Moiré materials realized by controlling the twistbetween different atomic layers represent anemerging family of crystals with unique electronicproperties.

By mapping momentum-resolved electronic states using time-resolved and angle-resolved photoemission spectroscopy, researchers recently revealed that monolayer Ag confined between bilayer graphene and SiC is a large gap (>1 eV) 2D semiconductor, consistent with ab initio GW calculations.

Living polymer networks, including tissues andbiofilms, actively respond to complex combinations ofenvironmental inputs, leading to differentiation,regeneration, and development.

With declining numbers of STEM degrees and limited diversity in the STEM workforce, there is a need for expansion of research opportunities for undergraduate and high school students, in particular those from underrepresented groups.

The Ohio State University and University of California, Santa Barbara MRSECS  partnered  to  host  the  Conference  Across  MRSECs  and PREMs (CAMPS) in October 2022.

This work demonstrates that the TI vdW material Bi2Se3 can be grown as a single-crystalline single-orientation film on semiconductor substrates with appropriate substrate pre-treatment conditions.

The ability to thermally trigger a conformational changeand collapse in a constituent resilin-like protein (RLP) providesthe opportunity to build, and eventually move, a bundlemer nanostructure.

Normally, unwanted oscillations are removed from a dynamical system through the introduction of energy loss. In materials used for moving photons between light waves of different frequencies – a key process, e.g., for transfer of information between nodes of a quantum network – unwanted oscillations between photon populations can limit device efficiency and cause instability and noise.

Many organisms use cilia to control fluids at the microscale. Engineering a cilia platform with comparable capabilities, however, has remained elusive. Now, Cornell researchers have taken a step towards such systems by creating electronically-actuated artificial cilia that can create arbitrary flow patterns in liquids near a surface. The team first created voltage-actuated cilia that can drive surface flows at tens of microns per second with only 1 volt applied.