A molecular approach to the powering of multi-component nano-devices capable of autonomous translational and rotational motion through the conversion of chemical to kinetic energy is reported.
The design and construction of machines and motors of molecular size is a stimulating scientific cha...
Motor proteins are nature's solution for directing movement at the molecular level. The field of art...
Atomically precise manufacturing systems, such as those described in Nanosystems [1], will utilize m...
A molecular approach to the powering of multi-component nano-devices capable of autonomous translati...
A molecular approach to the powering of multi-component nano-devices capable of autonomous translati...
Autonomous propulsion of microparticles using catalytic olefin polymerization, and directional rotat...
Self-propelled, synthetic active matters that transduce chemical energy into mechanical motion are e...
Progress in nanotechnology has enabled the synthesis of active particles that can harness chemical e...
In this review we chart recent advances in what is at once an old and very new field of endeavour — ...
The bottom-up construction and operation of machines and motors of molecular size is a topic of grea...
Nanomachines of the future will require molecular-scale motors1, 2, 3, 4, 5, 6 that can perform work...
Movement is one of the central attributes of life, and a key feature in many technological processes...
A molecular machine can be defined as an assembly of a discrete number of molecular components (that...
Nature has inspired the creation of artificial micro- and nanomotors that self-propel converting che...
The design and construction of machines and motors of molecular size is a stimulating scientific cha...
Motor proteins are nature's solution for directing movement at the molecular level. The field of art...
Atomically precise manufacturing systems, such as those described in Nanosystems [1], will utilize m...
A molecular approach to the powering of multi-component nano-devices capable of autonomous translati...
A molecular approach to the powering of multi-component nano-devices capable of autonomous translati...
Autonomous propulsion of microparticles using catalytic olefin polymerization, and directional rotat...
Self-propelled, synthetic active matters that transduce chemical energy into mechanical motion are e...
Progress in nanotechnology has enabled the synthesis of active particles that can harness chemical e...
In this review we chart recent advances in what is at once an old and very new field of endeavour — ...
The bottom-up construction and operation of machines and motors of molecular size is a topic of grea...
Nanomachines of the future will require molecular-scale motors1, 2, 3, 4, 5, 6 that can perform work...
Movement is one of the central attributes of life, and a key feature in many technological processes...
A molecular machine can be defined as an assembly of a discrete number of molecular components (that...
Nature has inspired the creation of artificial micro- and nanomotors that self-propel converting che...
The design and construction of machines and motors of molecular size is a stimulating scientific cha...
Motor proteins are nature's solution for directing movement at the molecular level. The field of art...
Atomically precise manufacturing systems, such as those described in Nanosystems [1], will utilize m...
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