New methods quiet noise and reduce error in measurements of elusive quantum properties
By mimicking biological machinery with non-biological parts, artificial cells work to convert light into chemical energy.
Scientists image complex superstructures self-assembled from tetrahedral quantum dots, expanding our understanding of forming small, complex crystals.
Models use a fraction of the computational cost of today’s best atom-based water models.
A new catalyst design meets cost, activity, and durability goals by leveraging ultralow loadings of platinum with platinum-free supports.
Read more about Improved Fuel Cell Catalysts with Less Platinum
Detailed 3D images show how nanoparticles change in reactions that purify contaminated water or power recyclable geochemical batteries.
Researchers developed a new self-generating lubricant with great potential for industrial applications.
Scientists add active control to design capabilities for new lightweight flat optical devices.
A nickelate thin film senses electric field changes analogous to the electroreception sensing organ in sharks, which detects the bioelectric fields of prey.
Control over light-emitting properties of tiny semiconductor platelets may yield new opportunities for innovative optics utilizing quantum phenomena.
An entirely human-made architecture produces hydrogen fuel using light, shows promise for transmitting energy in numerous applications.
A twisted array of atomic magnets were driven to move in a curved path, a needed level of control for use in future memory devices.
