Add to ORKGThe specific binding of complementary DNA strands has been suggested as an ideal method for directing the controlled self-assembly of microscopic objects. We report the first direct measurements of such DNA-induced interactions between colloidal microspheres, as well as the first colloidal crystals assembled using them. The interactions measured with our optical tweezer method can be modeled in detail by well-known statistical physics and chemistry, boding well for their application to directed selfassembly. The microspheres’ binding dynamics, however, have a surprising power-law scaling that can significantly slow annealing and crystallization
In this article we review the latest achievements in understanding and controlling DNA-mediated inte...
Immense insight into fundamental processes necessity for the fabrication of nanostructures is gather...
Nanoscale self-assembly is investigated using the specific interaction of DNA hybridization. Ordered...
The specific binding of complementary DNA strands has been suggested as an ideal method for directin...
Much of the excitement regarding nanotechnology stems from the idea of bottom-up self-assembly: th...
Much of the excitement regarding nanotechnology stems from the idea of bottom-up self-assembly: th...
A promising route to forming novel nanoparticle-based materials is directed self-assembly, where the...
A promising route to forming novel nanoparticle-based materials is directed self-assembly, where the...
A promising route to forming novel nanoparticle-based materials is directed self-assembly, where the...
This thesis revolves around exploiting the specificity of DNA interactions to guide the assembly of ...
A promising route to forming novel nanoparticle-based materials is directed self-assembly, where the...
Controlling interactions between colloidal suspensions has been a fascinating challenge both experim...
Controlling interactions between colloidal suspensions has been a fascinating challenge both experim...
This thesis revolves around exploiting the specificity of DNA interactions to guide the assembly of ...
In this article we review the latest achievements in understanding and controlling DNA-mediated inte...
In this article we review the latest achievements in understanding and controlling DNA-mediated inte...
Immense insight into fundamental processes necessity for the fabrication of nanostructures is gather...
Nanoscale self-assembly is investigated using the specific interaction of DNA hybridization. Ordered...
The specific binding of complementary DNA strands has been suggested as an ideal method for directin...
Much of the excitement regarding nanotechnology stems from the idea of bottom-up self-assembly: th...
Much of the excitement regarding nanotechnology stems from the idea of bottom-up self-assembly: th...
A promising route to forming novel nanoparticle-based materials is directed self-assembly, where the...
A promising route to forming novel nanoparticle-based materials is directed self-assembly, where the...
A promising route to forming novel nanoparticle-based materials is directed self-assembly, where the...
This thesis revolves around exploiting the specificity of DNA interactions to guide the assembly of ...
A promising route to forming novel nanoparticle-based materials is directed self-assembly, where the...
Controlling interactions between colloidal suspensions has been a fascinating challenge both experim...
Controlling interactions between colloidal suspensions has been a fascinating challenge both experim...
This thesis revolves around exploiting the specificity of DNA interactions to guide the assembly of ...
In this article we review the latest achievements in understanding and controlling DNA-mediated inte...
In this article we review the latest achievements in understanding and controlling DNA-mediated inte...
Immense insight into fundamental processes necessity for the fabrication of nanostructures is gather...
Nanoscale self-assembly is investigated using the specific interaction of DNA hybridization. Ordered...