22 research outputs found
Reprogrammable, Reprocessible, and Self-Healable Liquid Crystal Elastomer with Exchangeable Disulfide Bonds
A liquid
crystal elastomer (LCE) can be regarded as an integration
of mesogenic molecules into a polymer network. The LCE can generate
large mechanical actuation when subjected to various external stimuli.
Recently, it has been extensively explored to make artificial muscle
and multifunctional devices. However, in the commonly adopted two-step
crosslinking method for synthesizing monodomain LCEs, the LCE needs
to be well-cross-linked in the first step before stretching, which
increases the disorder of mesogenic molecules in the final state of
the LCE and makes it very challenging to fabricate the LCE of complex
shapes. In this article, we developed a new LCE with disulfide bonds,
which can be reprogrammed from the polydomain state to the monodomain
state either through heating or UV illumination, owing to the rearrangement
of the polymer network induced by the metathesis reaction of disulfide
bonds. In addition, the newly developed LCE can be easily reprocessed
and self-healed by heating. Because of the excellent reprogrammability
as well as reprocessability of the LCE, we further fabricated LCE-based
active micropillar arrays through robust imprint lithography, which
can be hardly achieved using the LCE prepared previously. Finally,
we showed an excellent long-term durability of the newly developed
LCE
Electrically Templated Dewetting of a UV-Curable Prepolymer Film for the Fabrication of a Concave Microlens Array with Well-Defined Curvature
This
paper presents an economic method, based on electrically templated
dewetting of a UV-curable prepolymer, for fabricating a concave microlens
array (MLA) of high quality and high density. In our strategy, a voltage
is applied to an electrode pair consisting of a conductive substrate
coated with a UV-curable prepolymer film and a microhole-arrayed silicon
template, sandwiching an air gap, to dewet the prepolymer film into
a curved air–liquid interface. At or beyond a critical voltage,
the curved prepolymer
can be pulled quickly into contact with the protrusive underside of
the silicon template. Contact of the prepolymer with the template
can be detected by monitoring the leaky current in the polymer, followed
by a UV curing of the prepolymer. Finally, by separating the mold
from the solidified polymer, a concave MLA is obtained. The curvature
of the MLA can be well-defined simply by changing the air gap between
the mold and prepolymer film.
Besides, the dewetting strategy results in a much smaller adhesion
area between the mold and solidified polymer structures, which allows
for easy separation of the mold from the MLA in a large-area operation
Electrically Modulated Microtransfer Molding for Fabrication of Micropillar Arrays with Spatially Varying Heights
The ability to generate a large area micropillar array
with spatially
varying heights allows for exploring numerous new interesting applications
in biotechnology, surface engineering, microfluidics, and so forth.
This Letter presents a clever and straightforward method, called electrically
modulated microtransfer molding (EM3), for generating such unique
microstructures from a silicon mold arrayed with microholes. The key
to the process is an application of electrically tunable wettability
caused by a spatially modulated voltage, which electrohydrodynamically
drives a photocurable and dielectric prepolymer to fill the microholes
to a depth depending on the voltage amplitude. Using EM3, micropillar
arrays with stepwise or continuously varying heights are successfully
fabricated, with the diameter scalable to 1.5 ÎĽm and with the
maximum height being equal to the depth of the high-aspect-ratio (more
than 10:1) microholes
Polydopamine-Coated Main-Chain Liquid Crystal Elastomer as Optically Driven Artificial Muscle
Optically
driven active materials have received much attention because their
deformation and motion can be controlled remotely, instantly, and
precisely in a contactless way. In this study, we investigated an
optically actuated elastomer with rapid response: polydopamine (PDA)-coated
liquid crystal elastomer (LCE). Because of the photothermal effect
of PDA coating and thermal responsiveness of LCE, the elastomer film
contracted significantly with near-infrared (NIR) irradiation. With
a fixed strain, light-induced actuating stress in the film could be
as large as 1.5 MPa, significantly higher than the maximum stress
generated by most mammalian skeletal muscle (0.35 MPa). The PDA-coated
LCE films could also bend or roll up by surface scanning of an NIR
laser. The response time of the film to light exposure could be as
