When it comes to analyzing living cells, challenging biological samples and thick, multilayer tissue samples require purposefully designed instrumentation. BioAFMs are ideal when it comes to these ...

Force microscopy is a family of scanning probe microscopy techniques that enable the visualization and manipulation of materials at the nanoscale. These techniques rely on the interaction forces ...

The developed high-speed three-dimensional scanning force microscopy enabled the measurement of 3D force distribution at solid-liquid interfaces at 1.6 s/3D image. With this technique, 3D hydration ...

Atomic force microscopy (AFM) is a method of topographical measurement, wherein a fine probe is raster scanned over a material, and the minute variation in probe height is interpreted by laser ...

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 ...

Conductive atomic force microscopy (C-AFM) is a powerful nanoscale characterization technique that combines the high-resolution imaging capabilities of atomic force microscopy (AFM) with the ability ...

BioAFM is seeing increasingly widespread use in biomedical and biological studies due to its extremely high resolution and its capacity to perform experiments with live cells in liquid and under ...

Atomic Force Microscopy (AFM) has evolved into a central technique in nanotechnology, providing three-dimensional imaging and precise measurements at the atomic scale. Its ability to probe surfaces by ...

Anyone who has ever taken the time to critically examine a walnut knows that a two-dimensional photograph fails in many respects to truly convey the unique features--the nicks, crannies, valleys, and ...

In MFM, a magnetic-coated AFM probe interacts with magnetic field gradients from the sample, causing detectable forces on the probe's cantilever. To focus on magnetic interactions, MFM is often ...