Atomic Force Microscopy (AFM) is pivotal in nanoscience, offering high-resolution imaging and manipulation for advancements in semiconductors and life sciences.

This study reveals how silver-coated microrobots use photocatalysis and motion to achieve significant antibiotic degradation ...

Gerd Binnig's creation of the scanning tunnelling microscope has been fundamental to nanoscience, influencing diverse ...

Atomic force microscopy (BioAFM) drives innovation in cosmetics and healthcare, ensuring product efficacy through precise ...

Explore how time-resolved fluorescence enables sensitive monitoring of dye–protein binding in microliter volumes.

A recent study published in Bioinorganic Chemistry and Applications reported a green synthesis method for silver nanoparticles (AgNPs) using peel extract from the “Mollar de Elche” variety of ...

New research explores silicon nanorods in metasurfaces for polarization holographic encryption, addressing image recovery and ...

Pittcon, the nation’s premier annual conference and exposition on laboratory science, is pleased to announce that the ...

Photothermal AFM-IR combines atomic force microscopy and infrared spectroscopy to reveal chemical heterogeneity and ...

As nanomaterials gain commercial traction, they have the potential to revolutionize medicine, aerospace, and 3D printing, and ...

Physik Instrumente (PI), a global leader in precision motion control and nanopositioning technologies, has been named the ...

Nanomaterials are materials with at least one dimension smaller than 100 nanometres (about 100,000 times thinner than a human hair). Because of their tiny size, they have unique properties that can be ...