The selectivity of DNA recognition inspires an elegant protocol for designing versatile nanoparticle (NP) assemblies. We use molecular dynamics simulations to analyze dynamic aspects of the assembly process and identify ingredients that are key to a successful assembly of NP superlattices through DNA hybridization. A scale-accurate coarse-grained model faithfully captures the relevant contributions to the kinetics of the DNA hybridization process and is able to recover all experimentally reported to date binary superlattices (BCC, CsCl, AlB2, Cr3Si, and Cs6C60). We study the assembly mechanism in systems with up to 10(6) degrees of freedom and find that the crystallization process is accompanied with a slight decrease of enthalpy. Furthermo...
Nanoscale self-assembly is investigated using the specific interaction of DNA hybridization. Ordered...
Understanding the fundamental principles behind biomemetic nanoparticle self- assembly has been unde...
One of the fundamental challenges of nanoscience and nanotechnology today is to organize nanoparticl...
The selectivity of DNA recognition inspires an elegant protocol for designing versatile nanoparticle...
The selectivity of DNA recognition inspires an elegant protocol for designing versatile nanoparticle...
The selectivity of DNA recognition inspires an elegant protocol for designing versatile nanoparticle...
The selectivity of DNA recognition inspires an elegant protocol for designing versatile nanoparticle...
The selectivity of DNA recognition inspires an elegant protocol for designing versatile nanoparticle...
The selectivity of DNA recognition inspires an elegant protocol for designing versatile nanoparticle...
Hybridization interactions between DNA-functionalized nanoparticles (DNA-NPs) can be used to program...
Herein, we report an example of entropy-driven crystallization behavior in DNA-nanoparticle superlat...
Colloidal crystal engineering with DNA can be used to realize precise control over nanoparticle (NP)...
Many researchers are interested in developing methods for rationally assembling nanoparticle buildin...
It is a challenging task to properly realize crystal superlattices with the precise organization of ...
Nanoscale self-assembly is investigated using the specific interaction of DNA hybridization. Ordered...
Nanoscale self-assembly is investigated using the specific interaction of DNA hybridization. Ordered...
Understanding the fundamental principles behind biomemetic nanoparticle self- assembly has been unde...
One of the fundamental challenges of nanoscience and nanotechnology today is to organize nanoparticl...
The selectivity of DNA recognition inspires an elegant protocol for designing versatile nanoparticle...
The selectivity of DNA recognition inspires an elegant protocol for designing versatile nanoparticle...
The selectivity of DNA recognition inspires an elegant protocol for designing versatile nanoparticle...
The selectivity of DNA recognition inspires an elegant protocol for designing versatile nanoparticle...
The selectivity of DNA recognition inspires an elegant protocol for designing versatile nanoparticle...
The selectivity of DNA recognition inspires an elegant protocol for designing versatile nanoparticle...
Hybridization interactions between DNA-functionalized nanoparticles (DNA-NPs) can be used to program...
Herein, we report an example of entropy-driven crystallization behavior in DNA-nanoparticle superlat...
Colloidal crystal engineering with DNA can be used to realize precise control over nanoparticle (NP)...
Many researchers are interested in developing methods for rationally assembling nanoparticle buildin...
It is a challenging task to properly realize crystal superlattices with the precise organization of ...
Nanoscale self-assembly is investigated using the specific interaction of DNA hybridization. Ordered...
Nanoscale self-assembly is investigated using the specific interaction of DNA hybridization. Ordered...
Understanding the fundamental principles behind biomemetic nanoparticle self- assembly has been unde...
One of the fundamental challenges of nanoscience and nanotechnology today is to organize nanoparticl...