Recent advancements in thermal performance of nano-fluids charged heat pipes used for thermal management applications: A comprehensive review
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[1] F. Kilinc,et al. EXERGY ANALYSIS OF GRAPHENE-BASED NANOFLUIDS IN A COMPACT HEAT EXCHANGER , 2022, Isı Bilimi ve Tekniği Dergisi.
[2] O. Makinde,et al. Rheological Modeling of Metallic Oxide Nanoparticles Containing Non-Newtonian Nanofluids and Potential Investigation of Heat and Mass Flow Characteristics , 2022, Nanomaterials.
[3] O. Bég,et al. Computational Framework of Magnetized MgO–Ni/Water-Based Stagnation Nanoflow Past an Elastic Stretching Surface: Application in Solar Energy Coatings , 2022, Nanomaterials.
[4] K. Bashirnezhad,et al. Experimental Study of Thermal Performance of a Newly Designed Pulsating Heat Pipe with Fe3O4 Nanofluid-Exposed Magnetic Field and Corrugated Evaporator , 2022, International Journal of Thermophysics.
[5] S. Bhattacharyya,et al. A detailed review on the performance of photovoltaic/thermal system using various cooling methods , 2022, Sustainable Energy Technologies and Assessments.
[6] E. Michaelides,et al. Hybrid nanofluid flow towards an elastic surface with tantalum and nickel nanoparticles, under the influence of an induced magnetic field , 2021, The European Physical Journal Special Topics.
[7] M. S. Naghavi,et al. Using Graphene Nanoplatelets Nanofluid in a Closed-Loop Evacuated Tube Solar Collector—Energy and Exergy Analysis , 2021, Journal of Composites Science.
[8] Xudong Zhao,et al. A comprehensive review on the application of nanofluid in heat pipe based on the machine learning: Theory, application and prediction , 2021 .
[9] M. Afrand,et al. The use of nanofluids in thermosyphon heat pipe: A comprehensive review , 2021 .
[10] W. Cai,et al. An updated review on working fluids, operation mechanisms, and applications of pulsating heat pipes , 2021, Renewable and Sustainable Energy Reviews.
[11] H. Mohammadiun,et al. The effect of variable temperature and location on relative thermal conductivity (RTC) on the heat pipe in the presence of AL2O3 nanoparticles: Numerical and optimization approaches , 2021, Journal of the Taiwan Institute of Chemical Engineers.
[12] N. Sateesh,et al. Experimental and transient thermal analysis of screen mesh wick heat pipe , 2021 .
[13] S. Abdel-Samad,et al. Thermal performances and characteristics of thermosyphon heat pipe using alumina nanofluids , 2021, Heat and Mass Transfer.
[14] Yong Tang,et al. Thermal performance enhancement of an ultra-thin flattened heat pipe with multiple wick structure , 2021 .
[15] H. Metselaar,et al. Thermal Performance and Numerical Simulation of the 1-Pyrene Carboxylic-Acid Functionalized Graphene Nanofluids in a Sintered Wick Heat Pipe , 2020, Energies.
[16] B. Suresh kumar,et al. Investigation on thermophysical properties and heat transfer performance of heat pipe charged with binary mixture based ZnO-MgO hybrid nanofluids , 2020 .
[17] Pushpendra Kumar Singh Rathore,et al. Thermal performance optimization of heat pipe using nanofluid: response surface methodology , 2020, Journal of the Brazilian Society of Mechanical Sciences and Engineering.
[18] M. Ahmadi,et al. Assessment of a heat pipe solar collector with nanofluids , 2020, Environmental Science and Pollution Research.
[19] S. M. Sohel Murshed,et al. Life Time Expectancy Prediction and Ageing Process of Heat Pipes Using Nanofluids , 2020, Heat Transfer Engineering.
[20] B. Salam,et al. A review on nanofluid: preparation, stability, thermophysical properties, heat transfer characteristics and application , 2020, SN Applied Sciences.
[21] M. Saghi,et al. Experimental investigation of the effect of using water and ethanol as working fluid on the performance of pyramid-shaped solar still integrated with heat pipe solar collector , 2020 .
[22] N. Gnanasundaram,et al. Preparation and characterization of ZnO, MgO and ZnO–MgO hybrid nanomaterials using green chemistry approach , 2020, Results in Materials.
