Scientists at Weill Cornell Medicine have developed a computational technique that greatly increases the resolution of atomic force microscopy, a specialized type of microscope that "feels" the atoms ...

Atomic force microscopy reveals three distinct dynamic states in individual polymer chain segments on surfaces, challenging ...

Atomic force microscopy (AFM) has evolved into a pivotal tool for investigating surfaces at the nanometre scale, providing detailed insight into both topographical and mechanical characteristics. This ...

First invented in 1985 by IBM in Zurich, Atomic Force Microscopy (AFM) is a scanning probe technique for imaging. It involves a nanoscopic tip attached to a microscopic, flexible cantilever, which is ...

This handbook illustrates the wide variety of operating modes available on Bruker AFMs, going well beyond the standard high‑resolution topographic imaging capabilities of AFM. The modes are broken ...

Nanomechanical systems have now reached a level of precision and miniaturization that will allow them to be used in ultra-high-resolution atomic force microscopes in the future. (Nanowerk News) ...

Invented 30 years ago, the atomic force microscope has been a major driver of nanotechnology, ranging from atomic-scale imaging to its latest applications in manipulating individual molecules, ...

The Park FX40 Automatic Atomic Force Microscope (AFM) System is capable of high spatial resolution surface mapping and is equipped with a True Non-Contact TM mode capable of nanoscale surface analysis ...

The Asylum Research MFP-3D Origin+ Atomic Force Microscope offers high-resolution imaging, supports large samples, and comes with a full range of imaging modes and accessories. Cantilevers are located ...

Atomic force microscopy (AFM) is a way to investigate the surface features of some materials. It works by “feeling” or “touching” the surface with an extremely small probe. This provides a ...

Not all defects are visible with the same microscope. Explore how resolution, contrast, and signal interpretation shape ...