New study shows that electron spins - tiny magnetic properties of atoms that can store information - can be protected from decohering (losing their quantum state) much more effectively than previously thought, simply by applying low magnetic fields.
A recent research study has successfully merged two cutting-edge 3D tissue engineering strategies - 3D polymeric scaffolds and 3D neuronal spheroids - to create a highly advanced model for studying neuronal behaviour and disease.
Cost-effective chiral nanostructures enable precise light control at the nanoscale, advancing applications in sensing, imaging, and emerging quantum technologies.
Laser-induced alignment boosts single-particle imaging by improving molecular orientation, enabling clearer 3D structure recovery of proteins and macromolecules.
Researchers developed graphene oxide nanoparticles that combine chemotherapy, immune activation, and photothermal heating to effectively destroy tumors.
Engineered bacteria secrete powerful nanoparticles to aid in drug delivery, vaccines and treating medical conditions, such as Inflammatory Bowel Disease.
Researchers show how 3D printing enables sub-micron precision in microelectronics and microfluidics, offering a flexible alternative to traditional methods.
Scientists have created a scalable cryogenic process for producing borophene sheets that efficiently harvest energy from motion, enabling next-generation flexible electronics.
