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Numerical Heat Transfer, Part A: Applications
An International Journal of Computation and Methodology
Volume 67, 2015 - Issue 9
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Original Articles

Evaluating the Optical Properties of TiO2 Nanofluid for a Direct Absorption Solar Collector

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Pages 1010-1027 | Received 17 Oct 2013, Accepted 13 Aug 2014, Published online: 12 Feb 2015

REFERENCES

  • S. U. S. Choi and J. Eastman , Enhancing Thermal Conductivity of Fluids with Nanoparticles , Argonne National Lab. , Illinois , 1995 .
  • D. Peer , J. M. Karp , S. Hong , O. C. Farokhzad , R. Margalit , and R. Langer , Nanocarriers as an Emerging Platform for Cancer Therapy , Nature Nanotech. , vol. 2 , no. 12 , pp. 751 – 760 , 2007 .
  • R. A. Taylor , P. E. Phelan , T. P. Otanicar , C. A. Walker , M. Nguyen , S. Trimble , and R. Prasher , Applicability of Nanofluids in High Flux Solar Collectors , J. Renewable Sustain Energy , vol. 3 , pp. 023104 , 2011 .
  • S. K. Das , Nanofluids—the Cooling Medium of the Future , Heat Transfer Engineering , vol. 27, no. 10, pp. 1–2, 2006 .
  • E. Serrano , G. Rus , and J. García-Martínez , Nanotechnology for Sustainable Energy , Renewable Sustainable Energy Rev. , vol. 13 , no. 9 , pp. 2373 – 2384 , 2009 .
  • R. Saidur , K. Leong , and H. Mohammad , A Review on Applications and Challenges of Nanofluids , Renewable Sustainable Energy Rev. , vol. 15 , no. 3 , pp. 1646 – 1668 , 2011 .
  • D. Wen , G. Lin , S. Vafaei , and K. Zhang , Review of Nanofluids for Heat Transfer Applications , Particuology , vol. 7 , no. 2 , pp. 141 – 150 , 2009 .
  • W. Yu , D. France , S. Choi , and J. Routbort , Review and Assessment of Nanofluid Technology for Transportation and Other Applications , Argonne National Laboratory (ANL) , Argonne , IL , 2007 .
  • W. Yu , D. M. France , J. L. Routbort , and S. U. S. Choi , Review and Comparison of Nanofluid Thermal Conductivity and Heat Transfer Enhancements , Heat Transfer Eng. , vol. 29 , no. 5 , pp. 432 – 460 , 2008 .
  • S. Thomas and C. B. P. Sobhan , A Review of Experimental Investigations on Thermal Phenomena in Nanofluids, Nanoscale Res. Lett. , vol. 6, no. 1, pp. 377, 2011.
  • J. Sarkar , A Critical Review on Convective Heat Transfer Correlations of Nanofluids , Renewable Sustainable Energy Rev. , vol. 15 , no. 6 , pp. 3271 – 3277 , 2011 .
  • S. Murshed , C. Nieto de Castro , M. Lourenço , M. Lopes , and F. Santos , A Review of Boiling and Convective Heat Transfer with Nanofluids , Renewable Sustainable Energy Rev. , vol. 15 , no. 5 , pp. 2342 – 2354 , 2011 .
  • W. Daungthongsuk and S. Wongwises , A Critical Review of Convective Heat Transfer of Nanofluids , Renewable Sustainable Energy Rev. , vol. 11 , no. 5 , pp. 797 – 817 , 2007 .
  • J. Buongiorno , Convective Transport in Nanofluids , J. Heat Transfer , vol. 128 , pp. 240 , 2006 .
  • R. Taylor , Thermal Energy Conversion in Nanofluids , Arizona State University , Ph.D Thesis, 2011 .
  • T. Robert , P. Patrick , O. Todd , A. Ronald , and P. Ravi , Nanofluid Optical Property Characterization: Towards Efficient Direct Absorption Solar Collectors , Nanoscale Res. Lett. , pp. 1 – 11 , 2011 .
  • B. A. Zvirin , Y, A Novel Algorithm to Investigate Conjugate Heat Transfer in Transparent Insulation: Application to Solar Collectors , Numer. Heat Transfer: Part A: Appl. , vol. 35 , no. 7 , pp. 757 – 777 , 1999 .
