RT Journal Article ID 2df4b3c8009434e6 A1 Bertaud, Jeremie A1 Qin, Zhao A1 Buehler, Markus J. T1 Atomistically Informed Mesoscale Model of Alpha-Helical Protein Domains JF International Journal for Multiscale Computational Engineering JO JMC YR 2009 FD 2009-06-17 VO 7 IS 3 SP 237 OP 250 K1 hierarchical material K1 nanomechanics K1 materiomics K1 biological protein materials K1 fracture K1 deformation K1 experiment K1 simulation K1 multiscale modeling AB Multiscale mechanical properties of biological protein materials have been the focal point of extensive investigations over the past decades. In this article, we present the development of a mesoscale model of alpha-helical (AH) protein domains, key constituents in a variety of biological materials, including cells, hair, hooves, and wool. Our model, derived solely from results of full atomistic simulations, is suitable to describe the deformation and fracture mechanics over multiple orders of magnitude in time- and length scales. After validation of the mesoscale model against atomistic simulation results, we present two case studies, in which we investigate, first, the effect of the length of an AH protein domain on its strength properties, and second, the effect of the length of two parallel AH protein domain arrangement on its shear strength properties and deformation mechanisms. We find that longer AHs feature a reduced tensile strength, whereas the tensile strength is maximized for ultrashort protein structures. Moreover, we find that the shearing of two parallel AHs engenders sliding, rather than AH unfolding, and that the shear strength does not significantly depend on the length of the two AHs. PB Begell House LK https://www.dl.begellhouse.com/journals/61fd1b191cf7e96f,0dfc4ca83265a62d,2df4b3c8009434e6.html