Application of the modulated temperature differential scanning calorimetry technique for the determination of the specific heat of copper nanofluids

Applied Thermal Engineering

Volumn 41, Issue , 2012, Pages 10-17

  De Robertis, E ^a   Cosme, E H H ^a   Neves, R S ^a   Kuznetsov, A Yu ^a   Campos, A P C ^a   Landi, S M ^a   Achete, C A ^a,b  

^a INSTITUTO NACIONAL DE METROLOGIA   (Brazil)

^b FEDERAL UNIVERSITY OF RIO DE JANEIRO   (Brazil)

Author keywords

Copper nanofluid; Modulated temperature differential scanning calorimetry; Specific heat capacity

Indexed keywords

CHEMICAL NATURE; COPPER NANOPARTICLES; MELTING PROCESS; MODULATED TEMPERATURE DIFFERENTIAL SCANNING CALORIMETRY; NANO-FLUID; NANOFLUIDS; ONE-STEP METHODS; STANDARD PROCEDURES; TEMPERATURE RANGE; THERMALLY STABLE;

COPPER; SPECIFIC HEAT; SYNTHESIS (CHEMICAL); TRANSMISSION ELECTRON MICROSCOPY; X RAY DIFFRACTION;

NANOFLUIDICS;

EID: 84860445916     PISSN: 13594311     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.applthermaleng.2012.01.003     Document Type: Conference Paper

References (49)

