. The maximum gas temperature, determined from nitrogen spectral lines, was below 400 K and the observed droplet size reduction implies additional factors beyond standard evaporation, including charge and surface chemistry effects. The demonstration of controlled microdroplet streams opens up possibilities for gas-phase microreactors and remote delivery of active species for plasma medicine.
Original language | English |
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Article number | 224101 |
Number of pages | 4 |
Journal | Applied Physics Letters |
Volume | 106 |
Issue number | 22 |
DOIs | |
Publication status | Published - 1 Jun 2015 |
Keywords
- electron density
- stellar structure and properties
- probability theory
- leptons
- chemical elements
- aerosols
- gas phase
- surface and interface chemistry
- plasmas
- laminar flows