Comparative Study of Optical Silicon Nanomachining Experimental Results and MD Simulation Outputs

The high strength and good optical performance offered by optical grade silicon could be considered as the reason for its wide usage as optical materials in many industries including electronic, metrology, infrared (IR) optics and solar cells. Due to this, nanoscale manufacturing of these products requires superior quality and enhanced functional performance of the produced materials. Because recent studies have been focusing on correlating both surface and subsurface nature alterations with better functional performance, an MD study of the experiment was carried out in comparison with experiment to match the observed MD model features to the experimental result obtained. The MD study was observed to conform with the Ra result as obtained in the experiment.

DNA-based self-assembly of nanostructures

This article examines the DNA-based self-assembly of nanostructures. It first reviews the development of DNA self-assembly and DNA-directed assembly, focusing on the main strategies and building blocks available in the modern molecular construction toolbox, including the design, construction, and analysis of nanostructures composed entirely of synthetic DNA, as well as origami nanostructures formed from a mixture of synthetic and biological DNA. In particular, it considers the stepwise covalent synthesis of DNA nanomaterials, unmediated assembly of DNA nanomaterials, hierarchical assembly, nucleated assembly, and algorithmic assembly. It then discusses DNA-directed assembly of heteromaterials such as proteins and peptides, gold nanoparticles, and multicomponent nanostructures. It also describes the use of complementary DNA cohesion as 'smart glue' for bringing together covalently linked functional groups, biomolecules, and nanomaterials. Finally, it evaluates the potential future of DNA-based self-assembly for nanoscale manufacturing for applications in medicine, electronics, photonics, and materials science.