MATERIALS AND SUSTAINABLE DEVELOPMENT: ADVANCED MATERIALS FOR CLEAN ENERGY UTILIZATION |
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A State-of-Art Review on Preparation Methodology of Nano-copper and Propertiesof Copper Nanofluids Used in Solar Radiation Absorbing Materials |
ZHOU Lu, MA Honghe, MA Suxia, DU Huijuan
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School of Electrical and Power Engineering, Taiyuan University of Technology, Taiyuan 030024 |
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Abstract The development of nanofluids has strongly alleviated the research of solar radiation absorbing materials serving in direct absorption type solar energy collection systems. Copper has the advantages of low cost, abundant source and excellent thermal conductivity. Moreover, the copper nanofluids prepared by dispersing nanoscale copper particles in the traditional solar absorbing mediums display strong absorptivity to visible light. This paper firstly reviews the preparation methodology of nanocopper additives with various morphologies, i.e. sphere, cube, rod and wire, by hydrothermal reduction method, and emphatically discusses the effects of surfactants on the morphology control and dispersion stability of nanocopper in the mediums. Besides, it also summarizes the research status of physical characteristics of the copper nanofluids such as thermal conductivity, viscosity, specific heat and light radiation, and sketches out copper nanofluids’ application in the direct absorption type solar energy collection systems. Finally, some unresolved problems and the corresponding suggestions for further research are proposed.
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Published: 09 August 2018
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1 Choi S U S, Eastman J A. Enhancing thermal conductivity of fluids with nanoparticles[C]∥ASME International Mechanical Engineering Congress & Exposition. San Francisco, 1995. 2 Patel H E, Sundararajan T, Das S K. An experimental investigation into the thermal conductivity enhancement in oxide and metallic nanofluids[J].Journal of Nanoparticle Research,2010,12(3):1015. 3 Zhang L. Radiative properties and photothermal conversion perfor-mance of ionic liquid based nanofluids[D].Guangzhou: South China University of Technology,2015(in Chinese). 张龙.离子液体基纳米流体的辐射特性和光热转换性能研究[D].广州:华南理工大学,2015. 4 Taylor R A, Phelan P E, Otanicar T P, et al. Applicability of nanofluids in high flux solar collectors[J].Journal of Renewable and Sustainable Energy,2011,3(2):4. 5 Chen F. Characteristics of nanofluids used in solar thermal collectors[D].Wuhan: Wuhan Institute of Technology,2016(in Chinese). 陈飞.太阳能集热器装置用纳米流体特性研究[D].武汉:武汉工程大学,2016. 6 Mao L B, Zhang R Y, Ke X F. Study on the preparation solar of one new recycle fluid for collector[J].Renewable Energy Resources,2010,28(3):11(in Chinese). 毛凌波,张仁元,柯秀芳.一种新型太阳能集热器循环工质的制备[J].可再生能源,2010,28(3):11. 7 Xu G Y, Chen W, Zhang X S, et al. Performance and heat loss analysis on the direct absorption medium-temperature solar collector using oil-based nanofluid[J].Journal of Engineering Thermophysics,2015,36(5):960(in Chinese). 徐国英,陈伟,张小松,等.纳米流体直接吸收式太阳能中温集热与热损分析[J].工程热物理学报,2015,36(5):960. 8 张立德.纳米材料和纳米结构[J].中国科学院院刊,2001,16(6):444. 9 Wu S, Wang H, Xiao S, et al. Numerical simulation on thermal energy storage behavior of Cu/paraffin nanofluids PCMs[J].Procedia Engineering,2011,2(1):240. 10 He Q B, Wang S F, Zeng S Q, et al. Experimental investigation on radiation characteristic of nanofluids for direct absorption solar thermal energy systems[J].Journal of Refrigeration,2014(1):109(in Chinese). 何钦波,汪双凤,曾社铨,等.直接吸收式太阳能集热纳米流体辐射特性实验研究[J].制冷学报,2014(1):109. 11 Mao L B, Zhang R Y, Ke X F. Dispersion of nano-copper in cycle fluids of solar collector[J].Nonferrous Metals,2010,62(1):26(in Chinese). 毛凌波,张仁元,柯秀芳.纳米铜粉在太阳能集热器循环工质中的分散[J].有色金属工程,2010,62(1):26. 12 Haddad Z, Abid C, Oztop H F, et al. A review on how the resear-chers prepare their nanofluids[J].International Journal of Thermal Sciences,2014,76(76):168. 