[23] A. Sözen,et al. The Impacts of Nanoparticle Concentration and Surfactant Type on Thermal Performance of A Thermosyphon Heat Pipe Working With Bauxite Nanofluid , 2020 .
[24] H. Qi,et al. Experimental study on heat transfer performance of pulsating heat pipes with hybrid working fluids , 2020, International Journal of Heat and Mass Transfer.
[25] A. Sözen,et al. An Experimental Investigation on Aqueous Fe–CuO Hybrid Nanofluid Usage in a Plain Heat Pipe , 2020, International Journal of Thermophysics.
[26] M. Mehrali,et al. Parametric study on the thermal performance enhancement of a thermosyphon heat pipe using covalent functionalized graphene nanofluids , 2020, Applied Thermal Engineering.
[27] A. Sözen,et al. Experimental and numerical analysis on using CuO-Al2O3/water hybrid nanofluid in a U-type tubular heat exchanger , 2020 .
[28] Metin Kaya. An experimental investigation on thermal efficiency of two-phase closed thermosyphon (TPCT) filled with CuO/water nanofluid , 2020, Engineering Science and Technology, an International Journal.
[29] T. Al‐Ansari,et al. An updated review of nanofluids in various heat transfer devices , 2020, Journal of Thermal Analysis and Calorimetry.
[30] Hao Yu,et al. Performance enhancement of graphene-coated micro heat pipes for light-emitting diode cooling , 2020, International Journal of Heat and Mass Transfer.
[31] Liu Yang,et al. An updated review on the properties, fabrication and application of hybrid-nanofluids along with their environmental effects , 2020 .
[32] H. Ali,et al. Heat pipes: progress in thermal performance enhancement for microelectronics , 2020, Journal of Thermal Analysis and Calorimetry.
[33] G. Kumaresan,et al. Performance analysis of thermosyphon heat pipe using aluminum oxide nanofluid under various angles of inclination , 2020 .
[34] K. V. Rao,et al. Impact of Green Synthesized Metal Oxide Nanoparticles on Seed Germination and Seedling Growth of Vigna radiata (Mung Bean) and Cajanus cajan (Red Gram) , 2020, Journal of Inorganic and Organometallic Polymers and Materials.
[35] S. Venkatachalapathy,et al. Thermal performance enhancement studies using graphite nanofluid for heat transfer applications , 2020, Heat Transfer.
[36] Yulong Ding,et al. A comparative investigation on the effect of different nanofluids on the thermal performance of two-phase closed thermosyphon , 2020, International Journal of Heat and Mass Transfer.
[37] S. Samanta,et al. Heat transfer enhancement in a thermosyphon using TiO2 nanofluid through natural convection , 2020 .
[38] Yuwen Zhang,et al. Numerical simulation of oscillatory flow and heat transfer in pulsating heat pipes with multi-turns using OpenFOAM , 2020 .
[39] M. Z. Abdullah,et al. Metal oxide nanofluids in electronic cooling: a review , 2020, Journal of Materials Science: Materials in Electronics.
[40] Dilip Singh Naruka,et al. Experimental inquisition of heat pipe: performance evaluation for different fluids , 2020 .
[41] Amnart Suksri,et al. Performance enhancement of a photovoltaic module by passive cooling using phase change material in a finned container heat sink , 2020 .
[42] K. Ng,et al. Numerical and experimental investigations of hybrid nanofluids on pulsating heat pipe performance , 2020 .
[43] Maryam Shafahi,et al. Effect of Nanofluid and Surfactant on Thermosyphon Heat Pipe Performance , 2020, Heat Transfer Engineering.
[44] S. Venkatachalapathy,et al. Effect of hydrophilic coating on mesh wicks used in heat pipes , 2019, Surface Engineering.
[45] Liu Yang,et al. Thermal conductivity enhancement of water by adding graphene Nano-sheets: Consideration of particle loading and temperature effects , 2019 .
[46] N. Chavda. Investigation of Thermal Performance of Cylindrical Heat Pipe Using Silver Nanofluid. Part I: Experimental Evaluation , 2019, Journal of The Institution of Engineers (India): Series C.
[47] H. Öztop,et al. Experimental investigation of oscillating heat pipe efficiency for a novel condenser by using Fe3O4 nanofluid , 2019, Journal of Thermal Analysis and Calorimetry.
