You are not logged in.

Architecture of a biocompatible supramolecular material by supersaturation-driven fabrication of fiber network

Li, Jing-Liang, Liu, Xiang-Yang, Wang, Rong-Yao and Xiong, Jun-Ying 2005, Architecture of a biocompatible supramolecular material by supersaturation-driven fabrication of fiber network, The journal of physical chemistry b, vol. 109, no. 51, pp. 24231-24235, doi: 10.1021/jp054676y.

Attached Files
Name Description MIMEType Size Downloads

Title Architecture of a biocompatible supramolecular material by supersaturation-driven fabrication of fiber network
Author(s) Li, Jing-LiangORCID iD for Li, Jing-Liang orcid.org/0000-0003-0709-2246
Liu, Xiang-Yang
Wang, Rong-Yao
Xiong, Jun-Ying
Journal name The journal of physical chemistry b
Volume number 109
Issue number 51
Start page 24231
End page 24235
Publisher American Chemical Society
Place of publication Washington D.C.
Publication date 2005-12-06
ISSN 1520-6106
1520-5207
Summary The architecture of a biocompatible organogel formed by gelation of a small molecule organic gelator, N-lauroyl-l-glutamic acid di-n-butylamide, in isostearyl alcohol was investigated based on a supersaturation-driven crystallographic mismatch branching mechanism. By controlling the supersaturation of the system, the correlation length that determines the mesh size of the fiber network was finely tuned and the rheological properties of the gel were engineered. This approach is of considerable significance for many gel-based applications, such as controlled release of drugs that requires precise control of the mesh size. A direct cryo-transmission electron microscopy (TEM) imaging technique capable of preserving the network structure was used to visualize its nanostructure.
Language eng
DOI 10.1021/jp054676y
Field of Research 091205 Functional Materials
030603 Colloid and Surface Chemistry
Socio Economic Objective 970110 Expanding Knowledge in Technology
HERDC Research category C1.1 Refereed article in a scholarly journal
Copyright notice ©2005, American Chemical Society
Persistent URL http://hdl.handle.net/10536/DRO/DU:30039295

Document type: Journal Article
Collection: Centre for Material and Fibre Innovation
Connect to link resolver
 
Unless expressly stated otherwise, the copyright for items in DRO is owned by the author, with all rights reserved.

Versions
Version Filter Type
Citation counts: TR Web of Science Citation Count  Cited 59 times in TR Web of Science
Scopus Citation Count Cited 59 times in Scopus
Google Scholar Search Google Scholar
Access Statistics: 220 Abstract Views, 0 File Downloads  -  Detailed Statistics
Created: Mon, 24 Oct 2011, 14:16:35 EST

Every reasonable effort has been made to ensure that permission has been obtained for items included in DRO. If you believe that your rights have been infringed by this repository, please contact drosupport@deakin.edu.au.