Ultrawide-bandgap semiconductors—such as diamond—are promising for next-generation electronics due to a larger energy gap ...

The basic scheme here is known as confocal laser scanning fluorescence microscopy, where a laser at one wavelength excites fluorescent tags bound to structures in a sample. Light emitted by the ...

Check out the demo after the break. Looking for something to do with the leftover laser diodes from this project? Try making yourself a laser microscope.

A team of researchers at JILA, led by Professors Margaret Murnane and Henry Kapteyn, has developed a groundbreaking ...

The microscope stage is based on an OpenFlexure "Delta" stage, and the confocal optics are constructed with a 3D printed body, some lenses, a 405nm laser, pinhole and photodiode.

The inverted Zeiss CLSM 510 laser scanning confocal microscope is equipped with three PMT detectors, seven laser lines (405, 458, 477, 488, 514, 543, 633 nm), motorized Z-drive and a wide range of ...

Now, scientists have developed a laser-based microscope that allowed them to study this at an unprecedented scale. Diamonds and similar materials have the quality to be transparent in visible and ...

Researchers have built a deep-ultraviolet microscope to study hard-to-analyze materials like diamond, offering a new way to probe their electronic and thermal properties at the nanoscale. This ...

The system delivers unmatched high-speed imaging, essential for capturing the dynamic in vivo response, with fine laser control pinpointing the precise site for optimum excitation efficiency ...

Bruker Corporation announced the launch of the LUMOS™ II ILIM , a quantum cascade laser (QCL) based infrared imaging ...

When laser spectroscopy is combined with microscopy, spatial variations of the chemical compositions of both organic and inorganic samples can be precisely determined. One of the spectroscopic ...