|
OALib Journal期刊
ISSN: 2333-9721
费用:99美元
|
|
|
|
聚乳酸/醋酸纤维素复合多孔超细纤维的制备
DOI: 10.3724/SP.J.1105.2013.13051, PP. 1312-1318
Keywords: 静电纺丝,聚乳酸,醋酸纤维素,多孔纤维
Abstract:
以DMF/二氯甲烷(DCM)或丙酮/DCM为溶剂,通过静电纺丝制备了直径为0.89~1.21μm、孔径大小为61~123nm的PLLA/CA复合多孔超细纤维.探讨溶剂组成、溶剂比例、聚合物浓度和环境湿度对纤维直径、孔径大小和比表面积的影响.通过SEM观察纤维形貌及其孔径大小,通过N2吸附-脱附曲线计算多孔纤维的比表面积.实验结果表明,相比较丙酮/DCM和DMF/DCM溶剂,以丙酮/DCM为溶剂所制备的纤维孔径小、比表面积大.主要因为丙酮/DCM沸点低,溶剂挥发过程越剧烈,聚合物温度降低越多,热致相分离越剧烈,越有利于形成密集的孔.且混合溶剂中随着DCM比例的增加,纤维上的孔密度和比表面积都增加.聚合物浓度从3%增加到15%,形貌从"多孔颗粒"过度到"珠-串多孔纤维"直到最后生成均匀无珠多孔纤维.纤维上纳米孔的形成主要是由于静电纺丝过程中溶剂的快速挥发引起纤维表面温度急剧降低导致热致相分离而产生多孔结构.且纤维中形成了相互贯穿的三维连通孔.因此可以判断此体系主要是旋节相分离机理进行相分离.
| [1] | 1 Liu R L,Ye H Y, Xiong X P,Liu H Q.Mater Chem Phys,2010,121(3):432~439
|
| [2] | 2 Amarjargal A,Tijing L D,Ruelo M T G,Lee D H,Kim C S.Mater Chem Phys,2012,135(2-3):2772~2781
|
| [3] | 3 Zhang Y,He X,Li J,Miao Z,Huang F.Sens Actuators,B:Chem,2008,132(1):67~73
|
| [4] | 4 Zhou C S,Shi Y L,Ding X D,Li M,Luo J J,Lu Z Y,Xiao D.Anal Chem,2012,85(2):1171~1176
|
| [5] | 5 Dotti F,Varesano A,Montarsolo A,Aluigi A,Tonin C,Mazzuchetti G.J Ind Text,2007,37(2):151~162
|
| [6] | 6 Kaur S,Sundarrajan S,Rana D,Matsuura T,Ramakrishna S.J Memb Sci,2012,392:101~111
|
| [7] | 7 Wu M Y,Wang Q Y,Liu X Q,Liu H Q.Carbon,2013,51:335~345
|
| [8] | 8 Liao Yuee(缪月娥),Liu Tianxi(刘天西).Acta Polymerica Sinica(高分子学报),2012,(8):801~811
|
| [9] | 12 Jin L,Feng Z Q,Zhu M L,Wang T,Leach M K,Jiang Q A.J Biomed Nanotech,2012,8(5):779~785
|
| [10] | 13 Chen L,Qiu X,Xie Z,Hong Z,Sun J,Chen X,Jing X.Carbohydr Polym,2006,65(1):75~80
|
| [11] | 14 Helenius G,Bckdahl H,Bodin A,Nannmark U,Gatenholm P,Risberg B.J Biomed Mater Res A 2006,76A(2):431~438
|
| [12] | 16 Hou J,Sun X,Zhang W,Li L,Teng H.Chinese J Polym Sci,2012,30(6):1~7
|
| [13] | 21 Liu Ruilai(刘瑞来),Han Jing(韩静),Chen Xiujuan(陈秀娟),Lei Shenghong(雷声宏),Liu Haiqing(刘海清),Acta Polymerica Sinica(高分子学报),2012,(3):291~298
|
| [14] | 22 Sun Hang(孙航),Wu Lixin(吴立新).Progress in Chemsitry(化学进展),2010,22(9):1784~1798
|
| [15] | 23 Yang F,Murugan R,Ramakrishna S,Wang X,Ma Y X,Wang S.Biomaterials,2004,25(10):1891~1900
|
| [16] | 24 Nam Y S,Park T G.J Biomed Mater Res,1999,47(1):8~17
|
| [17] | 25 Feng L,Li S,Li H,Zhai J,Song Y,Jiang L,Zhu D.Angew Chem,2002,114(7):1269~1271
|
| [18] | 9 Meng Z X,Zheng W,Li L,Zheng Y F.Mater Sci Eng C,2010,30(7):1014~1021
|
| [19] | 10 McCann J T,Li D,Xia Y N.J Mater Chem,2005,15(7):735~738
|
| [20] | 11 Cont L,Grant D,Scotchford C,Todea M,Popa C.J Biomater Appl,2013,27(6):707~716
|
| [21] | 15 Rubenstein D A,Venkitachalam S M,Zamfir D,Wang F,Lu H B,Frame M D,Yin W.J Biomater Sci,2010,21(13),1713~1736
|
| [22] | 17 Qi Z,Yu H,Chen Y,Zhu M.Mater Lett,2009,63:415~418
|
| [23] | 18 Celebioglu A,Uyar T.Mater Lett,2011,65(14):2291~2294
|
| [24] | 19 Cao Shengguang(曹胜光),Hu Binghuan(胡炳环),Liu Haiqing(刘海清).Acta Polymerica Sinica(高分子学报),2010,(10):1193~1198
|
| [25] | 20 Wang Jiangnan(王江南),Liu Haiqing(刘海清).Polymer Materials Science and Enginnering(高分子材料科学与工程),2011,27(5):133~136
|
Full-Text
|
|
Contact Us
service@oalib.com QQ:3279437679 
WhatsApp +8615387084133
|
|