13 Xie H W, Tian Y, Yang W L, et al. Nano-copper: Wet-chemical synthesis and applications[J].Journal of Functional Materials,2017,48(4):4060(in Chinese). 谢汉文,田宇,杨万亮,等.纳米铜的湿化学合成及其应用[J].功能材料,2017,48(4):4060. 14 Granata G, Yamaoka T, Pagnanelli F, et al. Study of the synthesis of copper nanoparticles: The role of capping and kinetic towards control of particle size and stability[J].Journal of Nanoparticle Research,2016,18(5):1. 15 Cheng X, Zhang X, Yin H, et al. Modifier effects on chemical reduction synthesis of nanostructured copper[J].Applied Surface Science,2006,253(5):2727. 16 Kuo P L, Liang W J, Wang F Y. Hyperbranch-polyethyl eniminated functional polymers Ⅱ: Effect of polyethyleniminated polyoxypropylenediamines on copper nanoparticle formation in aqueous solution[J].Colloid and Polymer Science,2006,284(4):435. 17 Wang Z L. Transmission electron microscopy of shape-controlled nanocrystals and their assemblies[J].Journal of Physical Chemistry B,2000,104(6):1153. 18 Zhou G, Lu M, Yang Z. Aqueous synthesis of copper nanocubes and bimetallic copper/palladium core-shell nanostructures[J].Langmuir,2006,22(13):5900. 19 Jin M, He G, Zhang H, et al. Shape-controlled synthesis of copper nanocrystals in an aqueous solution with glucose as a reducing agent and hexadecylamine as a capping agent[J].Angewandte Chemie,2011,50(45):10560. 20 Abeywickrama T, Sreeramulu N N, Xu L, et al. A versatile method to prepare size- and shape-controlled copper nanocubes using an aqueous phase green synthesis[J].RSC Advances,2016,6:91949. 21 Rathmell A R, Bergin S M, Hua Y L, et al. The growth mechanism of copper nanowires and their properties in flexible, transparent conducting films[J].Advanced Materials,2010,22(32):3558. 22 Xu C, Wang Y, Chen H, et al. Large-scale synthesis of ultralong copper nanowires via a facile ethylenediamine-mediated process[J].Journal of Materials Science Materials in Electronics,2014,25(5):2344. 23 Kumar D V, Kim I, Zhong Z, et al. Cu(Ⅱ)-alkyl amine complex mediated hydrothermal synthesis of Cu nanowires: Exploring the dual role of alkyl amines[J].Physical Chemistry Chemical Physics,2014,16(40):22107. 24 Ruan H, Wang R, Luo Y, et al. Study on synthesis and growth mechanism of copper nanowires via a facile oleylamine-mediated process[J].Journal of Materials Science Materials in Electronics,2016,27(9):9405. 25 Ebrahimzadeh F, Fung K Z. One-pot synthesis of size and shape controlled copper nanostructures in aqueous media and their application for fast catalytic degradation of organic dyes[J].Journal of Chemical Research,2016,40(9):552. 26 Zhang X, Zhang D, Ni X, et al. One-step preparation of copper nanorods with rectangular cross sections[J].Solid State Communications,2006,139(8):412. 27 Dehghanpour S, Mahmoudi A, Shadpour S. Selective synthesis of copper microsheets and ultralong microwires via a surfactant assisted hydrothermal process[J].Russian Journal of General Chemistry,2015,85(5):1167. 28 Liu Y, Liu Z, Lu N, et al. Facile synthesis of polypyrrole coated copper nanowires: A new concept to engineered core-shell structures[J].Chemical Communications,2012,48(20):2621. 29 Wang Y, Asefa T. Poly(allylamine)-stabilized colloidal copper nanoparticles: Synthesis, morphology, and their surface-enhanced Raman scattering properties[J].Langmuir,2010,26(10):7469. 30 Bhanushali S, Jason N N, Ghosh P C, et al. Enhanced thermal conductivity of copper nanofluids: The effect of filler geometry[J].ACS Applied Materials and Interfaces,2017,9(22):18925. 31 Ye S, Stewart I E, Chen Z, et al. How copper nanowires grow and how to control their properties[J].Accounts of Chemical Research,2016,49(3):442. 32 Kim H, Choi S H, Kim M, et al. Seed-mediated synthesis of ultra-long copper nanowires and their application as transparent conducting electrodes[J].Applied Surface Science,2017,422:731. 33 Kole M, Dey T K. Thermal performance of screen mesh wick heat pipes using water-based copper nanofluids[J].Applied Thermal Engineering,2013,50(1):763. 34 Garg J, Poudel B, Chiesa M, et al. Enhanced thermal conductivity and viscosity of copper nanoparticles in ethylene glycol nanofluid[J].Journal of Applied Physics,2008,103(7):074301. 