[48] G. Walker,et al. Thermo-physical properties of the nano-binary fluid (acetone–zinc bromide-ZnO) as a low temperature operating fluid for use in an absorption refrigeration machine , 2019, Heat and Mass Transfer.
[49] R. Baby,et al. Enhancement of the thermal performance of a loop heat pipe using silica-water nanofluid , 2019, Journal of Physics: Conference Series.
[50] Somchai Wongwises,et al. An updated review on application of nanofluids in heat exchangers for saving energy , 2019, Energy Conversion and Management.
[51] G. Huminic,et al. Numerical study of the heat transfer and flow characteristics of heat pipes , 2019, IOP Conference Series: Materials Science and Engineering.
[52] A. Sözen,et al. Experimental and numerical study on enhancement of heat transfer characteristics of a heat pipe utilizing aqueous clinoptilolite nanofluid , 2019, Applied Thermal Engineering.
[53] V. Patel,et al. Channel wise displacement-velocity-frequency analysis in acetone charged multi-turn Closed Loop Pulsating Heat Pipe , 2019, Energy Conversion and Management.
[54] M. Ahmadi,et al. A review on using nanofluids in heat pipes , 2019, Journal of Thermal Analysis and Calorimetry.
[55] M. Assad,et al. Thermal Resistance Modeling of Oscillating Heat Pipes for Nanofluids by Artificial Intelligence Approach , 2019, Journal of Heat Transfer.
[56] J. Graves,et al. Ultrasonic preparation, stability and thermal conductivity of a capped copper-methanol nanofluid. , 2019, Ultrasonics sonochemistry.
[57] Ali Sulaiman Alsagri,et al. Influence of cerium oxide nanoparticles on thermal conductivity of antifreeze , 2019, Journal of Thermal Analysis and Calorimetry.
[58] H. Ghorbani,et al. Synthesis, preparation and the experimental study of silver/water nanofluid to optimize convective heat transfer in a shell and tube heat exchanger , 2019, Inorganic and Nano-Metal Chemistry.
[59] M. Sarafraz,et al. Assessment of the thermal performance of a thermosyphon heat pipe using zirconia-acetone nanofluids , 2019, Renewable Energy.
[60] Saeed Zeinali Heris,et al. Experimental investigation of a novel type of two-phase closed thermosyphon filled with functionalized carbon nanotubes/water nanofluids for electronic cooling application , 2019, Energy Conversion and Management.
[61] M. Sadeghzadeh,et al. A review on application of nanofluid in various types of heat pipes , 2019, Journal of Central South University.
[62] Rakesh K. Bumataria,et al. Current research aspects in mono and hybrid nanofluid based heat pipe technologies , 2019, Heliyon.
[63] Hafiz Muhammad Ali,et al. Towards hybrid nanofluids: Preparation, thermophysical properties, applications, and challenges , 2019, Journal of Molecular Liquids.
[64] O. Sazhin,et al. Heat transfer enhancement in a loop thermosyphon using nanoparticles/water nanofluid , 2019, International Journal of Heat and Mass Transfer.
[65] Wenjun Fang,et al. Stability properties of water-based gold and silver nanofluids stabilized by cationic gemini surfactants , 2019, Journal of the Taiwan Institute of Chemical Engineers.
[66] M. Koç,et al. A comprehensive review on synthesis, stability, thermophysical properties, and characterization of nanofluids , 2019, Powder Technology.
[67] M. Joseph,et al. An investigation on heat transfer performance of polystyrene encapsulated n-octadecane based nanofluid in square channel , 2019 .
[68] Gang Wang,et al. Performance of a flat-plate micro heat pipe at different filling ratios and working fluids , 2019, Applied Thermal Engineering.
[69] K. Ng,et al. Evaluation of the thermal performance of hybrid nanofluids in pulsating heat pipe , 2019 .
[70] J. Narayan,et al. Synthesis, Characterization and Physicochemical Properties of Cupric Oxide Nanoparticles and their Nanofluids , 2019, Materials Today: Proceedings.
[71] S. Ghosh,et al. Numerical study of CeO2/H2O nanofluid application on thermal performance of heat pipe , 2019, Materials Today: Proceedings.
[72] M. Nazari,et al. Application of nanofluids in thermosyphons: A review , 2018, Journal of Molecular Liquids.
