Add to ORKGMotion in plants often relies on dynamic helical systems as seen in coiling tendrils, spasmoneme springs, and the opening of chiral seedpods. Developing nanotechnology that would allow molecular-level phenomena to drive such movements in artificial systems remains a scientific challenge. Herein, we describe a soft device that uses nanoscale information to mimic seedpod opening. The system exploits a fundamental mechanism of stimuli-responsive deformation in plants, namely that inflexible elements with specific orientations are integrated into a stimuli-responsive matrix. The device is operated by isomerization of a light-responsive molecular switch that drives the twisting of strips of liquid-crystal elastomers. The strips twist in opposite...
Soft robots, composed of intrinsically soft materials, have continuously deformable structures that ...
Smart materials adapt to, rather than resist, changes to their environment. In Nature, a variety of ...
Natural systems transfer chiral information across multiple length scales through dynamic supramolec...
Motion in plants often relies on dynamic helical systems as seen in coiling tendrils, spasmoneme spr...
A key goal of nanotechnology is the development of artificial machines capable of converting molecul...
A key goal of nanotechnology is the development of artificial machines capable of converting molecul...
Polymer springs that twist under irradiation with light, in a manner that mimics how plant tendrils ...
Future robotic systems will have to adapt their operation to dynamic environments and therefore thei...
The motion of artificial molecular machines has been amplified into the shape transformation of poly...
Interfacing molecular photoswitches with liquid crystal polymers enables the amplification of their ...
The cooperative operation of artificial molecular motors and switches has been amplified in polymer-...
This protocol describes the preparation of polymer springs that twist under irradiation with light, ...
Soft actuator is a promising candidate for replacing a traditional rigid materials-based actuator wh...
Bioinspired material research aims at learning from the sophisticated design principles of nature, i...
Soft robots, composed of intrinsically soft materials, have continuously deformable structures that ...
Smart materials adapt to, rather than resist, changes to their environment. In Nature, a variety of ...
Natural systems transfer chiral information across multiple length scales through dynamic supramolec...
Motion in plants often relies on dynamic helical systems as seen in coiling tendrils, spasmoneme spr...
A key goal of nanotechnology is the development of artificial machines capable of converting molecul...
A key goal of nanotechnology is the development of artificial machines capable of converting molecul...
Polymer springs that twist under irradiation with light, in a manner that mimics how plant tendrils ...
Future robotic systems will have to adapt their operation to dynamic environments and therefore thei...
The motion of artificial molecular machines has been amplified into the shape transformation of poly...
Interfacing molecular photoswitches with liquid crystal polymers enables the amplification of their ...
The cooperative operation of artificial molecular motors and switches has been amplified in polymer-...
This protocol describes the preparation of polymer springs that twist under irradiation with light, ...
Soft actuator is a promising candidate for replacing a traditional rigid materials-based actuator wh...
Bioinspired material research aims at learning from the sophisticated design principles of nature, i...
Soft robots, composed of intrinsically soft materials, have continuously deformable structures that ...
Smart materials adapt to, rather than resist, changes to their environment. In Nature, a variety of ...
Natural systems transfer chiral information across multiple length scales through dynamic supramolec...