TY - GEN
T1 - Spider silk morphology for responsive materials
AU - Guan, Juan
AU - Porter, David
AU - Vollrath, Fritz
PY - 2013
Y1 - 2013
N2 - This study reveals that an "old" mechanism for shape memory in oriented polymers is in fact just one separate contribution for "supercontraction" in Nephila spider major ampulate silks. When Nephila spider silks are in contact with liquid water, they "super"- contract up to 28% of the original stretched length. However, we discovered that under glass transition conditions these silks only relax with a maximum shrinkage of 13%, and this phenomenon is defined as Tg-contraction. Structural components permanent order (PO), permanent disorder (PD), meta order (MO) and meta disorder (MD) were proposed from the primary amino-acid sequence of the silk protein to explain morphological changes in the two contraction phenomena: MD contributes 13% of the full supercontraction and contributes to Tg-contraction; whereas MO (the proline-containing motifs) contributes the rest for the full super-contraction and does not contribute to Tg-contraction. The morphology in Nephila spider silk structure suggests two separate mechanisms to generate the shape memory effect in synthetic polymers.
AB - This study reveals that an "old" mechanism for shape memory in oriented polymers is in fact just one separate contribution for "supercontraction" in Nephila spider major ampulate silks. When Nephila spider silks are in contact with liquid water, they "super"- contract up to 28% of the original stretched length. However, we discovered that under glass transition conditions these silks only relax with a maximum shrinkage of 13%, and this phenomenon is defined as Tg-contraction. Structural components permanent order (PO), permanent disorder (PD), meta order (MO) and meta disorder (MD) were proposed from the primary amino-acid sequence of the silk protein to explain morphological changes in the two contraction phenomena: MD contributes 13% of the full supercontraction and contributes to Tg-contraction; whereas MO (the proline-containing motifs) contributes the rest for the full super-contraction and does not contribute to Tg-contraction. The morphology in Nephila spider silk structure suggests two separate mechanisms to generate the shape memory effect in synthetic polymers.
UR - https://www.scopus.com/pages/publications/84892393777
U2 - 10.1557/opl.2013.336
DO - 10.1557/opl.2013.336
M3 - 会议稿件
AN - SCOPUS:84892393777
SN - 9781605114750
T3 - Materials Research Society Symposium Proceedings
SP - 197
EP - 202
BT - Biomimetic, Bio-Inspired and Self-Assembled Materials for Engineered Surfaces and Applications
T2 - 2012 MRS Fall Meeting
Y2 - 25 November 2012 through 30 November 2012
ER -