[73] G. Kumaresan,et al. Experimental study on effect of wick structures on thermal performance enhancement of cylindrical heat pipes , 2018, Journal of Thermal Analysis and Calorimetry.
[74] P. C. Mishra,et al. Stability of Heat Transfer Nanofluids - A Review , 2018, ChemBioEng Reviews.
[75] Angel Huminic,et al. Hybrid nanofluids for heat transfer applications – A state-of-the-art review , 2018, International Journal of Heat and Mass Transfer.
[76] M. Kahani,et al. Thermal performance prediction of wickless heat pipe with Al2O3/water nanofluid using artificial neural network , 2018, Chemical Engineering Communications.
[77] Mohammad Hossein Ahmadi,et al. A review of thermal conductivity of various nanofluids , 2018, Journal of Molecular Liquids.
[78] Mohammad Behshad Shafii,et al. How to improve the thermal performance of pulsating heat pipes: A review on working fluid , 2018, Renewable and Sustainable Energy Reviews.
[79] C. Byon,et al. Fabrication and characterization of pure-metal-based submillimeter-thick flexible flat heat pipe with innovative wick structures , 2018, International Journal of Heat and Mass Transfer.
[80] Ahmet Ozsoy,et al. Thermal performance of a thermosyphon heat pipe evacuated tube solar collector using silver-water nanofluid for commercial applications , 2018, Renewable Energy.
[81] S. Ghosh,et al. Exergy analysis of hybrid nanofluids with optimum concentration in a plate heat exchanger , 2018, Materials Research Express.
[82] A. Farzaneh,et al. Experimental study of using Al2O3/methanol nanofluid in a two phase closed thermosyphon (TPCT) array as a novel photovoltaic/thermal system , 2018 .
[83] V. Sharma,et al. Experimental and Numerical Investigations on Al2O3–Tricosane Based Heat Pipe Thermal Energy Storage , 2018, International Journal of Engineering.
[84] Mohammad Hossein Ahmadi,et al. Experimental investigation of graphene oxide nanofluid on heat transfer enhancement of pulsating heat pipe , 2018 .
[85] Gnanavelbabu A,et al. Experimental Analysis on Thermal Performance of Fabricated Flat Plate Heat Pipe Using Titanium Dioxide Nanofluid , 2018 .
[86] M. Sarafraz,et al. Thermal performance analysis of a flat heat pipe working with carbon nanotube-water nanofluid for cooling of a high heat flux heater , 2018 .
[87] S. Ghosh,et al. Heat transfer mechanisms in heat pipes using nanofluids-A review , 2018 .
[88] Davood Toghraie,et al. A comprehensive study of the performance of a heat pipe by using of various nanofluids , 2017 .
[89] K. S. Rajan,et al. Metal oxide nanofluids: Review of formulation, thermo-physical properties, mechanisms, and heat transfer performance , 2017 .
[90] L. Wrobel,et al. Heat pipe based systems - Advances and applications , 2017 .
[91] E. Languri,et al. Exergy analysis of a shell-and-tube heat exchanger using graphene oxide nanofluids , 2017 .
[92] Steven P. Benn,et al. Thermal performance of heat pipes using nanofluids , 2017 .
[93] Jianlin Sun,et al. Preparation, characterization and tribological mechanism of nanofluids , 2017 .
[94] Sarit K. Das,et al. Augmented Thermal Performance of Straight Heat Pipe Employing Annular Screen Mesh Wick and Surfactant Free Stable Aqueous Nanofluids , 2017 .
[95] Wael I. A. Aly,et al. Thermal performance evaluation of a helically-micro-grooved heat pipe working with water and aqueous Al2O3 nanofluid at different inclination angle and filling ratio , 2017 .
[96] M. Bassily,et al. Experimental Study of Filling Ratio Effect on the Thermal Performance in a Multi-Heat Pipe with Graphene Oxide/Water Nanofluids , 2016 .
[97] F. Hormozi,et al. An experimental investigation on the effects of surfactants on the thermal performance of hybrid nanofluids in helical coil heat exchangers , 2016 .
[98] Mohammad Reza Safaei,et al. Particle size and type effects on heat transfer enhancement of Ferro-nanofluids in a pulsating heat pipe , 2016 .
[99] Raya Al-Dadah,et al. Numerical investigation of effect of fill ratio and inclination angle on a thermosiphon heat pipe thermal performance , 2016 .
