Sacrificial bonds and hidden length: unraveling molecular mesostructures in tough materials
Sacrificial bonds and hidden length: unraveling molecular mesostructures in tough materials
Sacrificial bonds and hidden length in structural molecules and composites have been found to greatly increase the fracture toughness of biomaterials by providing a reversible, molecular-scale energy-dissipation mechanism. This mechanism relies on the energy, of order 100 eV, needed to reduce entropy and increase enthalpy as molecular segments are stretched after being released by the breaking of weak bonds, called sacrificial bonds. This energy is relatively large compared to the energy needed to break the polymer backbone, of order a few eV. In many biological cases, the breaking of sacrificial bonds has been found to be reversible, thereby additionally providing a "self-healing" property to the material. Due to the nanoscopic nature of this mechanism, single molecule force spectroscopy using an atomic force microscope has been a useful tool to investigate this mechanism. Especially when investigating natural molecular constructs, force versus distance curves quickly become very complicated. In this work we propose various types of sacrificial bonds, their combination, and how they appear in single molecule force spectroscopy measurements. We find that by close analysis of the force spectroscopy curves, additional information can be obtained about the molecules and their bonds to the native constructs.
1411-1418
Fantner, Georg E.
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Oroudjev, Emin
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Schitter, Georg
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Golde, Laura S.
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Thurner, Philipp J.
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Finch, Marquesa M.
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Turner, Patricia
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Gutsmann, Thomas
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Morse, Daniel E.
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Hansma, Helen
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Hansma, Paul K.
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February 2006
Fantner, Georg E.
e95e5469-568d-4c76-843c-bb8a4f6153df
Oroudjev, Emin
ecc16bff-423f-48b7-b232-4ba24dfe554c
Schitter, Georg
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Golde, Laura S.
44b05dda-284c-4e61-825c-d533fca8993b
Thurner, Philipp J.
ab711ddd-784e-48de-aaad-f56aec40f84f
Finch, Marquesa M.
f46e95a9-2f6c-466c-8fc0-edc7e0f9d4fc
Turner, Patricia
fb040b75-606d-4dba-b4f7-1e00a4d348ed
Gutsmann, Thomas
01def759-e7f8-432d-9f14-5af3e5f9b8eb
Morse, Daniel E.
aaa0e018-1bd0-41f3-8ff8-b8a22015d742
Hansma, Helen
c6670604-2217-4f90-aaaa-58fd8d05659c
Hansma, Paul K.
aeab95c4-0f23-4690-8302-72db3316215d
Fantner, Georg E., Oroudjev, Emin, Schitter, Georg, Golde, Laura S., Thurner, Philipp J., Finch, Marquesa M., Turner, Patricia, Gutsmann, Thomas, Morse, Daniel E., Hansma, Helen and Hansma, Paul K.
(2006)
Sacrificial bonds and hidden length: unraveling molecular mesostructures in tough materials.
Biophysical Journal, 90 (4), .
(doi:10.1529/biophysj.105.069344).
Abstract
Sacrificial bonds and hidden length in structural molecules and composites have been found to greatly increase the fracture toughness of biomaterials by providing a reversible, molecular-scale energy-dissipation mechanism. This mechanism relies on the energy, of order 100 eV, needed to reduce entropy and increase enthalpy as molecular segments are stretched after being released by the breaking of weak bonds, called sacrificial bonds. This energy is relatively large compared to the energy needed to break the polymer backbone, of order a few eV. In many biological cases, the breaking of sacrificial bonds has been found to be reversible, thereby additionally providing a "self-healing" property to the material. Due to the nanoscopic nature of this mechanism, single molecule force spectroscopy using an atomic force microscope has been a useful tool to investigate this mechanism. Especially when investigating natural molecular constructs, force versus distance curves quickly become very complicated. In this work we propose various types of sacrificial bonds, their combination, and how they appear in single molecule force spectroscopy measurements. We find that by close analysis of the force spectroscopy curves, additional information can be obtained about the molecules and their bonds to the native constructs.
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Published date: February 2006
Identifiers
Local EPrints ID: 48815
URI: http://eprints.soton.ac.uk/id/eprint/48815
ISSN: 0006-3495
PURE UUID: b7e8d867-a508-43f0-95a0-02fdefa8c0ec
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Date deposited: 15 Oct 2007
Last modified: 15 Mar 2024 09:50
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Contributors
Author:
Georg E. Fantner
Author:
Emin Oroudjev
Author:
Georg Schitter
Author:
Laura S. Golde
Author:
Marquesa M. Finch
Author:
Patricia Turner
Author:
Thomas Gutsmann
Author:
Daniel E. Morse
Author:
Helen Hansma
Author:
Paul K. Hansma
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