short as 1/10 of a second, comparable to or even faster than that
of mammalian skeletal muscle. Using the PDA-coated LCE film, we designed
and fabricated a prototype of robotic swimmer that was able to swim
near the water–air interface by performing “swimming
strokes” through reversible bending and unbending motions induced
and controlled by an NIR laser. The results presented in this study
clearly demonstrated that PDA-coated LCE is a promising optically
driven artificial muscle, which may have great potential for applications
of soft robotics and optomechanical coupling devices
Polydopamine-Coated Main-Chain Liquid Crystal Elastomer as Optically Driven Artificial Muscle
Optically
driven active materials have received much attention because their
deformation and motion can be controlled remotely, instantly, and
precisely in a contactless way. In this study, we investigated an
optically actuated elastomer with rapid response: polydopamine (PDA)-coated
liquid crystal elastomer (LCE). Because of the photothermal effect
of PDA coating and thermal responsiveness of LCE, the elastomer film
contracted significantly with near-infrared (NIR) irradiation. With
a fixed strain, light-induced actuating stress in the film could be
as large as 1.5 MPa, significantly higher than the maximum stress
generated by most mammalian skeletal muscle (0.35 MPa). The PDA-coated
LCE films could also bend or roll up by surface scanning of an NIR
laser. The response time of the film to light exposure could be as
short as 1/10 of a second, comparable to or even faster than that
of mammalian skeletal muscle. Using the PDA-coated LCE film, we designed
and fabricated a prototype of robotic swimmer that was able to swim
near the water–air interface by performing “swimming
strokes” through reversible bending and unbending motions induced
and controlled by an NIR laser. The results presented in this study
clearly demonstrated that PDA-coated LCE is a promising optically
driven artificial muscle, which may have great potential for applications
of soft robotics and optomechanical coupling devices
Polydopamine-Coated Main-Chain Liquid Crystal Elastomer as Optically Driven Artificial Muscle
Optically
driven active materials have received much attention because their
deformation and motion can be controlled remotely, instantly, and
precisely in a contactless way. In this study, we investigated an
optically actuated elastomer with rapid response: polydopamine (PDA)-coated
liquid crystal elastomer (LCE). Because of the photothermal effect
of PDA coating and thermal responsiveness of LCE, the elastomer film
contracted significantly with near-infrared (NIR) irradiation. With
a fixed strain, light-induced actuating stress in the film could be
as large as 1.5 MPa, significantly higher than the maximum stress
generated by most mammalian skeletal muscle (0.35 MPa). The PDA-coated
LCE films could also bend or roll up by surface scanning of an NIR
laser. The response time of the film to light exposure could be as
short as 1/10 of a second, comparable to or even faster than that
of mammalian skeletal muscle. Using the PDA-coated LCE film, we designed
and fabricated a prototype of robotic swimmer that was able to swim
near the water–air interface by performing “swimming
strokes” through reversible bending and unbending motions induced
and controlled by an NIR laser. The results presented in this study
clearly demonstrated that PDA-coated LCE is a promising optically
driven artificial muscle, which may have great potential for applications
of soft robotics and optomechanical coupling devices
Polydopamine-Coated Main-Chain Liquid Crystal Elastomer as Optically Driven Artificial Muscle
Optically
driven active materials have received much attention because their
deformation and motion can be controlled remotely, instantly, and
precisely in a contactless way. In this study, we investigated an
optically actuated elastomer with rapid response: polydopamine (PDA)-coated
liquid crystal elastomer (LCE). Because of the photothermal effect
of PDA coating and thermal responsiveness of LCE, the elastomer film
contracted significantly with near-infrared (NIR) irradiation. With
a fixed strain, light-induced actuating stress in the film could be
as large as 1.5 MPa, significantly higher than the maximum stress
generated by most mammalian skeletal muscle (0.35 MPa). The PDA-coated
LCE films could also bend or roll up by surface scanning of an NIR
laser. The response time of the film to light exposure could be as
short as 1/10 of a second, comparable to or even faster than that
of mammalian skeletal muscle. Using the PDA-coated LCE film, we designed
and fabricated a prototype of robotic swimmer that was able to swim