[100] Yanzhong Li,et al. Effect of C60 nanofluid on the thermal performance of a flat-plate pulsating heat pipe , 2016 .
[101] F. Hormozi,et al. Experimental investigation on the thermal performance of a coiled heat exchanger using a new hybrid nanofluid , 2016 .
[102] S. Wongwises,et al. Comparative study of the effect of hybrid nanoparticle on the thermal performance of cylindrical screen mesh heat pipe , 2016 .
[103] A. D'Orazio,et al. An experimental study on thermal conductivity of F-MWCNTs–Fe3O4/EG hybrid nanofluid: Effects of temperature and concentration , 2016 .
[104] Valan Arasu Amirtham,et al. A review on preparation, characterization, properties and applications of nanofluids , 2016 .
[105] Emad Sadeghinezhad,et al. Effect of nitrogen-doped graphene nanofluid on the thermal performance of the grooved copper heat pipe , 2016 .
[106] F. Jiang,et al. A Feasibility Study About Using SiO2 Nanofluid Screen Mesh Wick Heat Pipe for Cooling of High-Power LEDs , 2016 .
[107] P. R. Mashaei,et al. Numerical simulation of nanofluid application in a horizontal mesh heat pipe with multiple heat sources: A smart fluid for high efficiency thermal system , 2016 .
[108] Abdullah Yildiz,et al. Thermoeconomic analysis of thermosyphon heat pipes , 2016 .
[109] E. Gedik,et al. Experimental investigation on the thermal performance of heat recovery system with gravity assisted heat pipe charged with R134a and R410A , 2016 .
[110] Zhen-hua Liu,et al. Performance improvement of wire-bonded mesh screen flat heat pipe using water-based nanofluid , 2016 .
[111] Somchai Wongwises,et al. Thermal performance of miniature loop heat pipe with graphene–water nanofluid , 2016 .
[112] Jiateng Zhao,et al. Experimental investigation on thermal performance of phase change material coupled with closed-loop oscillating heat pipe (PCM/CLOHP) used in thermal management , 2016 .
[113] M. Shojaeefard,et al. Numerical Simulation of the Thermal Performance of a Nanofluid-Filled Heat Pipe , 2016 .
[114] Bahman Zohuri,et al. Heat Pipe Design and Technology , 2016 .
[115] Laifeng Li,et al. Experimental investigation on the thermal performance of helium based cryogenic pulsating heat pipe , 2016 .
[116] S. Wongwises,et al. Effect of volume concentration and temperature on viscosity and surface tension of graphene–water nanofluid for heat transfer applications , 2016, Journal of Thermal Analysis and Calorimetry.
[117] M. Ghanbarpour,et al. Improvement of heat transfer characteristics of cylindrical heat pipe by using SiC nanofluids , 2015 .
[118] A. Sözen,et al. Heat transfer enhancement using MgO/water nanofluid in heat pipe , 2015 .
[119] P. R. Mashaei,et al. Effect of nanofluid on thermal performance of heat pipe with two evaporators; application to satellite equipment cooling , 2015 .
[120] Mohammad Mohsen Sarafraz,et al. Role of nanofluid fouling on thermal performance of a thermosyphon: Are nanofluids reliable working fluid? , 2015 .
[121] Satyajit Sahu,et al. Performance of Carbon Nanotubes–Water Nanofluid Charged Wickless Heat Pipe Flat Plate Solar Collectors Having Different Filling Ratio , 2015 .
[122] Bin Li,et al. Thermal performance of a miniature loop heat pipe using water–copper nanofluid , 2015 .
[123] Mohamed I. Hassan,et al. An Experimental Study of Heat Pipe Performance Using Nanofluids , 2015 .
[124] P. Ghosh,et al. A review on hybrid nanofluids: Recent research, development and applications , 2015 .
[125] B. T. Chew,et al. Performance dependence of thermosyphon on the functionalization approaches: An experimental study on thermo-physical properties of graphene nanoplatelet-based water nanofluids , 2015 .
[126] S. Sarada,et al. Thermal Analysis of Gravity Effected Sintered Wick Heat Pipe , 2015 .
[127] K. Goudarzi,et al. Experimental study on the effect of pH variation of nanofluids on the thermal efficiency of a solar collector with helical tube , 2015 .
