Do-Nyun Kim

TL;DR: A computational tool for predicting the structure of DNA Origami objects is introduced and information is provided on the conditions under which DNA origami objects can be expected to maintain their structure.

TL;DR: This model represents an important advance in the quantitative understanding of DNA-based nanostructure shape and flexibility, and it is anticipated that this model will increase significantly the number and variety of synthetic nanostructures designed using nucleic acids.

TL;DR: The stretch-unresponsive touch sensing capability of the transparent and stretchable capacitive touch sensor has great potential in wearable electronics and human-machine interfaces.

TL;DR: In this paper, the authors proposed a method to predict the 3D structure of high molecular weight planar and spherical ring-like origami objects, a tile-based sheet-like ribbon, and a 3D crystalline tensegrity motif.

TL;DR: In this paper, the authors present a shell element that models the 3D effects of surface tractions, like needed when a shell is confined between other solid media, using the widely used MITC4 shell element enriched by the use of a fully 3D stress-strain description, appropriate through-the-thickness displacements, and pressure degrees of freedom for incompressible analyses.