Add to ORKGA key goal of nanotechnology is the development of artificial machines capable of converting molecular movement into macroscopic work. Although conversion of light into shape changes has been reported and compared to artificial muscles, real applications require work against an external load. Here, we describe the design, synthesis and operation of spring-like materials capable of converting light energy into mechanical work at the macroscopic scale. These versatile materials consist of molecular switches embedded in liquid-crystalline polymer springs. In these springs, molecular movement is converted and amplified into controlled and reversible twisting motions. The springs display complex motion, which includes winding, unwinding and heli...
Controlling sophisticated motion by molecular motors is a major goal on the road to future actuators...
Molecular/supramolecular springs are artificial nanoscale objects possessing well‐defined structures...
Smart materials adapt to, rather than resist, changes to their environment. In Nature, a variety of ...
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...
Motion in plants often relies on dynamic helical systems as seen in coiling tendrils, spasmoneme spr...
The motion of artificial molecular machines has been amplified into the shape transformation of poly...
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, ...
Controlling sophisticated motion by molecular motors is a major goal on the road to future actuators...
Molecular/supramolecular springs are artificial nanoscale objects possessing well‐defined structures...
Smart materials adapt to, rather than resist, changes to their environment. In Nature, a variety of ...
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...
Motion in plants often relies on dynamic helical systems as seen in coiling tendrils, spasmoneme spr...
The motion of artificial molecular machines has been amplified into the shape transformation of poly...
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, ...
Controlling sophisticated motion by molecular motors is a major goal on the road to future actuators...
Molecular/supramolecular springs are artificial nanoscale objects possessing well‐defined structures...
Smart materials adapt to, rather than resist, changes to their environment. In Nature, a variety of ...