Atomic force microscopy (AFM) is a cornerstone technique for nanoscale manipulation, and has applications in nanoparticle assembly, biomolecule handling, semiconductor device manufacturing, etc.

A multimodal imaging study combines cryo-X-ray nanotomography and super-resolution fluorescence microscopy to reveal how protein-coated nanoparticles behave in cells. (Nanowerk Spotlight) The ...

To the untrained eye, they look like blobs blotching the otherwise smooth surface of rod-like bacteria. But if you ask a microbiologist about "cellulosomes," they will likely tell you that those blobs ...

Using artificial intelligence, engineers have developed a new way to watch the inner workings of living cells in real time. The process both captures images that are twice as sharp as conventional ...

Bruker’s xView ™ Module for the Ultima 2Pplus multiphoton microscope delivers a major leap in large-scale, high-resolution imaging. By expanding the field of view by more than 2.5 times the standard ...

Stanford researchers have developed a microscope that can show how nanostructures interact inside living cells at the highest ...

Structured illumination microscopy (SIM) is the most preferable system for live-cell super-resolution imaging. It enables the observation of intricate subcellular dynamics. However, conventional SIM ...

A super-resolution microscopy technique offers an unparalleled glimpse into how monoclonal antibodies bind to their targets on cancer cells to induce cell death. “There is a power in seeing things,” ...

Chiral light-matter interactions underpin many emerging technologies in sensing, quantum optics, and polarization control. Artificial chiral metasurfaces, which are patterned at nanoscale, can ...

When single-molecule super-resolution microscopes were first commercialized some 15 years ago, they made headlines for their ability to resolve individual molecules and structures at the nanometer ...