Electron microscopy has evolved into a suite of sophisticated techniques essential for investigating the structure and properties of materials at the nanoscale and beyond. By utilising focused ...

The rapid evolution of microscopy techniques has transformed our ability to visualise biological structures and processes at unprecedented resolutions. Advances in live‐cell imaging, super‐resolution ...

One variation of electron microscopy is transmission electron microscopy (TEM). In a TEM experiment, the electron beam passes through the sample and the electrons are directly imaged onto an electron ...

Sensing: point-of-care sensors, mobile-phone enabled sensors, field-based sensing and measurement systems with applications in mobile health and telemedicine, environmental monitoring (for example, ...

In this article, we look at some of the key developments of various microscopy techniques over the last few years and how they have benefitted different areas of research and development. The impact ...

Fluorescence laser scanning confocal microscopy enables neuroscientists to obtain three-dimensional images of neurons at extremely high resolution. The pinhole of 1 airy unit (1 AU) cuts out ...

While not all microscopy samples can fluoresce, all can scatter light, and this scattered light can be imaged. This has resulted in the development of scattering microscopy techniques, such as ...

A team of medical researchers at Charité has analyzed damage by focused high energetic X-rays in bone samples from fish and mammals at BESSY II. With a combination of microscopy techniques, the ...

Virtual apertures let researchers isolate and solve atomic structures from individual nanocrystals embedded in dense clusters, providing valuable new data for energy and pharmaceutical applications.