35 Wang X J, Zhu D S, Yang S. Investigation of pH and SDBS on enhancement of thermal conductivity in nanofluids[J].Chemical Phy-sics Letters,2009,470(1-3):107. 36 Peng H, Ding G, Hu H. Effect of surfactant additives on nucleate pool boiling heat transfer of refrigerant-based nanofluid[J].Experimental Thermal and Fluid Science,2011,35(6):960. 37 Kathiravan R, Kumar R, Gupta A, et al. Preparation and pool boi-ling characteristics of silver nanofluids over a flat plate heater[J].Heat Transfer Engineering,2012,33(2):69. 38 Kumar S A, Meenakshi K S, Narashimhan B R V, et al. Synthesis and characterization of copper nanofluid by a novel one-step method[J].Materials Chemistry and Physics,2009,113(1):57. 39 Robertis E D, Cosme E H H, Neves R S, et al. Application of the modulated temperature differential scanning calorimetry technique for the determination of the specific heat of copper nanofluids[J].Applied Thermal Engineering,2012,41(41):10. 40 Xuan Y, Qiang L. Heat transfer enhancement of nanofluids[J].International Journal of Heat and Fluid Flow,2000,21(1):58. 41 Yu W, Xie H, Chen L, et al. Investigation on the thermal transport properties of ethylene glycol-based nanofluids containing copper na-noparticles[J].Powder Technology,2010,197(3):218. 42 Liu M S, Lin C C, Tsai C Y, et al. Enhancement of thermal conductivity with Cu for nanofluids using chemical reduction method[J].International Journal of Heat and Mass Transfer,2006,49(17-18):3028. 43 Eastman J A, Choi S U S, Li S, et al. Anomalously increased effective thermal conductivities of ethylene glycol-based nanofluids containing copper nanoparticles[J].Applied Physics Letters,2001,78(6):718. 44 Sinha K, Kavlicoglu B, Liu Y, et al. A comparative study of thermal behavior of iron and copper nanofluids[J].Journal of Applied Phy-sics,2009,106(6):064307. 45 Yu W, Yu W, Xie H, et al. Thermal conductivity of composite materials containing copper nanowires[J].Journal of Nanomaterials,2016,2016:8. 46 Zhang Y N, Liu N, You L T, et al. Research progress in the effect of surfactants on the characteristics of H2O-based nanofluids[J].Chemical Industry and Engineering Progress,2015,34(4):903(in Chinese). 张亚楠,刘妮,由龙涛,等.表面活性剂对水基纳米流体特性影响的研究进展[J].化工进展,2015,34(4):903. 47 Wang X J, Li X F. Influence of pH on nanofluids’ viscosity and thermal conductivity[J].Chinese Physics Letters,2009,26(5):183. 48 Lee D, Kim J W, Kim B G. A new parameter to control heat transport in nanofluids: Surface charge state of the particle in suspension[J].Journal of Physical Chemistry B,2006,110(9):4323. 49 Namburu P K, Das D K, Tanguturi K M, et al. Numerical study of turbulent flow and heat transfer characteristics of nanofluids consi-dering variable properties[J].International Journal of Thermal Sciences,2009,48(2):290. 50 Devendiran D K, Amirtham V A. A review on preparation, characterization, properties and applications of nanofluids[J].Renewable and Sustainable Energy Reviews,2016,60:21. 51 He Q, Wang S, Zeng S, et al. Experimental investigation on photothermal properties of nanofluids for direct absorption solar thermal energy systems[J].Journal of Refrigeration,2014,73(5):150. 52 Wei W. Radiative properties of nanofluids and its utilization in solar thermal power systems[D].Hangzhou: Zhejiang University,2013(in Chinese). 魏葳.纳米流体的辐射特性及其在太阳能热利用中的应用研究[D].杭州:浙江大学,2013. 53 Mao L B, Zhang R Y, Ke X F, et al. Photo-thermal properties of nanofluid-based solar collector[J].Acta Energlae Solaris Sinica,2009,30(12):1647(in Chinese). 毛凌波,张仁元,柯秀芳,等.纳米流体太阳集热器的光热性能研究[J].太阳能学报,2009,30(12):1647. 54 Chen H, Zhu Q Z, Li J D, et al. Study of the performance of a direct absorption solar collector using nanofluids as working fluids[J].Acta Energlae Solaris Sinica,2016,37(7):1845(in Chinese). 陈慧,朱群志,李金斗,等.纳米流体为工质的直吸式太阳集热器性能研究[J].太阳能学报,2016,37(7):1845. 55 Zamzamian A, Keyanpour Rad M, Kiani Neyestani M, et al. An experimental study on the effect of Cu-synthesized/EG nanofluid on the efficiency of flat-plate solar collectors[J].Renewable Energy,2014,71:658. |
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