Tailoring nanomaterial products through electrode material and oxygen partial pressure in a mini-arc plasma reactor
Nanomaterials with controllable morphology and composition are synthesized by a simple one-step vapor condensation process using a mini-arc plasma source. Through systematic investigation of mini-arc reactor parameters, the roles of carrier gas, electrode material, and precursor on producing diverse nanomaterial products are revealed. Desired nanomaterial products, including tungsten oxide nanoparticles (NPs), tungsten oxide nanorods (NRs), tungsten oxide and tin oxide NP mixtures and pure tin dioxide NPs can thus be obtained by tailoring reaction conditions. The amount of oxygen in the reactor is critical to determining the final nanomaterial product. Without any precursor material present, a lower level of oxygen in the reactor favors the production of W18O49 NRs with tungsten as cathode, while a high level of oxygen produces more round WO3 NPs. With the presence of a precursor material, amorphous particles are favored with a high ratio of argon:oxygen. Oxygen is also found to affect tin oxide crystallization from its amorphous phase in the thermal annealing. Results from this study can be used for guiding gas phase nanomaterial synthesis in the future.
KeywordsNanoparticle Nanorod Mini-arc plasma Oxygen partial pressure Gas phase
- Mahoney W, Andres RP (1995) Aerosol synthesis of nanoscale clusters using atmospheric arc evaporation. Mater Sci Eng A 204(1–2):160–164Google Scholar
- Rella R, Spadavecchia J, Manera MG, Capone S, Taurino A, Martino M, Caricato AP, Tunno T (2007) Acetone and ethanol solid-state gas sensors based on TiO2 nanoparticles thin film deposited by matrix assisted pulsed laser evaporation. Sens Actuators B 127(2):426–431. doi:10.1016/j.snb.2007.04.048 CrossRefGoogle Scholar