Numerical simulations on the formation of laser speckles with nanofluids

Optics and Lasers in Engineering

Volumn 46, Issue 6, 2008, Pages 461-468

  Qian, Ming ^a   Shen, Zhonghua ^a   Lu, Jian ^a   Ni, Xiaowu ^a   Li, Qiang ^a   Xuan, Yimin ^a  

^a NANJING UNIVERSITY OF SCIENCE AND TECHNOLOGY   (China)

Author keywords

Laser speckle velocimetry; Nanofluids; Nanoparticle; Numerical simulation; Speckle

Indexed keywords

COMPUTER SIMULATION; ELECTRIC DIPOLE MOMENTS; LASER OPTICS; MONTE CARLO METHODS; NANOFLUIDICS; NANOPARTICLES;

ELECTRIC-DIPOLE MODEL; LASER SPECKLE VELOCIMETRY; PHOTON-NANOPARTICLE-COLLISION MODEL;

SPECKLE;

EID: 41149139663     PISSN: 01438166     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.optlaseng.2008.01.003     Document Type: Article

References (17)

1. Qian M., Liu J., Yan M.-S., Shen Z.-H., Lu J., Ni X.-W., et al. Investigation on utilizing laser speckle velocimetry to measure the velocities of nanoparticles in nanofluids. Opt Express 14 (2006) 7559-7566
2. Choi U.S. Enhancing thermal conductivity of fluids with nanoparticles. ASME FED 231 (1995) 99-103
3. Eastman J.A., Choi S.U.S., Li S., Yu W., and Thompson L.J. Anomalous increased effective thermal conductivities of ethylene glycol-based nanofluids containing copper nanoparticles. Appl Phys Lett 78 (2001) 718
4. Choi S.U.S., Zhang Z.G., Yu W., Lockwood F.E., and Grulke E.A. Anomalous thermal conductivity enhancement in nanotubes suspensions. Appl Phys Lett 79 (2001) 2252
5. Das S.K., Putra N., Thiesen P., and Roetzel W. Temperature dependence of thermal conductivity enhancement for nanofluids. J Heat Transfer 125 (2003) 567-574
6. Kumar D.H., Patel H.E., Kumar V.R.R., Sundarajan T., Pradeep T., and Das S.K. Model for heat conduction in nanofluids. Phys Rev Lett 93 (2004) 144301
7. Wang B.X., Zhou L.P., and Peng X.P. A fractal model for predicting the effective thermal conductivity of liquid with suspension of nanoparticles. Int J Heat Mass Transfer 46 (2003) 2665
8. Xue Q.-Z. Model for effective thermal conductivity of nanofluids. Phys Lett A 307 (2003) 313
9. Xue L., Keblinski P., Phillpot S.R., Choi S.U.S., and Eastman J.A. Effect of liquid layering at the liquid-solid interface on thermal transport. Int J Heat Mass Transfer 47 (2004) 4277
10. Jang S.P., and Choi S.U.S. Role of Brownian motion in the enhanced thermal conductivity of nanofluids. Appl Phys Lett 84 (2004) 4316-4318
11. Koo J., and Kleinstreuer C. A new thermal conductivity model for nanofluids. J Nanopart Res 6 (2004) 577
12. Prasher R., Bhattacharya P., and Phelan P.E. Thermal conductivity of nanoscale colloidal solutions (nanofluids). Phys Rev Lett 94 (2005) 025901
13. Prasher R., Bhattacharya P., and Phelan P.E. Brownian-motion-based convective-conductive model for the effective thermal conductivity of nanofluids. J Heat Transfer 128 (2006) 588-595
14. Xuan Y., and Li Q. Stochastic thermal transport of nanoparticle suspensions. J Appl Phys 100 (2006) 043507
15. 3) thermal conductivity enhancement. Appl Phys Lett 87 (2005) 153107
16. Chon C.H., and Kihm K.D. Thermal conductivity enhancement of nanofluids by Brownian motion. J Heat Transfer 127 (2005) 810
17. Robert S., and Erf K. Speckle metrology (1978), Academic Press, New York