[128] John A. Paulson. Heat Pipes , 2015 .
[129] M. Anwar,et al. Enhancement of Thermal Performance of Heat Pipe Using Hybrid Nanofluid , 2014 .
[130] S. M. Peyghambarzadeh,et al. Thermal performance and efficiency of a thermosyphon heat pipe working with a biologically ecofriendly nanofluid , 2014 .
[131] Bilal Akash,et al. Energy and exergy analysis of alumina-water nanofluid for an electronic liquid cooling system☆ , 2014 .
[132] X. Cui,et al. A comparative study of the behavior of working fluids and their properties on the performance of pulsating heat pipes (PHP) , 2014 .
[133] A. Solomon,et al. Numerical analysis of a screen mesh wick heat pipe with Cu/water nanofluid , 2014 .
[134] Samion Syahrullail,et al. Fluid flow and heat transfer characteristics of nanofluids in heat pipes: A review , 2014 .
[135] A. Solomon,et al. Effect of nanofluids on thermal performance of closed loop pulsating heat pipe , 2014 .
[136] H. Oztop,et al. A review on how the researchers prepare their nanofluids , 2014 .
[137] M. Mehrali,et al. Investigation of thermal conductivity and rheological properties of nanofluids containing graphene nanoplatelets , 2014, Nanoscale Research Letters.
[138] Siamak Kazemzadeh Hannani,et al. Ferrofluidic Open Loop Pulsating Heat Pipes: Efficient Candidates for Thermal Management Of Electronics , 2014 .
[139] Siamak Kazemzadeh Hannani,et al. Open-Loop Pulsating Heat Pipes Charged With Magnetic Nanofluids: Powerful Candidates for Future Electronic Coolers , 2014 .
[140] Dr. V. D. Dhiman,et al. Heat Transfer Enhancement of Heat Pipe Using Nanofluid , 2014 .
[141] Shuofeng Wang,et al. Experimental study on the heat recovery characteristics of a new-type flat micro-heat pipe array heat exchanger using nanofluid , 2013 .
[142] K. S. Ong,et al. Effects of nanofluids on heat transfer characteristics of a two-phase closed thermosyphon , 2013 .
[143] Mohd Zulkifly Abdullah,et al. Influence of nanofluid on heat transfer in a loop heat pipe , 2013 .
[144] S. Rittidech,et al. Silver Nanofluid Containing Oleic Acid Surfactant As Working Fluid In The Two-Phase Closed Thermosyphon (TPCT): A Thermodynamic Study , 2013 .
[145] Mohammad Behshad Shafii,et al. Promising Technology for Electronic Cooling: Nanofluidic Micro Pulsating Heat Pipes , 2013 .
[146] R. Sureshkumar,et al. Heat transfer characteristics of nanofluids in heat pipes: A review , 2013 .
[147] Madhusree Kole,et al. Thermal performance of screen mesh wick heat pipes using water-based copper nanofluids , 2013 .
[148] Mohammad Ali,et al. Effect of Filling Ratio on Heat Transfer Characteristics and Performance of a Closed Loop Pulsating Heat Pipe , 2013 .
[149] Thanaphol Sukchana,et al. Effect of Filling Ratios and Adiabatic Length on Thermal Efficiency of Long Heat Pipe Filled with R-134a , 2013 .
[150] Zhen-hua Liu,et al. A new frontier of nanofluid research – Application of nanofluids in heat pipes , 2012 .
[151] Jae Won Lee,et al. Thermal conductivity measurement of methanol-based nanofluids with Al2O3 and SiO2 nanoparticles , 2012 .
[152] A. Yu. Kuznetsov,et al. Application of the modulated temperature differential scanning calorimetry technique for the determination of the specific heat of copper nanofluids , 2012 .
[153] Munkhbayar Batmunkh,et al. Investigation of Al2O3-MWCNTs hybrid dispersion in water and their thermal characterization. , 2012, Journal of nanoscience and nanotechnology.
[154] Nagamany Nirmalakhandan,et al. Desalination at low temperatures: an exergy analysis , 2012 .
[155] S. Ramaprabhu,et al. Surfactant free graphene nanosheets based nanofluids by in-situ reduction of alkaline graphite oxide suspensions , 2011 .
[156] Nandy Putra,et al. Application of nanofluids to a heat pipe liquid-block and the thermoelectric cooling of electronic equipment , 2011 .
