Amphidynamic crystals, engineered with rigid components linked to moving parts, are promising platforms for the development of smart materials and crystalline molecular machines.
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Scientists are constantly crisscrossing the periodic table in search of new 2D materials, leading to the recently spotlighted transition metal dichalchogenides, Xenes, MXenes, etc.
As the mission space of NA-213 Office of Nuclear Detection and Deterrence continues to evolve away from traditional stationary monitoring at borders and ports, the need for a solution to maintain situational awareness is critical.
The structure of amphiphilic molecules at buried liquid/liquid interfaces can be controlled by ion-pairing interactions to better understand the mechanisms of liquid extraction and self-assembly.
Researchers developed an automated scanning probe microscopy (SPM) platform to rapidly find regions of interest.
Electrical activity in the brain and heart depends on rhythmic generation of action potentials by pacemaker (HCN) ion channels whose activity is regulated by cAMP binding.
A novel, complementary method to oxidative Scholl coupling enables synthesis of conjugated porous networks via direct aromatic ring knitting.
Researchers showed that dual-function intermetallic nanoprecipitates simultaneously enhanced strength and ductility of medium-entropy alloys via synergistic spatial confinement effects on two distinct deformation mechanisms: precipitation
Researchers have discovered a new mode of SMSI construction under ambient conditions that is driven by photochemistry instead of the traditional thermal activation.
The nEDM@SNS project will search for the Electric Dipole Moment of the neutron at a level of 3 x 10-28 e-cm