Environmental Engineering Reference
In-Depth Information
113. Wang XW, Xu XF, Choi SUS (1999) Thermal conductivity of nanoparticle-fluid mixture.
J Thermophys Heat Transf 13(4):474
-
480
114. Li CH, Peterson GP (2006) Experimental investigation of temperature and volume fraction
variations on the effective thermal conductivity of nanoparticle suspensions (nanofluids).
J Appl Phys 99(8):084314
115. Zhu D, Li X, Wang N et al
(2009) Dispersion behavior and thermal conductivity
139
116. Jang SP, Choi SUS (2004) Role of Brownian motion in the enhanced thermal conductivity of
nano
characteristics of Al
2
O
3
-H
2
O nano
fl
uids. Curr Appl Phys 9:131
-
4318
117. Timofeeva EV, Gavrilov AN, McCloskey JM et al (2007) Thermal conductivity and particle
agglomeration in alumina nano
fl
uids. Appl Phys Lett 84:4316
-
uids: experiment and theory. Phys Rev E 76:061203
118. Timofeeva EV, Smith DS, Yu W et al (2010) Particle size and interfacial effects on thermo-
physical
fl
and
heat
transfer
characteristics
of water-based
alpha-SiC nano
fl
uids.
Nanotechnology 21:215703
119. Murshed SMS, Leong KC, Yang C (2005) Enhanced thermal conductivity of TiO
2
-water
based nanofluids. Int J Therm Sci 44:367
-
373
120. Lee S, Choi SUS, Li S et al (1999) Measuring thermal conductivity of fluids containing oxide
nanoparticles. J Heat Transf 121:280
-
289
121. Keblinski P, Phillpot SR, Choi SUS et al (2002) Mechanisms of heat flow in suspensions of
nanos-sized particles (nanofluids). Int J Heat Mass Transf 45:855
-
863
122. Jang SP, Choi SUS (2007) Effects of various parameters on nanofluid thermal conductivity.
J Heat Transf 129:617
-
623
123. Kleinstreuer C, Li J (2008) Discussion: effects of various parameters on nano
fl
uid thermal
conductivity. J Heat Transf 130:025501
124. Prasher
(2006) Brownian-motion-based convective-conductive model
for
the effective
thermal conductivity of nano
fl
uids. J Heat Transf 128:588
595
-
125. Li J (2008) Computational analysis of nano
ow in microchannels with applications to
micro-heat sinks and bio-MEMS. PhD thesis, North Carolina State University
126. Kumar DH, Patel HE, Kumar VRR et al (2004) Model for heat conduction in nano
fl
uid
fl
fl
uids.
Phys Rev Lett 93:144301
127. Koo J, Kleinstreuer C (2004) A new thermal conductivity model for nano
fl
uids. J Nanopart
588
128. Bao Y (2008) Thermal conductivity equations based on Brownian motion in suspensions of
nanoparticles (nanofluids). J Heat Transf 130:042408
129. Feng Y, Kleinstreuer C (2010) Nanofluid convective heat transfer in a parallel disk system.
Int J Heat Mass Transf 53:4619
-
4628
130. Blums E (2002) Heat and mass transfer phenomena. In: Odenbach S (ed) Ferrofluids:
magnetically controllable fluids and their applications, vol 594. Lecture notes in physics.
Springer, Berlin
131. Li Q, Xuan Y, Wang J (2005) Experimental
Res 6:577
-
investigations on transport properties of
116
132. Krichler M, Odenbach S (2013) Thermal conductivity measurements on ferro
magnetic
fl
uids. Exp Therm Fluid Sci 30:109
-
fl
uids with
90
133. Philip J, Shima P, Raj B (2008) Evidence for enhanced thermal conduction through
percolating structures in nano
special reference to measuring arrangement. J Magn Magn Mater 326:85
-
uids. Nanotechnology 19:305706
134. Philip J, Shima P, Raj B (2007) Enhancement of thermal conductivity in magnetite based
nano
fl
uid due to chainlike structures. Appl Phys Lett 91:203108
135. Wright B, Thomas D, Hong H et al (2007) Magnetic
eld enhanced thermal conductivity in
heat transfer nano
fl
fl
uids containing Ni coated single wall carbon nanotubes. Appl Phys Lett
91:173116
136. Wensel J, Wright B, Thomas D et al (2008) Enhanced thermal conductivity by aggregation in
heat transfer nanofluids containing metal oxide nanoparticles and carbon nanotubes. Appl
Phys Lett 92:023110
Search WWH ::
Custom Search