1. D. Wen, G. Lin, S. Vafaei, and K. Zhang Review of nanofluids for heat transfer applications Particuology 7 2009 141 150
2. 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. 29 2008 432 460
3. K.S. Gandhi Thermal properties of nanofluids: controversy in the making? Curr. Sci. 92 2007 717 718
4. S.M.S. Murshed, K.C. Leong, and C. Yang Thermophysical and electrokinetic properties of nanofluids - a critical review Appl. Therm. Eng. 28 2008 2109 2125
5. S.U.S. Choi Enhancing thermal conductivity of fluids with nanoparticles D.A. Siginer, H.P. Wang, Developments and Applications of Non-Newtonian Flows FED-vol. 231/MD-vol. 66 1995 ASME New York 99 105
6. X.-Q. Wang, and A.S. Mujumdar Heat transfer characteristics of nanofluids: a review Int. J. Therm. Sci. 46 2007 1 19
7. V. Trisaksri, and S. Wongwises Critical review of heat transfer characteristics of nanofluids Renew. Sustain. Energy Rev. 11 2007 512 523
8. L. Cheng, E.P. Bandarra Filho, and J.R. Thome Nanofluid two-phase flow and thermal physics: a new research frontier of nanotechnology and its challenges J. Nanosci. Nanotechnol. 8 2008 1 18
9. S. Özerinç, S. Kakaç, and A.G. Yazcoglu Enhanced thermal conductivity of nanofluids: a state-of-the-art review Microfluid. Nanofluid. 8 2010 145 170
10. G. Paul, M. Chopkar, I. Manna, and P.K. Das Techniques for measuring the thermal conductivity of nanofluids: a review Renew. Sustain. Energy Rev. 14 2010 1913 1924
11. L. Wang, and J. Fan Nanofluids research: key issues Nanoscale Res. Lett. 5 2010 1241 1252
12. R. Saidur, S.N. Kazi, M.S. Hossain, M.M. Rahman, and H.A. Mohamme A review on the performance of nanoparticles suspended with refrigerants and lubricating oils in refrigeration systems Renew. Sustain. Energy Rev. 15 2011 310 323
13. K.V. Wong, and M.J. Castillo Heat transfer mechanisms and clustering in nanofluids Adv. Mech. Eng. 2010 2010 9 Article ID 795478
14. K.V. Wong, and O. De Leon Applications of nanofluids: current and future Adv. Mech. Eng. 2010 2010 11 Article ID 519659
15. J. Fan, and L. Wang Is classical energy equation adequate for convective heat transfer in nanofluids? Adv. Mech. Eng. 2010 2010 5 Article ID 719406
16. 3/DI water nanoparticle suspensions (nanofluids) Adv. Mech. Eng. 2010 2010 10 Article ID 742739
17. 3 nanofluid turbulent convection Adv. Mech. Eng. 2010 2010 10 Article ID 976254
18. R. Gowda, H. Sun, P. Wang, M. Charmchi, F. Gao, Z. Gu, and B. Budhlall Effects of particle surface charge, species, concentration, and dispersion method on the thermal conductivity of nanofluids Adv. Mech. Eng. 2010 2010 10 Article ID 807610
19. Y. Xuan, Y. Huang, and Q. Li Experimental investigation on thermal conductivity and specific heat capacity of magnetic microencapsulated phase change material suspension Chem. Phys. Lett. 479 2009 264 269
20. 3 nanofluid Appl. Phys. Lett. 92 2008 093123
21. L.-P. Zhou, B.-X. Wang, X.-F. Peng, X.-Z. Du, and Y.-P. Yang On the specific heat capacity of CuO nanofluid Adv. Mech. Eng. 2010 2010 4 Article ID 172085
22. I.C. Nelson, D. Banerjee, and R. Ponnappan Flow loop experiments using polyalphaolefin nanofluids J. Thermophys. Heat Transfer 23 2009 752 761
23. D. Shin, and D. Banerjee Enhancement of specific heat capacity of high-temperature silica-nanofluids synthesized in alkali chloride salt eutectics for solar thermal-energy storage applications Int. J. Heat Mass Transfer 54 2011 1064 1070
24. D. Shin, and D. Banerjee Enhanced specific heat of silica nanofluid J. Heat Transfer 133 2011 4 Article ID 024501
25. ASTM Standard E1269, standard test method for determining specific heat capacity by differential scanning calorimetry West Conshohocken, PA ASTM Int. 2005 10.1520/E1269-05
26. S.L. Simon Temperature-modulated differential scanning calorimetry: theory and application Thermochim. Acta 374 2001 55 71
27. E. Verdonck, K. Schaap, and L.C. Thomas A discussion of the principles and applications of modulated temperature DSC (MTDSC) Int. J. Pharm. 192 1999 3 20
28. V.L. Hill, D.Q.M. Craig, and L.C. Feely The effects of experimental parameters and calibration on MTDSC data Int. J. Pharm. 192 1999 21 32
29. ASTM Standard E2716, standard test method for determining specific heat capacity by sinusoidal modulated temperature differential scanning calorimetry West Conshohocken, PA ASTM Int. 2005 10.1520/E2716-09
30. A.A. Coelho TOPAS-Academic Users Manual 2005 http://members.optusnet.com. au/∼alancoelho/gt
31. G.O. Mallory, and J.B. Hajdu Electroless Plating: Fundamentals & Applications 1990 AESF Orlando
32. J.I. Langford, and A.J.C. Wilson Scherrer after sixty years: a survey and some new results in the determination of crystallite size J. Appl. Crystallogr. 11 1978 102 113
33. A.R. Stokes, and A.J.C. Wilson A method of calculating the integral breadths of Debye-Scherrer lines Math. Proc. Cambridge Philos. Soc. 38 1942 313 322
34. B.E. Warren X-ray Diffraction 1990 Dover Publications New York
35. E.F. Bertaut Raies De Debye-Scherrer et Repartition des Dimensions des Domaines de Bragg dans les Poudres Polycristallines Acta Crystallogr. 3 1950 14 18
36. J.I. Langford, D. Louer, and P. Scardi Effect of a crystallite size distribution on X-ray diffraction line profiles and whole-powder-pattern fitting J. Appl. Crystallogr. 33 2000 964 974
37. D. Balzar Voigt function model in diffraction-line broadening analysis R.L. Snyder, J. Fiala, H.J. Bunge, Defect and Microstructure Analysis by Diffraction 1999 IUCr/Oxford University Press 94 126
38. http://webbook.nist.gov/cgi/cbook.cgi?ID=C7440508&Units=SI&Mask= 2#Thermo-Condensed (last accessed 10.04.11).
39. R.E. Newnham Properties of Materials 2005 Oxford University Press
40. N.W. Ashcroft, and N.D. Mermin Solid State Physics 1976 W. B. Saunders Company Philadelphia
41. (last accessed 10.04.11).
42. V. Velagapudi, R.K. Konijeti, and C.S.K. Aduru Empirical correlations to predict thermophysical and heat transfer characteristics of nanofluids Therm. Sci. 12 2008 27 37
43. B.-X. Wang, L.-P. Zhou, and X.-F. Peng Surface and size effects on the specific heat capacity of nanoparticles Int. J. Thermophys. 27 2006 139 151
44. E.V. Timofeeva, D.S. Smith, W. Yu, D.M. France, D. Singh, and J.L. Routbort Particle size and interfacial effects on thermo-physical and heat transfer characteristics of water-based α-SiC nanofluids Nanotechnology 21 2010 10 Article ID 215703
45. D. Lee, J.-W. Kim, and B.G. Kim A new parameter to control heat transport in nanofluids: surface charge state of the particle suspension J. Phys. Chem. B 110 2006 4323 4328
46. X.-J. Wang, D.-S. Zhu, and S. Yang Investigation of pH and SDBS on enhancement of thermal conductivity in nanofluids Chem. Phys. Lett. 470 2009 107 111
47. X.-J. Wang, and X.-F. Li Influence of pH on nanofluids' viscosity and thermal conductivity Chin. Phys. Lett. 26 4 2009 056601
48. (last accessed 10.04.11).
49. W.J. Parker, R.J. Jenkins, C.P. Butler, and G.L. Abbott Flash method of determining thermal diffusivity, heat capacity and thermal conductivity J. Appl. Phys. 32 1961 1679 1684