[157] K. P. Venkitaraj,et al. Synthesis of Al2O3–Cu/water hybrid nanofluids using two step method and its thermo physical properties , 2011 .
[158] L. Chow,et al. Jet impingement and spray cooling using slurry of nanoencapsulated phase change materials , 2011 .
[159] A. F. Akon,et al. PERFORMANCE OF HEAT PIPE FOR DIFFERENT WORKING FLUIDS AND FILL RATIOS , 2011 .
[160] Saeed Zeinali Heris,et al. Designing a neural network for closed thermosyphon with nanofluid using a genetic algorithm , 2011 .
[161] J. Thibault,et al. Thermal conductivity of non-Newtonian nanofluids: Experimental data and modeling using neural network , 2011 .
[162] Angel Huminic,et al. Experimental study of the thermal performance of thermosyphon heat pipe using iron oxide nanoparticles , 2011 .
[163] Ashutosh Kumar Singh,et al. Thermal and rheological behavior of acetylacetone stabilized ZnO nanofluids , 2010 .
[164] Kyu Hyung Do,et al. Effect of nanofluids on the thermal performance of a flat micro heat pipe with a rectangular grooved wick , 2010 .
[165] Kirk L. Yerkes,et al. Experimental investigation into the convective heat transfer and system-level effects of Al2O3-propanol nanofluid , 2010 .
[166] Vincenzo Bianco,et al. Thermal performance of flat-shaped heat pipes using nanofluids , 2010 .
[167] Huaqing Xie,et al. Enhanced thermal conductivities of nanofluids containing graphene oxide nanosheets , 2010, Nanotechnology.
[168] Stéphane Lips,et al. Combined effects of the filling ratio and the vapour space thickness on the performance of a flat plate heat pipe , 2010 .
[169] S. Wongwises,et al. An experimental study on the heat transfer performance and pressure drop of TiO2-water nanofluids flowing under a turbulent flow regime , 2010 .
[170] Saeed Zeinali Heris,et al. HEAT TRANSFER ENHANCEMENT USING AL2O3/WATER NANOFLUID IN A TWO-PHASE CLOSED THERMOSYPHON , 2009 .
[171] Ravikanth S. Vajjha,et al. Density Measurement of Different Nanofluids and Their Comparison With Theory , 2009 .
[172] Paisarn Naphon,et al. Experimental investigation of titanium nanofluids on the heat pipe thermal efficiency , 2008 .
[173] A. Mujumdar,et al. A review on nanofluids - part I: theoretical and numerical investigations , 2008 .
[174] Shung-Wen Kang,et al. Effect of silver nano-fluid on pulsating heat pipe thermal performance , 2008 .
[175] Sheng‐Qi Zhou,et al. Measurement of the specific heat capacity of water-based Al2O3 nanofluid , 2008 .
[176] Yuwen Zhang,et al. Advances and Unsolved Issues in Pulsating Heat Pipes , 2008 .
[177] B. Ku,et al. Stability and thermal conductivity characteristics of nanofluids , 2007 .
[178] J. O. Jabera,et al. Evaluation of conventional and renewable energy sources for space heating in the household sector , 2007 .
[179] Leonardo L Carvalho,et al. The fat-1 transgene in mice increases antioxidant potential, reduces pro-inflammatory cytokine levels, and enhances PPARγ and SIRT-1 expression on a calorie restricted diet , 2009, Oxidative medicine and cellular longevity.
[180] S. M. Kumar,et al. A sedimentation study to optimize the dispersion of alumina nanoparticles in water , 2005 .
[181] Wenhua Yu,et al. The Role of Interfacial Layers in the Enhanced Thermal Conductivity of Nanofluids: A Renovated Maxwell Model , 2003 .
[182] Manfred Groll,et al. Understanding operational regimes of closed loop pulsating heat pipes: an experimental study , 2003 .
[183] Xianfan Xu,et al. Thermal Conductivity of Nanoparticle -Fluid Mixture , 1999 .
[184] K. S. Ong. Thermal performance of solar air heaters—Experimental correlation , 1995 .
[185] O. K. Crosser,et al. Thermal Conductivity of Heterogeneous Two-Component Systems , 1962 .
[186] J. Maxwell. A Treatise on Electricity and Magnetism , 1873, Nature.