Effect of Surface Hydration and Interfusion of Suspended Silica Nanoparticles on Heat Transfer

ABOUT | COURSES | EVENTS | PUBLICATIONS | LEADERSHIP | OUTREACH | NEWS | PRESS | JOBS |

Nanotechnology Solutions

Nanotech 2008 CDROM

Nanotech 2007 CDROM

Nanotech 2006 CDROM

Nanotech 2005 CDROM

Nanotech 2004 CDROM

3 CDROM Special Offer

Nanotech 2008 Vol. 1

Nanotech 2008 Vol. 2

Nanotech 2008 Vol. 3

Nanotech 2007 Vol. 1

Nanotech 2007 Vol. 2

Nanotech 2007 Vol. 3

Nanotech 2007 Vol. 4

Nanotech 2006 Vol. 1

Nanotech 2006 Vol. 2

Nanotech 2006 Vol. 3

Nanotech 2005 Vol. 1

Nanotech 2005 Vol. 2

Nanotech 2005 Vol. 3

Nanotech 2004 Vol. 1

Nanotech 2004 Vol. 2

Nanotech 2004 Vol. 3

Nanotech 2003 Vol. 1

Nanotech 2003 Vol. 2

Nanotech 2003 Vol. 3

Nanotech 2002 Vol. 1

Nanotech 2002 Vol. 2

Nanotech 2001 Vol. 1

Nanotech 2001 Vol. 2

Index of Authors

Index of Keywords

Index of Affiliations

Library Request Form

Publications
Nanotech 2006 Vol. 2

	Nanotech 2006 Vol. 2 Technical Proceedings of the 2006 NSTI Nanotechnology Conference and Trade Show, Volume 2 Chapter 9: Soft Nanotechnology
	Effect of Surface Hydration and Interfusion of Suspended Silica Nanoparticles on Heat Transfer
Authors:	D. Milanova, X. Wu and R. Kumar
Affilation:	University of Central Florida, US
Pages:	690 - 693
Keywords:	nanofluid, silica, hydration, heat transfer, critical heat flux
Abstract:	Nanofluid suspensions enhance thermal conductivity and the heat transfer. The authors have previously shown that the Critical Heat Flux (CHF) of NiChrome wire in a silica nanofluid can be increased by 200% compared to conventional fluids. Particle size, concentration and chemistry play a major role in improving the heat transfer characteristics and the critical heat flux. In this paper, we will report the effect of surface chemistry of amorphous silica, the process of surface hydration and interfusion of two particles in determining the CHF enhancement. CHF is seen to increase as the concentration is increased to 0.5%, then decrease at 1% before increasing again at 2%. The reasons are attributed to an increase in the effective diameter which stays a constant after 0.5% concentration. Beyond this concentration, the number density of the particles increases. This unreported event is strongly correlated to surface chemistry. One of the factors for the discharging of nanoparticles is the dehydration due to particle’s surface shape and structure. At 0.2%, the particle has positive radius of curvature due to strong dispersion, while at 0.5%, the agglomeration results in negative curvature. Interaction between SiOH groups leads to dehydration, i.e., the formation of water molecules around the surface with negative radius of curvature. This process is accompanied by discharging of those sites and formation of immobilized water layer surrounding the uncharged SiOH surface.
ISBN:	0-9767985-7-3
Pages:	893
Hardcopy:	$185.00

Order:	Mail/Fax Form
Special:	3 CD Set — 15% off with Free Shipping
Up

Upcoming Events

nanoPRwire™

News Headlines

Breaking News

Nanotech Week

© Nano Science and Technology Institute About NSTI | Terms of Use | Privacy Policy | Contact