Stability Investigation of the PCM Nanocomposites

1 Haghighi EB, Nikkam N, Saleemi M, Behi M, Mirmohammadi MA, Poth H, et al. Shelf stability of nanofluids and its effect on thermal conductivity and viscosity. Measurement Science and Technology. 2013;24;105301. Search in Google Scholar

2 Lotfizadeh Dehkordi B., Ghadimi A., Metselaar H.S.C. Box–Behnken experimental design for investigation of stability and thermal conductivity of TiO₂ nanofluids. Journal of Nanoparticle Research. 2013;15:1369. Search in Google Scholar

3 Witharana S., Palabiyik I., Musina Z., Ding Y. Stability of glycol nanofluids — The theory and experiment. Powder Technology. 2013;239:72–77. Search in Google Scholar

4 Ilyas S.U., Pendyala R., Marneni N. Stability and Agglomeration of Alumina Nanoparticles in Ethanol-Water Mixtures. Procedia Engineering. 2016;148:290–297. Search in Google Scholar

5 Fuskele V., Sarviya R.M. Recent developments in Nanoparticles Synthesis. Preparation and Stability of Nanofluids. Materials Today: Proceedings. 2017;4:4049–4060. Search in Google Scholar

6 Yu F, Chen Y, Liang X, Xu J, Lee C, Liang Q, et al. Dispersion stability of thermal nanofluids. Progress in Natural Science: Materials International. 2017;27:531-542. Search in Google Scholar

7 Abdullah M, Malik SA, Iqbal MH, Sajid MM, Shad NA, Hussain SZ, et al. Sedimentation and stabilization of nano-fluids with dispersant. Colloids and Surfaces. 2018;554;86–92. Search in Google Scholar

8 Mahbubul IM, Elcioglu EB, Amalina MA, Saidur R. Stability, thermophysical properties and performance assessment of alumina–water nanofluid with emphasis on ultrasonication and storage period. Powder Technology. 2019;345:668–675. Search in Google Scholar

9 Lee L, Han K, Koo J. A novel method to evaluate dispersion stability of nanofluids. International Journal of Heat and Mass Transfer. 2014;70;421–429. Search in Google Scholar

10 Lemes MA, Rabelo D, de Oliveira AE. A novel method to evaluate nanofluid stability using multivariate image analysis. Analytical Methods. 2017;9;5826. Search in Google Scholar

11 Ilyas SU, Pendyala R, Marneni N. Stability of nanofluids. Topics in Mining, Metallurgy and Materials Engineering. Eds. Korada VS, Hamid NHB. Engineering applications of nanotechnology. From energy to drug delivery. Springer;2017. Avaiable from: https://www.springerprofessional.de/engineering-applications-of-nanotechnology/11992454 Search in Google Scholar

12 Wu S, Zhu D, Zhang X, Huang J. Preparation and Melting/Freezing Characteristics of Cu/Paraffin Nanofluid as Phase-Change Material (PCM). Energy Fuels. 2010; 24(3):1894–1898. Search in Google Scholar

13 Choi DH, Lee J, Hong H, Kang Y T. Thermal conductivity and heat transfer performance enhancement of phase change materials (PCM) containing carbon additives for heat storage application. International Journal of Refrigeration. 2014;42:112-120. Search in Google Scholar

14 Jin Y, Wan Q, Ding Y. PCMs Heat Transfer Performance Enhancement with Expanded Graphite and its Thermal Stability. Procedia Eng. 2015;102:1877-1884 Search in Google Scholar

15 Zhichao L, Qiang Z, Gaohui W. Preparation and enhanced heat capacity of nano-titania doped erythritol as phase change material. International Journal of Heat and Mass Transfer. 2015;80;653–659. Search in Google Scholar

16 Nourani M, Hamdami N, Keramat J, Moheb A, Shahedi M. Thermal behavior of paraffin-nano-Al₂O₃ stabilized by sodium stearoyl lactylate as a stable phase change material with high thermal conductivity. Renewable Energy. 2016;88:474-482. Search in Google Scholar

17 Liu Y, Yang Y. Use of nano-α-Al₂O₃ to improve binary eutectic hydrated salt as phase change material. Solar Energy Materials & Solar Cells. 2017;160;18–25. Search in Google Scholar

18 Singh DK, Suresh S, Singh H, Rose BAJ, Tassou S, Anantharaman N. Myo-inositol based nano-PCM for solar thermal energy storage. Applied Thermal Engineering. 2017;110;564–572. Search in Google Scholar

19 Zhang JL, Wu N, Wu XW, Chen Y, Zhao Y, Liang JF, et al. High latent heat stearic acid impregnated in expanded graphite. Thermochimica Acta. 2018;663;118–124. Search in Google Scholar

20 Nourani M, Hamdami N, Keramat J. Preparation and evaluation of a stable nanoalumina-paraffin composite: Melting rate investigation using image analysis. Journal of Dispersion Science and Technology. 2018;39(10);1385-1393. Search in Google Scholar

21 Prabhu B, ValanArasu A. Stability analysis of TiO₂–Ag nanocomposite particles dispersed paraffin wax as energy storage material for solar thermal systems. Renewable Energy. 2020;152;358-367. Search in Google Scholar

22 Ibrahim SI, Ali AA., Hafidh SA, Chaichan MT, Kazem HA, Ali JM, Isahak WNR, Alamiery A. Stability and thermal conductivity of different nano-composite material prepared for thermal energy storage applications. South African Journal of Chemical Engineering. 2022;39;72-89. Search in Google Scholar

23 Zhang G, Guo Y, Zhang B, Yan X, Lu W, Cui G, Du Y. Preparation and control mechanism of nano-phase change emulsion with high thermal conductivity and low supercooling for thermal energy storage. Energy Reports. 2022;8;8301-8311. Search in Google Scholar

24 Venkateshwar K, Joshy N, Simha H, Mahmud S. Quantifying the nanoparticles concentration in nano-PCM. Journal of Nanoparticle Research. 2019;21;260. Search in Google Scholar

25 Saydam V, Duan X. Dispersing Different Nanoparticles in Paraffin Wax as Enhanced Phase Change Materials – A Study on the Stability Issue. Journal of Thermal Analysis and Calorimetry. 2018;135(1): Search in Google Scholar

26 Lee W, Yeop J, Heo J, Yoon YJ, Park SY, Jeong J, et al. High colloidal stability ZnO nanoparticles independent on solvent polarity and their application in polymer solar cells. Scientific Reports. 2020;10:18055. Search in Google Scholar

27 Rajendran D, Ramalingame R, Adiraju A, Nouri H, Kanoun O. Role of Solvent Polarity on Dispersion Quality and Stability of Functionalized Carbon Nanotubes. Journal of Composites Science. 2022;6(1):26 Search in Google Scholar

28 Saroha J, Mehra S, Kumar M, Sharma SN. Thermo-physical properties of paraffin/TiO₂ and sorbitol/TiO₂ nanocomposites for enhanced phase change materials: a study on the stability issue. Applied Physics A. 2021;127:916. Search in Google Scholar