. 2019 May 23;5(5):e01627. doi: 10.1016/j.heliyon.2019.e01627

Table 3.

Summary of experimental and theoretical works related to Thermosyphon using nanofluids.

Literature	Desc. of Working Medium	Desc. of operating parameters	Critique Outcome	Year
Noie et al. [28]	Types of nanofluids: Al₂O₃/water % concentration: 1–3 v% Particle size (nm): 20	Heat Load (W): 50, 100, 150, 200 Surface temperature (°C): 28-58	o Efficiency was increased up to 14.7% as compared with pure water.	2009
Huminic et al. [29]	Types of nanofluids: Iron oxide/DI Water % concentration: 2.0, 5.3 % Filling ratio: 12% HP Particle size (nm): 4-5	Orientation (Deg.): 45, 90 Surface temperature (°C): 25-65	o Thermal resistance of thermosyphon with iron oxide nanofluid had lower than DI water. o Thermal resistance was decreased by increasing concentration.	2011
Parametthanuwat et al. [30]	Types of nanofluids: Ag/water % concentration: 0.5, 1.0, 1.5 w% Filling ratio: 30, 40, 80 % V_Evap.	Heat Load: 0–4 kW/m2 Surface temperature (°C): 60, 70, 80	o Highest heat flux of 25 kW/m² and highest effectiveness of 0.3 were achieved at 50 % filling ratio and 1 wt% concentration.	2011
Huminic et al. [31]	Types of nanofluids: Fe₂O₃/water % concentration: 2, 5.3 v% Particle size (nm): 4-5	Orientation (Deg.): 60, 70, 80, 90 Heat Load (W): 60, 70, 80, 90 Surface temperature (°C): 60-90	o Experimental and numerical results showed better heat transfer characteristics of thermosyphon using nanofluid as compared with water.	2013
Kamyar et al. [32]	Types of nanofluids: Al₂O₃, TiSiO₄/water % concentration: 0.01, 0.02, 0.05, 0.075 v% Particle size (nm): 13, 50	Heat Load (W): 40, 70, 120, 180, 210 Surface temperature (°C): 20-80 Pressure: -0.9 bar	o Thermal resistance was decreased by 65% with 0.05 v% Al₂O₃ and 57% with 0.075 v% TiSiO₄ nanofluids.	2013
Liu et al. [33]	Types of nanofluids: CuO/DI Water % concentration: 0.8–1.5 wt% Filling ratio: 60% V_Evap. Particle size (nm): 20-50	Heat Load (W): 300-1200 Surface temperature (°C): 0-40°	o Air outlet temperature and system collecting efficiency of the solar air collector using nanofluid was higher than water.	2013
Menlik et al. [34]	Types of nanofluids: MgO/Water % concentration: 1–5 v% Filling ratio: 33.3% HP Particle size (nm): 40	Heat Load (W): 200, 300, 400 Surface temperature (°C): 20-80	o Heat transfer rate was enhanced by 26% at 200 W heating power and 7.5 g/s flow rate.	2015