%0 Journal Article
%A Soochan Lee
%A Patrick E Phelan
%A Lenore Dai
%A Ravi S Prasher
%A Andrey Gunawan
%A Robert A Taylor
%B Applied Physics Letters
%D 2014
%G eng
%I American Institute of Physics
%P 151908
%R 10.1063/1.4872176
%T Experimental investigation of the latent heat of vaporization in aqueous nanofluids
%V 104
%8 04/2014
%X <p><span>This paper reports an experimental investigation of the&nbsp;</span>latent heat<span>&nbsp;of&nbsp;</span>vaporization<span>&nbsp;(h</span><span>fg</span><span>) in nanofluids. Two different types of&nbsp;</span>nanoparticles,<span>&nbsp;</span>graphite<span>&nbsp;and&nbsp;</span>silver,<span>&nbsp;suspended in deionized water were exposed to a continuous laser beam (130 mW, 532&thinsp;nm) to generate boiling. The&nbsp;</span>latent heat<span>&nbsp;of&nbsp;</span>vaporization<span>&nbsp;in the nanofluids was determined by the measured vapor mass generation and the heat input. To ensure that the measured h</span><span>fg</span><span>&nbsp;values are independent of&nbsp;</span>heating<span>&nbsp;method, the experiments were repeated with an electrically heated hot wire as a primary heat input. These experiments show considerable variation in the h</span><span>fg</span><span>&nbsp;of nanofluids. That is,&nbsp;</span>graphite<span>&nbsp;nanofluid exhibits an increased h</span><span>fg</span><span>&nbsp;and&nbsp;</span>silver<span>&nbsp;nanofluid shows a decrease in h</span><span>fg</span><span>&nbsp;compared to the value for pure water. As such, these results indicate that relatively low mass fractions of&nbsp;</span>nanoparticles<span>&nbsp;can apparently create large changes in h</span><span>fg</span><span>.</span></p>