Scientists have devised a unique means of achieving effective gate operation with a form of information processing called electromagnonics. Their pivotal discovery allows real-time control of information transfer between microwave photons and magnons.
The quantum movements of a small glass sphere could be controlled for the first time by combining microscopy with control engineering, setting the course for future quantum technologies.
Ligands are much like nanosized barnacles, binding to many kinds of surfaces. This form of adsorption is crucial for a range of chemical processes, from purification and catalysis to the design of nanomaterials.
Researchers have created a neural network that can help tweak semiconductor crystals in a controlled fashion to achieve superior properties for electronics. This enables a new direction of development of next-generation chips and solar cells by exploiting a controllable deformation that may change the properties of a material on the fly.
Researchers have reported a new type of NIR-II responsive hollow magnetite nanoclusters, which is made of ferroferric oxide, composed of mesoporous shell and hollow cavity for targeted imaging-guided combined therapy of cancer.
Researchers have reported on a novel alternative mechanism to achieve superconductivity in graphene. They achieved this feat by proposing a hybrid system consisting of graphene and 2D Bose-Einstein condensate.