near the water–air interface by performing “swimming
strokes” through reversible bending and unbending motions induced
and controlled by an NIR laser. The results presented in this study
clearly demonstrated that PDA-coated LCE is a promising optically
driven artificial muscle, which may have great potential for applications
of soft robotics and optomechanical coupling devices
Polydopamine-Coated Main-Chain Liquid Crystal Elastomer as Optically Driven Artificial Muscle
Optically
driven active materials have received much attention because their
deformation and motion can be controlled remotely, instantly, and
precisely in a contactless way. In this study, we investigated an
optically actuated elastomer with rapid response: polydopamine (PDA)-coated
liquid crystal elastomer (LCE). Because of the photothermal effect
of PDA coating and thermal responsiveness of LCE, the elastomer film
contracted significantly with near-infrared (NIR) irradiation. With
a fixed strain, light-induced actuating stress in the film could be
as large as 1.5 MPa, significantly higher than the maximum stress
generated by most mammalian skeletal muscle (0.35 MPa). The PDA-coated
LCE films could also bend or roll up by surface scanning of an NIR
laser. The response time of the film to light exposure could be as
short as 1/10 of a second, comparable to or even faster than that
of mammalian skeletal muscle. Using the PDA-coated LCE film, we designed
and fabricated a prototype of robotic swimmer that was able to swim
near the water–air interface by performing “swimming
strokes” through reversible bending and unbending motions induced
and controlled by an NIR laser. The results presented in this study
clearly demonstrated that PDA-coated LCE is a promising optically
driven artificial muscle, which may have great potential for applications
of soft robotics and optomechanical coupling devices
Polydopamine-Coated Main-Chain Liquid Crystal Elastomer as Optically Driven Artificial Muscle
Optically
driven active materials have received much attention because their
deformation and motion can be controlled remotely, instantly, and
precisely in a contactless way. In this study, we investigated an
optically actuated elastomer with rapid response: polydopamine (PDA)-coated
liquid crystal elastomer (LCE). Because of the photothermal effect
of PDA coating and thermal responsiveness of LCE, the elastomer film
contracted significantly with near-infrared (NIR) irradiation. With
a fixed strain, light-induced actuating stress in the film could be
as large as 1.5 MPa, significantly higher than the maximum stress
generated by most mammalian skeletal muscle (0.35 MPa). The PDA-coated
LCE films could also bend or roll up by surface scanning of an NIR
laser. The response time of the film to light exposure could be as
short as 1/10 of a second, comparable to or even faster than that
of mammalian skeletal muscle. Using the PDA-coated LCE film, we designed
and fabricated a prototype of robotic swimmer that was able to swim
near the water–air interface by performing “swimming
strokes” through reversible bending and unbending motions induced
and controlled by an NIR laser. The results presented in this study
clearly demonstrated that PDA-coated LCE is a promising optically
driven artificial muscle, which may have great potential for applications
of soft robotics and optomechanical coupling devices
Step-Controllable Electric-Field-Assisted Nanoimprint Lithography for Uneven Large-Area Substrates
Large-area
nanostructures are widely used in various fields, but fabrication
on large-area uneven substrates poses a significant challenge. This
study demonstrates a step-controllable electric-field-assisted nanoimprint
lithography (e-NIL) method that can achieve conformal contact with
uneven substrates for high fidelity nanostructuring. Experiments are
used to demonstrate the method where a substrate coated with liquid
resist is brought into contact with a flexible template driven by
the applied electric field. Theoretical analysis based on the elasticity
theory and electro-hydrodynamic theory is carried out. Effective voltage
range and the saturation voltage are also discussed. A step-controllable
release of flexible template is proposed and demonstrated to ensure
the continuous contact between the template and an uneven substrate.
This prevents formation of air traps and allows large area conformal
contact to be achieved. A combination of Vacuum-electric field assisted
step-controllable e-NIL is implemented in the developed prototype.
Finally, photonic crystal nanostructures are successfully fabricated
on a 4 in., 158 ÎĽm bow gallium nitride light-emitting diode
epitaxial wafer using the proposed method, which enhance the light
extraction property