  • H. Tyagi , P. Phelan , and R. Prasher , Predicted Efficiency of a Low-temperature Nanofluid-based Direct Absorption Solar Collector , J. Solar Energy Eng. , vol. 131 , no. 4 , pp. 1 – 7 , 2009 .
  • T. P. Otanicar , P. E. Phelan , and J. S. Golden , Optical Properties of Liquids for Direct Absorption Solar Thermal Energy Systems , Solar Energy , vol. 83 , no. 7 , pp. 969 – 977 , 2009 .
  • H. Tyagi , Radiative and Combustion Properties of Nanoparticles-Laden Liquid, Ph.D, Arizona State University, 2008.
  • N. Khlebtsov , L. Trachuk , and A. Mel'nikov , The Effect of the Size, Shape, and Structure of Metal Nanoparticles on the Dependence of Their Optical Properties on the Refractive Index of a Disperse Medium , Opt. Spectroscopy , vol. 98 , no. 1 , pp. 77 – 83 , 2005 .
  • C. F. Boliren and D. R. Huffman , Absorption and Scattering of Light by Small Particles , J Wiley & Sons , New York , 1983 .
  • H. C. Hulst and H. C. Van De Hulst , Light Scattering by Small Particles , Courier Dover Publications , 1957 .
  • F. Michael , Modest Radiative Heat Transfer , Academic Press , USA , 2003 .
  • M. Vollmer and U. Kreibig , Optical Properties of Metal Clusters , Springer Ser. Mat. Sci. , 1995 .
  • M. Abdelrahman , P. Fumeaux , and P. Suter , Study of Solid-Gas-Suspensions used for Direct Absorption of Concentrated Solar Radiation , Solar Energy , vol. 22 , no. 1 , pp. 45 – 48 , 1979 .
  • A. J. Hunt , Small Particle Heat Exchangers , Lawrence Berkeley National Laboratory , 2011 .
  • J. Karni , A. Kribus , R. Rubin , and P. Doron , The “Porcupine”: A Novel High-Flux Absorber for Volumetric Solar Receivers , Trans.-Am. Society Mech. Eng. J. Solar Energy Eng. , vol. 120 , pp. 85 – 95 , 1998 .
  • T. P. Otanicar , P. E. Phelan , R. S. Prasher , G. Rosengarten , and R. A. Taylor , Nanofluid-Based Direct Absorption Solar Collector , J. Renewable Sustainable Energy , vol. 2 , pp. 033102 , 2010 .
  • E. Sani , S. Barison , C. Pagura , L. Mercatelli , P. Sansoni , D. Fontani , D. Jafrancesco , and F. Francini , Carbon Nanohorns-Based Nanofluids as Direct Sunlight Absorbers , Opt. Exp. , vol. 18 , no. 5 , pp. 5179 – 5187 , 2010 .
  • R. S. Prasher and P. E. Phelan , Modeling of Radiative, and Optical Behavior of Nanofluids Based on Multiple, and Dependent Scattering Theories, ASME 2010 4th International Conference on Energy Sustainability, pp. 825–832, 2005.
  • P. Andresen , A. Bath , W. Gröger , H. Lülf , G. Meijer , and J. J. Meulen , Laser-Induced Fluorescence with Tunable Excimer Lasers as a Possible Method for Instantaneous Temperature Field Measurements at High Pressures: Checks with an Atmospheric Flame , Appl. Opt. , vol. 27 , no. 2 , pp. 365 – 378 , 1988 .
  • C. Tien , Thermal Radiation in Packed and Fluidized Beds , J. Heat Transfer , vol. 110 , pp. 1230 , 1988 .
  • A. Steinfeld and M. Schubnell , Optimum Aperture Size and Operating Temperature of a Solar Cavity-Receiver , Solar Energy , vol. 50 , no. 1 , pp. 19 – 25 , 1993 .
  • F. J. Miller , Thermal Modeling of a Small-Particle Solar Central Receiver , J. Solar Energy Eng. , vol. 122 , pp. 23 , 2000 .
  • R. Bertocchi , A. Kribus , and J. Karni , Experimentally Determined Optical Properties of a Polydisperse Carbon Black Cloud for a Solar Particle Receiver , J. Solar Energy Eng. , vol. 126 , pp. 833 , 2004 .
  • T. P. Otanicar , P. E. Phelan , R. A. Taylor , and H. Tyagi , Spatially Varying Extinction Coefficient for Direct Absorption Solar Thermal Collector Optimization , J. Solar Energy Eng. , vol. 133 , pp. 024501 , 2011 .
