Add to ORKG\u3cp\u3eVarious nanomotors that can mimic the motion of natural systems have recently been proposed. Yet, most designs are metal based and not applicable in biological settings. We report the first biodegradable nanomotor that moves in the presence of fuel. Tubular-shaped polymersomes with 5 wt% azide handles were assembled with catalase chemically linked to the handles. The nanotubes move autonomously in H\u3csub\u3e2\u3c/sub\u3eO\u3csub\u3e2\u3c/sub\u3e.\u3c/p\u3
A number of organisms and organelles are capable of self-propulsion at the micro- and nanoscales. Pr...
A number of organisms and organelles are capable of self-propulsion at the micro- and nanoscales. Pr...
We describe nanoscale tools in the form of autonomous and remotely guided catalytically self-propell...
Various nanomotors that can mimic the motion of natural systems have recently been proposed. Yet, mo...
Self-powered artificial nanomotors are currently attracting increased interest as mimics of biologic...
Self-powered artificial nanomotors are currently attracting increased interest as mimics of biologic...
Designer particles that are embued with nanomachinery for autonomous motion have great potential for...
Replicating efficient chemical energy utilization of biological nanomotors is one ultimate goal of n...
A number of organisms and organelles are capable of self-propulsion at the micro- and nanoscales. Pr...
A number of organisms and organelles are capable of self-propulsion at the micro- and nanoscales. Pr...
We describe nanoscale tools in the form of autonomous and remotely guided catalytically self-propell...
Various nanomotors that can mimic the motion of natural systems have recently been proposed. Yet, mo...
Self-powered artificial nanomotors are currently attracting increased interest as mimics of biologic...
Self-powered artificial nanomotors are currently attracting increased interest as mimics of biologic...
Designer particles that are embued with nanomachinery for autonomous motion have great potential for...
Replicating efficient chemical energy utilization of biological nanomotors is one ultimate goal of n...
A number of organisms and organelles are capable of self-propulsion at the micro- and nanoscales. Pr...
A number of organisms and organelles are capable of self-propulsion at the micro- and nanoscales. Pr...
We describe nanoscale tools in the form of autonomous and remotely guided catalytically self-propell...