李勍,陈文帅,于海鹏,等. 2013.纤维素纳米纤维增强聚合物复合材料研究进展.林业科学, 49(8):126-131. (Li Q, Chen W S, Yu H P, et al. 2013. Cellulose nanofiber reinforced polymer nanocomposites:a short review.Scientia Silvae Sinicae, 49(8):126-131.[in Chinese]) 李伟,王锐,刘守新. 2010.纳米纤维素的制备.化学进展, 22(10):2060-2070. (Li W, Wang R, Liu S X. 2010. Preparation of nanocrystalline cellulose. Progress in Chemistry, 22(10):2060-2070.[in Chinese]) 卿彦,蔡智勇,吴义强,等. 2012.纤维素纳米纤丝研究进展.林业科学, 48(7):145-152. (Qing Y, Cai Z Y, Wu Y Q, et al. 2010. Study progress on cellulose nanofibril. Scientia Silvae Sinicae, 48(7):145-152.[in Chinese]) 王学昭,沈容,路阳,等. 2010.极性分子型电流变液导电机理研究.物理学报, 59(10):7144-7148. (Wang X Z, Shen R, Lu Y, et al. 2010. Polar molecules based ER fluid conductivity mechanism. Acta Physica Sinica, 59(10):7144-7148.[in Chinese]) 魏克湘,孟光,朱石沙. 2005.电流变液在流体控制中的应用.功能材料与器件学报, 11(1):97-102. (Wei K X, Meng G, Zhu S S. 2005. ER fluid in the fluid control application. Functional Materials and Devices, 11(1):97-102.[in Chinese]) 徐顺香,瞿伟廉,袁润章. 2005.采用电流变阻尼器汽车悬架的半主动控制研究.汽车工程, 26(5):593-595. (Xu S X, Qu W L, Yuan R Z. 2005. Semi-active control study of electrorheological dampers automobile suspension. Automotive Engineering, 26(5):593-595.[in Chinese]) 赵晓鹏,尹剑波,向礼琴. 2009.包覆表面活性剂的TiO2电流变液.材料研究学报, 15(3):308-312. (Zhao X P, Yin J B, Xiang L Q. 2009. Electrorheological behavior of the suspensions of surfactant coated TiO2. Journal of Materials Research, 15(3):308-312.[in Chinese]) 赵艳,王宝祥,赵晓鹏. 2006.改性纳米氧化钛电流变液的制备及其特性.复合材料学报, 23(3):96-102. (Zhao Y, Wang B X, Zhao X P. 2006. Preparation and properties of modified nano-titania electrorheological fluid. Composite Materials, 23(3):96-102.[in Chinese]) Block H, Kelly J P, Qin A, et al. 1990. Materials and mechanisms in electrorheology. Langmuir, 6(1):6-14. Choi C S, Park S J, Choi H J. 2007. Carbon nanotube/polyaniline nanocomposites and their electrorheological characteristics under an applied electric field. Current Applied Physics, 7(4):352-355. Choi Y, Sprecher A F, Conrad H. 1992. Response of electrorheological fluid-filled laminate composites to forced vibration. Journal of Intelligent Material Systems and Structures, 3(1):17-29. Hao T. 2002. Electrorheological suspensions. Advances in Colloid and Interface Science, 97(1):1-35. Kim S G, Kim J W, Jang W H, et al. 2001. Electrorheological characteristics of phosphate cellulose-based suspensions. Polymer, 42(11):5005-5012. Lu K, Shen R, Wang X, et al. 2005. The electrorheological fluids with high shear stress. International Journal of Modern Physics B, 19(07n09):1065-1070. Ma H, Wen W, Tam W Y, et al. 2003. Dielectric electrorheological fluids:theory and experiment. Advances in Physics, 52(4):343-383. Rejon L, Ramírez A, Paz F, et al. 2002. Response time and electrorheology of semidiluted gellan, xanthan and cellulose suspensions. Carbohydrate Polymers, 48(4):413-421. Shen R, Wang X, Lu Y, et al. 2009. Polar-molecule-dominated electrorheological fluids featuring high yield stresses. Advanced Materials, 21(45):4631-4635. Stangroom J E. 1983. Electrorheological fluids. Physics in Technology, 14(6):290. Wen W, Huang X, Yang S, et al. 2003. The giant electrorheological effect in suspensions of nanoparticles. Nature Materials, 2(11):727-730. Zhang S, Winter W T, Stipanovic A J. 2005. Water-activated cellulose-based electrorheological fluids. Cellulose, 12(2):135-144. |