Open Access Open Access  Restricted Access Subscription Access

Physico-Chemical Study on Heat Transfer Property of Iron Oxide Nanofluid


Affiliations
1 Department of Physics, Veer Surendra Sai University of Technology, Burla Sambalpur, Odisha 768018, India
 

The analytical characterization of thermophysical properties of metal oxide nanofluid has got significant attention in thermal industries due to their high capability of reducing energy loss and enhancing the efficiency of machinery parts. The fascinating heat transfer characteristics of green modulated iron oxide nanoparticles (IONPs) attain significant importance due to their wide range of diverse applications in different industries. In the current study, IONPs were successfully synthesized using an aqueous extract of Aloe vera (Aloe barbadensis) leaves to evaluate its effective thermophysical properties in base fluid like water. The average particle size of 11nm IONPs with its nanofluid of various volume concentrations 0.01 to 0.05 with a different temperature range of 30 °C to 50 °C shows an enhancement in thermal conductivity of 34.08% compared to distilled water (base fluid). Different characterization technique like Scanning electron microscopy (SEM), X-ray diffraction (XRD), Fourier transforms infrared (FTIR) spectroscopy, UV-visible spectroscopy, and particle size analyzer has been employed to get characteristic modification and formation of iron oxide nanoparticles. The experimentally measured values of thermal conductivity were compared with existing theoretical models for effective enhancement in thermophysical properties and the same was analyzed with the importance of green technique.

Keywords

Green Synthesis, Iron Oxide Nanofluids, Thermal Conductivity, Viscosity, Density.
User
Notifications
Font Size

  • Barai D P, Bhanvase B A & Saharan V K, Ind Eng Chem Res, 58 (2019) 8349.
  • Chougule S S & Sahu S K, J Nanotechnol Eng Med, 5 (2014) 010901.
  • Chaurasia P, Kumar A, Yadav A, Rai P K, Kumar V & Prasad L, SN Appl Sci, 1 (2019) 1.
  • Tembhare S P, Barai D P & Bhanvase B A, Renew Sust Energ Rev, 153 (2022) 111738.
  • Ajayi O O, Ukasoanya D E, Ogbonnaya M, Salawu E Y, Okokpujie I P, Akinlabi S A, Akinlabi E T & Owoeye F T, Procedia Manuf, 35 (2019) 112.
  • Sheikholeslami M, Rezaeianjouybari B, Darzi M, Shafee A, Li Z & Nguyen TK, Int J Heat Mass Transf, 141 (2019) 974.
  • Singh J, Dutta T & Kim K H, J Nanobiotechnol, 16 (2018) 1.
  • Kumar L H, Kazi S N, Masjuki H H & Zubir M N M, Chem Eng J, 429 (2022) 132321.
  • Sundar L S, Singh M K & Sousa A, Int Commun Heat Mass Transf, 44 (2013) 7.
  • Medda S, Hajra A & Dey U, Appl Nanosci, 5 (2015) 875.
  • Sa J & Nath G, Adv Nat Sci: Nanosci Nanotechnol, 13 (2022) 025011.
  • Sa J & Nath G, Mater Today: Proc, 62 (2022) 5877.
  • Yew Y P, Shameli K & Miyake M, Nanoscale Res Lett, 11 (2016) 1.
  • Maxwell J C, 2nd Edn, A treatise on electricity and magnetism, Clarendon Press, Oxford, 1881.
  • Hamilton R L & Crosser O K, Ind Eng Chem, 1 (1962) 187.
  • Mahdavi M, Namvar F, Ahmad M B & Mohamad R, Molecules, 18 (2013) 5954.
  • Demir A, Topkaya R & Baykal A, Polyhedron, 65 (2013) 282.
  • Basavegowda N, Magar K B S, Mishra K & Lee Y R, New J Chem, 38 (2014) 5415.
  • Niraimathee V A, Subha V & Ramaswami S E R, Int J Env Sustain Dev, 15 (2016) 1.
  • Hussein A M, Sharma K V, Bakar R A & Kadirgama K, J Nanomater, 2013 (2013) 1.
  • Sadri R, Ahmadi G, Togun H, Dahari M, Kazi S N, Sadeghinezhad E & Zubir N, Nanoscale Res Lett, 9 (2014) 1.
  • Gao D, Bai M, Hu C, Lv J, Wang C & Zhang X, Nanotechnol, 31 (2020) 495402.
  • Hemmat E M, Yan W M, Akbari M, Karimipour A & Hassani M, Int Commun Heat Mass Transf, 68 (2015) 248.
  • Chon C H, Kihm K D, Lee S P & Choi S U S, Appl Phy Lett, 87 (2005) 153107.
  • Nichols G, Byard S, Bloxham M J, Botterill J, Dawson N J, Dennis A, Diart V, North N C & Sherwood J D, J Pharm Sci, 91 (2002) 2103.
  • Teleki A, Wengeler R, Wengeler L, Nirschl H & Pratsinis S, Powder Technol, 181 (2008) 292.
  • Ghadimi A & Metselaar I H, Exp Therm Fluid Sci, 51 (2013) 1.
  • Barai D, Bhanvase B & Żyła G, Nanomater, 12 (2022) 1.
  • Sonawane S S, Khedkar R S & Wasewar K L, J Exp Nanosci, 10 (2015) 310.
  • Sa J & Nath G, J Sci Ind Res, 81 (2022) 671.
  • Malik P, Shankar R, Malik V, Sharma N & Mukherjee T K, J Nanoparticles, 2014 (2014) 1.
  • Dwivedi A D & Gopal K, Colloids Surf A: Physicochem Eng Asp, 369 (2010) 27.
  • Rostamian S H, Biglari M, Saedodin S & Esfe MH, J Mol Liq, C (2017) 364.
  • Xuan Y & Li Q, Int J Heat Fluid Flow, 21 (2000) 58.

Abstract Views: 130

PDF Views: 91




  • Physico-Chemical Study on Heat Transfer Property of Iron Oxide Nanofluid

Abstract Views: 130  |  PDF Views: 91

Authors

Jayashree Sa
Department of Physics, Veer Surendra Sai University of Technology, Burla Sambalpur, Odisha 768018, India
Ganeswar Nath
Department of Physics, Veer Surendra Sai University of Technology, Burla Sambalpur, Odisha 768018, India

Abstract


The analytical characterization of thermophysical properties of metal oxide nanofluid has got significant attention in thermal industries due to their high capability of reducing energy loss and enhancing the efficiency of machinery parts. The fascinating heat transfer characteristics of green modulated iron oxide nanoparticles (IONPs) attain significant importance due to their wide range of diverse applications in different industries. In the current study, IONPs were successfully synthesized using an aqueous extract of Aloe vera (Aloe barbadensis) leaves to evaluate its effective thermophysical properties in base fluid like water. The average particle size of 11nm IONPs with its nanofluid of various volume concentrations 0.01 to 0.05 with a different temperature range of 30 °C to 50 °C shows an enhancement in thermal conductivity of 34.08% compared to distilled water (base fluid). Different characterization technique like Scanning electron microscopy (SEM), X-ray diffraction (XRD), Fourier transforms infrared (FTIR) spectroscopy, UV-visible spectroscopy, and particle size analyzer has been employed to get characteristic modification and formation of iron oxide nanoparticles. The experimentally measured values of thermal conductivity were compared with existing theoretical models for effective enhancement in thermophysical properties and the same was analyzed with the importance of green technique.

Keywords


Green Synthesis, Iron Oxide Nanofluids, Thermal Conductivity, Viscosity, Density.

References