Preparation and Thermal Properties of Grafted CNTs Composites 被引量：4

Preparation and Thermal Properties of Grafted CNTs Composites

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摘要 Oleylamine （G18） and octanol （G8） were grafted onto the surfaces of the multi-walled carbon nanotubes （CNTs）. The grafted CNTs were dispersed into palmitic acid （PA） and paraffin wax （PW） to prepare phase change composites. The heat storage/retrieval experiments showed that the composites kept stable after repeating melting and solidification for 80 times. The structure of the G18-CNT/PA and G8-CNT/PA was homogenous compared with the pristine CNT （P-CNT）/PA. The latent heat capacity （Ls） of solid liquid phase change of G18-CNT/PW was higher than that of PW while those of the G8-CNTI/PW and P-CNT/PW were lower than that of PW. Compared with PA, all PA based composites with both P-CNTs and grafted CNTs decreased Ls evidently. The Ls values of GI8-CNT composites in both matrices were higher than that of the counterparts of G8-CNT. The thermal conductivities of all the PA based composites in the study were higher than that of PA, as well as those of all the PW based composites. However, the thermal conductivities of the GI8-CNT composites in both matrixes were lower than those of the G8-CNT composites in both matrixes at all measured temperatures. Oleylamine （G18） and octanol （G8） were grafted onto the surfaces of the multi-walled carbon nanotubes （CNTs）. The grafted CNTs were dispersed into palmitic acid （PA） and paraffin wax （PW） to prepare phase change composites. The heat storage/retrieval experiments showed that the composites kept stable after repeating melting and solidification for 80 times. The structure of the G18-CNT/PA and G8-CNT/PA was homogenous compared with the pristine CNT （P-CNT）/PA. The latent heat capacity （Ls） of solid liquid phase change of G18-CNT/PW was higher than that of PW while those of the G8-CNTI/PW and P-CNT/PW were lower than that of PW. Compared with PA, all PA based composites with both P-CNTs and grafted CNTs decreased Ls evidently. The Ls values of GI8-CNT composites in both matrices were higher than that of the counterparts of G8-CNT. The thermal conductivities of all the PA based composites in the study were higher than that of PA, as well as those of all the PW based composites. However, the thermal conductivities of the GI8-CNT composites in both matrixes were lower than those of the G8-CNT composites in both matrixes at all measured temperatures.

作者 Jifen Wang Huaqing Xie Zhong Xin

机构地区 State Key Laboratory of Chemical Engineering School of Urban Development and Environmental Engineering

出处《Journal of Materials Science & Technology》 SCIE EI CAS CSCD 2011年第3期233-238,共6页 材料科学技术（英文版）

基金 supported by the National Natural Science Foundation of China (Nos. 50876058 and 20876042) Program for New Century Excellent Talents in University(NCET-10-883) Program for Professor of Special Appointment (Eastern Scholar) at Shanghai Institutions of Higher Learning

关键词 Carbon nanotube （CNT） GRAFTING Phase change composite Thermal property Carbon nanotube （CNT） Grafting Phase change composite Thermal property

分类号 TB383 [一般工业技术—材料科学与工程] TB33 [一般工业技术—材料科学与工程]

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Preparation and Thermal Properties of Grafted CNTs Composites 被引量：4

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