  • R. A. Taylor , P. E. Phelan , T. P. Otanicar , R. Adrian , and R. Prasher , Nanofluid Optical Property Characterization: Towards Efficient Direct Absorption Solar Collectors , Nanoscale Res. Lett. , vol. 6 , no. 1 , pp. 1 – 11 , 2011 .
  • H. Tyagi , Radiative and Combustion Properties of Nanoparticle-Laden Liquids , ProQuest , 2008 .
  • A. Lenert , Y. S. P. Zuniga , and E. N. Wang , Nanofluid-Based Absorbers for High Temperature Direct Solar Collectors , ASME , 2010 .
  • E. Natarajan and R. Sathish , Role of Nanofluids in Solar Water Heater , Int. J. Adv. Manuf Technol. , 2009 .
  • R. A. Taylor , P. E. Phelan , T. P. Otanicar , H. Tyagi , and S. Trimble , Applicability of Nanofluids in Concentrated Solar Energy Harvesting , ASME , 2010 .
  • E. Sani , L. Mercatelli , S. Barison , C. Pagura , F. Agresti , L. Colla , and P. Sansoni , Potential of Carbon Nanohorn-Based Suspensions for Solar Thermal Collectors , Solar Energy Mater. Solar Cells , vol. 95 , no. 11 , pp. 2994 – 3000 , 2011 .
  • R. A. Taylor , P. E. Phelan , T. Otanicar , R. J. Adrian , and R. S. Prasher , Vapor Generation in a Nanoparticle Liquid Suspension using a Focused, Continuous Laser , Appl. Phys. Lett. , vol. 95 , no. 16 , pp. 161907 – 161907–3 , 2009 .
  • Q. Zhu , Y. Cui , L. Mu , and L. Tang , Characterization of Thermal Radiative Properties of Nanofluids for Selective Absorption of Solar Radiation , Int. J. Therm. , vol. 34 , no. 12 , pp. 2307 – 2321 , 2012 .
  • A. Lenert , Nanofluid-based Receivers for High-Temperature, High-flux Direct Solar Collectors. M.Sc. Massachusetts Institute of Technology, 2010.
  • L. Mercatelli , E. Sani , G. Zaccanti , F. Martelli , D. P. Ninni , S. Barison , C. Pagura , F. Agresti , and D. Jafrancesco , Absorption and Scattering Properties of Carbon Nanohorn-Based Nanofluid for Direct Sunlight Absorbers , Nanoscale Res. Lett. , vol. 6 , no. 1 , pp. 282 , 2011 .
  • M. Chaplin , Water Absorption Spectrum. In Water Structure and Science. Retrieved 29 July 2011, http://www.lsbu.ac.uk/water/vibrat.html#uv. 2011.
  • M. Q. Brewster , Thermal Radiative Transfer and Properties , John Wiley & Sons , Canada , 1992 .
  • Z. Said , M. Sajid , R. Saidur , M. Kamalisarvestani , and N. Rahim , Radiative Properties of Nanofluids , Int. Commun. Heat Mass Transfer , vol. 46 , pp. 74 – 84 , 2013 .
  • G. M. Hale and M. R. Querry , Optical Constants of Water in the 200-nm to 200-µm Wavelength Region, Appl. Opt. , vol. 12, no. 3, pp. 555–563, 1973.
  • M. Q. Brewster and Brewster , Thermal Radiative Transfer and Properties , Wiley , New York , 1992 .
  • T. P. Otanicar , P. E. Phelan , R. S. Prasher , G. Rosengarten , and R. A. Taylor , Nanofluid-based Direct Absorption Solar Collector , J. Renewable Sustainable Energy , vol. 2 , no. 033102 , pp. 1 – 13 , 2010 .
  • R. Saidur , T. Meng , Z. Said , M. Hasanuzzaman , and A. Kamyar , Evaluation of the Effect of Nanofluid-Based Absorbers on Direct Solar Collector , Int. J. Heat Mass Transfer , vol. 55 , no. 21 , pp. 5899 – 5907 , 2012 .
  • C. F. Bohren and D. R. Huffman , Absorption and Scattering of Light by Small Particles , Wiley. com , 2008 .
  • M. F. Modest , Radiative Heat Transfer , McGraw-Hill , New York , 1993 .
  • E. D. Palik , Handbook of Optical Constants of Solids , Vol. 3 . Academic Press , 1998 .
  • Color versions of one or more of the figures in the article can be found online at www.tandfonline.com/unht.

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