A dynamic surface pattern with a topography and fluorescence in response to environmental stimulus can enable information recording, hiding, and reading. Such patterns are therefore widely used in information security and anticounterfeiting. Here, we demonstrate a dynamic dual pattern using a supramolecular network comprising a copolymer containing pyridine (P4VP-nBA-S) and hydroxyl distyrylpyridine (DSP-OH) as the skin layer for bilayer wrinkling systems, in which both the wrinkle morphology and fluorescence color can be simultaneously regulated by visible light-triggered isomerization of DSP-OH, or acids. Acid-induced protonation of pyridines can dynamically regulate the cross-linking of the skin layer through hydrogen bonding, and the fluorescence of DSP-OH. On selective irradiation with 450 nm visible light or acid treatment, the resulting hierarchical patterned surface becomes smooth and wrinkled reversibly, and simultaneously its fluorescence changes dynamically from blue to orange-red. The smart surfaces with dynamic hierarchical wrinkles and fluorescence can find potential application in anticounterfeiting.
Dynamic micro-/nanowrinkle
patterns with response to multienvironmental
stimuli can offer a facile method for on-demand regulation of surface
properties, thus allowing for generation of a smart surface. Here
a practical yet robust strategy is described to fabricate redox, light
and thermal responsive wrinkle by building dynamic double interpenetrating
polymer network (IPN) as the top layer for a typical bilayer system.
IPNs were constructed through the photochemical reaction of a mixture
comprised of light-sensitive anthracene-containing polymer (PAN) and
redox-sensitive disulfide-containing diacrylate monomer (DSDA). Thanks
to the dynamic covalent reversible C–C bond in PAN and S–S
bond in DSDA, the morphology of wrinkled surface not only can be reversibly
and precisely (micrometer scale) tailored to all kinds of complicated
hierarchical pattern permanently, but also can be controlled temporarily
by irradiation of near-infrared light (NIR). A sine wave model is
proposed to investigate the dynamics of real-time reversible wrinkle evolution. This general approach based on IPN
allows independent multistimuli control over wettability and optical
properties on the wrinkled surface, thus, presents a considerable
alternative to implement a smart surface.
Pattern technology plays an important role in the generation of microstructures with different functionalities and morphologies. In this report, a straightforward and versatile strategy is presented for spatially regulating the growth of a microstructure on a surface by the photodimerization of maleimide (MI). Upon exposure of ultraviolet (UV) light, photodimerization of MI in a film comprising furan‐grafted polymer and bismaleimide (BMI) produces a chemical gradient, which can drive the diffusion of BMI from the unexposed to the exposed region and from the bottom to the surface, resulting in the growth of micropatterns. Sequential crosslinking induced by the Diels–Alder reaction between MI and furan maintains the stability of pattern shape. Theoretical modeling with reaction‐diffusion equations reveal that as photodimerization moves the system far from thermodynamic equilibrium, the formation of a chemical potential gradient requires the redistribution of matter, resulting in the formation of topographies. Directional molecular motion induced by UV light can generate complex morphology, and produce materials with unique optical functions, such as charming‐ordered gratings. This straightforward method of fabricating micropatterns by photodimerization‐induced diffusion is successfully applied to patterned curved surfaces, microfluidic channels and encapsulation of integrated light emitting diode chips.
Camouflage is widespread in nature, engineering, and the military. Dynamic surface wrinkles enable a material the on-demand control of the reflected optical signal and may provide an alternative to achieve adaptive camouflage. Here, we demonstrate a feasible strategy for adaptive visible camouflage based on light-driven dynamic surface wrinkles using a bilayer system comprising an anthracene-containing copolymer (PAN) and pigment-containing poly (dimethylsiloxane) (pigment-PDMS). In this system, the photothermal effect–induced thermal expansion of pigment-PDMS could eliminate the wrinkles. The multiwavelength light–driven dynamic surface wrinkles could tune the scattering of light and the visibility of the PAN film interference color. Consequently, the color captured by the observer could switch between the exposure state that is distinguished from the background and the camouflage state that is similar to the surroundings. The bilayer wrinkling system toward adaptive visible camouflage is simple to configure, easy to operate, versatile, and exhibits in situ dynamic characteristics without any external sensors and extra stimuli.
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