Organic
crystals are of primary importance in pharmaceuticals,
functional materials, and biological systems; however, organic crystallization
mechanisms are not well-understood. It has been recognized that “nonclassical”
organic crystallization from solution involving transient amorphous
precursors is ubiquitous. Understanding how these precursors evolve
into crystals is a key challenge. Here, we uncover the crystallization
mechanisms of two simple aromatic compounds (perylene diimides), employing
direct structural imaging by cryogenic electron microscopy. We reveal
the continuous evolution of density, morphology, and order during
the crystallization of very different amorphous precursors (well-defined
aggregates and diffuse dense liquid phase). Crystallization starts
from initial densification of the precursors. Subsequent evolution
of crystalline order is gradual, involving further densification concurrent
with optimization of molecular ordering and morphology. These
findings may have implications for the rational design of organic
crystals.
The eyes of some aquatic animals form images through reflective optics. Shrimp, lobsters, crayfish, and prawns possess reflecting superposition compound eyes, composed of thousands of square-faceted eye units (ommatidia). Mirrors in the upper part of the eye (the distal mirror) reflect light collected from many ommatidia onto the photosensitive elements of the retina, the rhabdoms. A second reflector, the tapetum, underlying the retina, back-scatters dispersed light onto the rhabdoms. Using microCT and cryo-SEM imaging accompanied by in situ micro-X-ray diffraction and micro-Raman spectroscopy, we investigated the hierarchical organization and materials properties of the reflective systems at high resolution and under close-to-physiological conditions. We show that the distal mirror consists of three or four layers of plate-like nanocrystals. The tapetum is a diffuse reflector composed of hollow nanoparticles constructed from concentric lamellae of crystals. Isoxanthopterin, a pteridine analog of guanine, forms both the reflectors in the distal mirror and in the tapetum. The crystal structure of isoxanthopterin was determined from crystal-structure prediction calculations and verified by comparison with experimental X-ray diffraction. The extended hydrogen-bonded layers of the molecules result in an extremely high calculated refractive index in the H-bonded plane, = 1.96, which makes isoxanthopterin crystals an ideal reflecting material. The crystal structure of isoxanthopterin, together with a detailed knowledge of the reflector superstructures, provide a rationalization of the reflective optics of the crustacean eye.
The generation of a current through interaction between bacteria and electrodes has been explored by various methods. We demonstrate the attachment of living bacteria through a surface displayed redox enzyme, alcohol dehydrogenase II. The unnatural amino acid para-azido-L-phenylalanine was incorporated into a specific site of the displayed enzyme, facilitating electron transfer between the enzyme and an electrode. In order to attach the bacteria carrying the surface displayed enzyme to a surface, a linker containing an alkyne and a thiol moiety on opposite ends was synthesized and attached to the dehydrogenase site specifically through a copper(I)-catalyzed azide-alkyne cycloaddition reaction. Using this approach we were able to covalently link bacteria to gold-coated surfaces and to gold nanoparticles, while maintaining viability and catalytic activity. We show the performance of a biofuel cell using these modified bacteria at the anode, which resulted in site-specific dependent fuel cell performance for at least a week. This is the first example of site-specific attachment of a true living biohybrid to inorganic material.
Facile molecular self-assembly affords a new family of organic nanocrystals that, unintuitively, exhibit a significant nonlinear optical response (second harmonic generation, SHG) despite the relatively small molecular dipole moment of the constituent molecules. The nanocrystals are self-assembled in aqueous media from simple monosubstituted perylenediimide (PDI) molecular building blocks. Control over the crystal dimensions can be achieved via modification of the assembly conditions. The combination of a simple fabrication process with the ability to generate soluble SHG nanocrystals with tunable sizes may open new avenues in the area of organic SHG materials.
Organic crystal nucleation and growth are complex processes
that
often do not fit into the framework of the existing crystallization
theories. We investigated a crystal growth mechanism of an organic
dye, perylene diimide, using high-resolution cryogenic transmission
electron microscopy and optical spectroscopy. The elucidated mechanism
involves classical (monomer attachments) and nonclassical pathways,
exhibiting a self-assembly sequence where all steps are interconnected.
It starts from the assembly of molecular π-stacks that are initially
disordered. They gradually optimize their structure, rigidify, and
interact to form crystalline domains. The latter further evolve via
the addition of individual molecules, and crystal fusion (via oriented
attachment). All the observed supramolecular transformations are connected
and follow a clear hierarchy starting from the molecular-scale interactions.
The elucidation of the complex pathway of organic crystallization
as a series of coordinated supramolecular transformations at multiple
scales conceptually advances the understanding of order evolution
in organic matter.
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