The performance of energy storage materials is often governed by their structure at the atomic scale.
Large-scale numerical calculations reveal fluctuating spin and charge stripes intertwined with pair-density-wave
a-RuCl3 is a prime candidate for the Kitaev-type quantum spin liquid relevant to noise-resilient solid state quantum gates.
We report the first observation of an enhanced electromechanical response in BaTiO3 thin films driven via local oxygen vacancy migration in piezoresponse force microscopy (PFM).
Structure-mediated adsorption and interfacial ordering is key to designing ligands for extractions with enhanced selectivity and efficiency.
Manipulation of matter at the nanoscale in functional nanostructures allows to harness nanoscale and even quantum phenomena, with applications in electronics, plasmonics, optoelectronics, and sensing.
Understanding the reaction mechanisms of dehydrogenative Caryl–Caryl coupling is the key to directed formation of p-extended polycyclic aromatic hydrocarbons.
New materials can now be routinely imaged at atomic resolution with such high throughput in aberration-corrected scanning transmission electron microscopy that automatic methods for detecting
Antisite defects were selectively incorporated in monolayer WS2 during its growth by regulating W diffusion in Au substrates, as predicted by first principles calculations.