Polyether ether ketone (PEEK) is a high-performance, semi-crystalline thermoplastic that is used in a wide range of engineering applications, including some structural components of aircraft. The design of new PEEK-based materials requires a precise understanding of the multiscale structure and behavior of semi-crystalline PEEK. Molecular Dynamics (MD) modeling can efficiently predict bulk-level properties of single phase polymers, and micromechanics can be used to homogenize those phases based on the overall polymer microstructure. In this study, MD modeling was used to predict the mechanical properties of the amorphous and crystalline phases of PEEK. The hierarchical microstructure of PEEK, which combines the aforementioned phases, was modeled using a multiscale modeling approach facilitated by NASA's MSGMC. The bulk mechanical properties of semi-crystalline PEEK predicted using MD modeling and MSGMC agree well with vendor data, thus validating the multiscale modeling approach.
The compatibility of both bulk and porous silicon at the subcutaneous site has been assessed for the first time, following ISO standard procedures. The in-vivo responses to implantation were monitored in the guinea pig and histopathological reactions evaluated at 1, 4, 12 and 26 weeks. Attention is focused here on the histological assessment protocols used, and the results demonstrating in-vivo evidence for good tissue compatibility, and porous Si bioactivity with regards calcification.
Self-assembly characterizes the fundamental
basis toward realizing
the formation of highly ordered hierarchical heterostructures. A systematic
approach toward the supramolecular self-assembly of free-standing
guanine nucleobases and the role of graphene as a substrate in directing
the monolayer assembly are investigated using the molecular dynamics
simulation. We find that the free-standing bases in gas phase aggregate
into clusters dominated by intermolecular H-bonds, whereas in solvent,
substantial screening of intermolecular interactions results in π-stacked
configurations. Interestingly, graphene facilitates the monolayer
assembly of the bases mediated through the base–substrate π–π
stacking. The bases assemble in a highly compact network in gas phase,
whereas in solvent, a high degree of immobilization is attributed
to the disruption of intermolecular interactions. Graphene-induced
stabilization/aggregation of free-standing guanine bases appears as
one of the prerequisites governing molecular ordering and assembly
at the solid/liquid interface. The results demonstrate an interplay
between intermolecular and π-stacking interactions, central
to the molecular recognition, aggregation dynamics, and patterned
growth of functional molecules on two-dimensional nanomaterials.
The
stability and electronic properties of gold (Au) clusters interacting
with the amino acids alanine (Ala) and tryptophan (Trp) in their canonical
and zwitterionic configurations were investigated using first-principles
density functional theory (DFT). We found that the geometrical structures
of the Au clusters and the polarities of the amino acids determine
the nature of the interactions in the gas and solvent phases. In the
gas phase, the Au8 (D
4h
) and Au20 (T
d
) clusters prefer single-site interactions through the amine
group for the canonical amino acids, whereas in the solvent phase,
the carboxylic site is preferred for the zwitterionic amino acids.
The limited screening of the intermolecular interactions introduced
by the solvent medium for the canonical forms of Ala and Trp conjugated
with the Au
n
complexes suggests that the
bonding is primarily covalent in nature. The screening is significantly
more pronounced for the zwitterionic complexes for which the electrostatic
interactions dominate. The cluster sizes and configurations define
the extent of the interactions and the overall stability of the complexes.
The structures of the Au
n
clusters govern
the charge distribution and electrostatic potential, directing the
selectivity toward the preferential binding sites with the Ala and
Trp amino acids.
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