TY - JOUR
T1 - Process development and material property of ZnO nanoparticle suspension by high frequency induction
AU - Chang, Ho
AU - Tsung, Tsing Tshih
AU - Chen, Liang Chia
AU - Chen, Yu Cheng
AU - Lin, Hong Ming
AU - Lin, Chung Kwei
PY - 2004/7
Y1 - 2004/7
N2 - The main purpose of this study is to develop a high frequency induction process that is capable of producing the nanoparticle suspension, as well as the investigation into the properties of nanoparticle suspension. Also the effects of the process parameters, such as cooling temperature, vacuum pressure and inert gas on the rheology of nanoparticles are investigated. Experimental results indicate that under lower vacuum pressure, the nanoparticle suspension performs a larger rheological change and produces smaller nanoparticles, whereas under lower cooling temperature, it can produce finer ones. Besides, by adding inert gas during the process, the rheology of nanoparticle suspension would change. Furthermore, by adjusting the pH value of nanoparticle suspension below 7, its surface electric potential can also be increased and subsequently acquires smaller suspension particles. Besides, the nanoparticle suspension produced by this study has a good capability of absorbing UV light.
AB - The main purpose of this study is to develop a high frequency induction process that is capable of producing the nanoparticle suspension, as well as the investigation into the properties of nanoparticle suspension. Also the effects of the process parameters, such as cooling temperature, vacuum pressure and inert gas on the rheology of nanoparticles are investigated. Experimental results indicate that under lower vacuum pressure, the nanoparticle suspension performs a larger rheological change and produces smaller nanoparticles, whereas under lower cooling temperature, it can produce finer ones. Besides, by adding inert gas during the process, the rheology of nanoparticle suspension would change. Furthermore, by adjusting the pH value of nanoparticle suspension below 7, its surface electric potential can also be increased and subsequently acquires smaller suspension particles. Besides, the nanoparticle suspension produced by this study has a good capability of absorbing UV light.
KW - High frequency induction
KW - Nanoparticle suspension
KW - ZnO
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U2 - 10.1299/jsmea.47.494
DO - 10.1299/jsmea.47.494
M3 - Article
AN - SCOPUS:4744341810
VL - 47
SP - 494
EP - 501
JO - JSME International Journal, Series A: Solid Mechanics and Material Engineering
JF - JSME International Journal, Series A: Solid Mechanics and Material Engineering
SN - 1344-7912
IS - 3
ER -