1 |
Experimental study on the influence of alternating working conditions on the physical properties and stability of ammonia-water nanofluid applied in the practical system Song JW, Jiang WX, Qian H, Du K Powder Technology, 369, 311, 2020 |
2 |
Application of TiO2 nanofluid-based coolant for jet impingement quenching of a hot steel plate Sarkar I, Chakraborty S, Roshan A, Behera DK, Pal SK, Chakraborty S Experimental Heat Transfer, 32(4), 322, 2019 |
3 |
Experimental comparison of Triton X-100 and sodium dodecyl benzene sulfonate surfactants on thermal performance of TiO2-deionized water nanofluid in a thermosiphon Sozen A, Guru M, Menlik T, Karakaya U, Ciftci E Experimental Heat Transfer, 31(5), 450, 2018 |
4 |
Experimental investigation of heat transfer and pressure drop in a straight minichannel heat sink using TiO2 nanofluid Arshad W, Ali HM International Journal of Heat and Mass Transfer, 110, 248, 2017 |
5 |
Thermal conductivity of dry anatase and rutile nano-powders and ethylene and propylene glycol-based TiO2 nanofluids Cabaleiro D, Nimo J, Pastoriza-Gallego MJ, Pineiro MM, Legido JL, Lugo L Journal of Chemical Thermodynamics, 83, 67, 2015 |
6 |
Experimental comparative study of heat pipe performance using CuO and TiO2 nanofluids Manimaran R, Palaniradja K, Alagumurthi N, Hussain J International Journal of Energy Research, 38(5), 573, 2014 |
7 |
Accuracy enhancement of thermal dispersion model in prediction of convective heat transfer for nanofluids considering the effects of particle migration Bahiraei M, Hosseinalipour SM Korean Journal of Chemical Engineering, 30(8), 1552, 2013 |