AI-powered thinking microscopes can analyze data, test hypotheses, and refine experiments, accelerating breakthroughs across science and healthcare.

Scientific discovery is often portrayed as the result of long hours alone in a lab, but true science is inherently collaborative. The most robust experimental processes are developed through ...

TEM works by transmitting a beam of electrons through an ultra-thin specimen. As the electrons interact with the specimen, they are scattered or transmitted, producing an image that is magnified and ...

They can image a wide range of materials and biological samples with high magnification, resolution, and depth of field, thereby revealing surface structure and chemical composition. Industries like ...

A custom-designed electron cryomicroscope operating at 100 keV promises to minimize the expense and complexity of biological structure research. Although electron cryo-microscopy (cryo-EM) has shown ...

University of Cincinnati structural biologists are the first in the world to visualize a key cell protein as part of newly ...

TEM works by accelerating electrons, typically with energies between 80 and 300 kV, and directing them through a specimen thin enough for electron transmission. Because of their very short wavelength ...

In a study published in ACS Nano, researchers from National Taiwan University report a new expansion microscopy strategy ...

As the global push toward a carbon-neutral society accelerates, understanding how microorganisms metabolize methanol with ...

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