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Scanning Probe Microscopy (SPM) in animated schemes

Scanning Probe Microscopy (SPM) in animated schemes

Basic SPM techniques

Scanning Tunneling Microscopy (STM)

Nanotubes

Atomic lattice of carbon nanotube as visualized by STM

Find more STM images on NT-MDT scan gallery

 

Atomic Force Microscopy (AFM)

Contact  modes  Intermittent- or non-contact modes
 

Samples of AFM images:

Nanotubes
AFM. Molecular resolution
 Eucariots Magnetic films

Carbon nanotubes

Protein molecules

Living cell

Magnetic film

Find tons of high quality AFM images on NT-MDT scan gallery  
 

Advanced techniques

Scanning Near-field Optical Microscopy (SNOM) – optical properties beyond diffraction limit!

diffraction of light

Diffraction of light in the focus of  microobjective lens

mitochondria

Mitochondria dyed with FITC-labeled antibodies (note that resolution of fluorescence image is much better then 200 nm – diffraction limit)

Info about SNOM instrumentation

 

 

Raman Spectroscopy of ultra-high resolution (far beyond diffraction limit)

raman spectroscopy

Effect of TERS (Tip-Enchanced Raman Scattering)
Raman signal becomes several orders of magnitude stronger. Moreover it is confined to the small area around the SPM tip, thus spatial resolution of Raman spectroscopy and Raman imaging occurs tens of nanometers. Compare to about 200 nm (diffraction limit for visible wavelengths).

 

nanotubes TERS

Nanotubes in Raman. Left – confocal Raman image (diffraction-limited). Right – TERS image.
 

TERS imaging provides almost the same resolution as SPM one: branching points of carbon nanotube bundle are clearly seen on both AFM (upper) and TERS (lower) images.
Image courtesy of  Prof. R. Zenobi (ETH Zurich, Switzerland), Dr. G. Hoffman, Dr. J. Loos, (TUE, the Netherlands), and Dr. P. Dorojkin (NT-MDT). Images obtained with the NanoLaboratory NTEGRA Spectra.
 

AFM Tomography



tomography tomography

Cross-section of multi-wall carbon nanotube network embedded in polymer matrix (2.0x2.0 um). Left – phase image, shows local differences in elasticity. Right – spreading resistance image, shows local differences in electrical conductivity.

sd tomography

3D model of the conductive nanotube network within polymer matrix, as reconstructed from series of 22 spreading resistance images. Dimensions of reconstructed volume 2.0x2.0x0.3 um, distance between individual layers (2D images) - 12 nm.

 

Advanced reading

What is important to manipulate single macromolecules (like DNA or nanotubes) with AFM

What is important for MFM - Magnetic Force Microscopy?

Testing of material hardness and elasticity on nanometer scale

NanoLaboratory concept – advantages of SPM-to-non-SPM integration

 

 

 

 
 
 

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