Scientists successfully visualized the ultrafast dynamics of quasi-particles known as excitons, which are generated in carbon nanotubes upon light excitation.

Researchers have developed a way to create tiny droplets of one liquid inside another liquid without mixing the two together.

Scientists have unveiled a new observational technique that's sensitive to the dynamics of the intrinsic quantum jiggles of materials, or phonons.

The highly integrated vector magnetometer is based on nitrogen vacancies (NV) in diamond and provides access to the smallest magnetic fields with a previously unattainable degree of flexibility and precision.

The new sensor is more light-sensitive, reproduces colours more accurately and offers significantly higher resolution than conventional silicon sensors.

Selenium-doped nanoparticles improve fungicide retention, activate plant defenses, and lower toxicity in environmentally safer pesticide formulations.

Portable NMR-AI biosensor enables rapid, precise viral detection and immune monitoring, offering a compact, user-friendly tool for faster point-of-care diagnosis.

Researchers have recently developed a new technique to adjust the properties of liquids that could be used to create soft electronics.

Scientists demonstrate an innovative acoustofluidics-based approach for intracellular nanoparticle delivery. This method offers a new way to transport various functional nanomaterials into different cell types, potentially revolutionizing therapeutic applications and biophysical studies.

Scientists have discovered the internal shape of tiny drug-delivery particles - called lipid nanoparticles - has a big impact on how well our cells absorb them, paving the way to more efficient vaccine and drug delivery.

Employing cost-effective MoS2 thin films in place of expensive noble metals resolves issues of non-uniform lithium plating and interfacial instability in anode-free all-solid-state batteries.