| Atomic de broglie microscope (17) |  |
| Nanogram (11) | |
| Nanometer (654) | |
| Nanometer resolution (12) | |
| Nanometer scale (65) | |
| Nanoscale (737) | |
| Nanoscopic (23) | |
| Subnanometer (7) | |
| Atomic de broglie microscope (17) | |
| Nanogram (11) | |
| Nanometer (654) | |
| Nanometer resolution (12) | |
| Nanometer scale (65) | |
| Nanoscale (737) | |
| Nanoscopic (23) | |
| Subnanometer (7) | |
The research was funded by the National Institute of Biomedical Imaging and Bioengineering and Nanoscope Technologies, LLC n
With the help of these nanoscopes researchers have been able to visualize molecules such as those created in synapses in the brain.
#Dresden Nanoscope Combines Microscopy and Ultra-Fast Spectroscopy for Precise Filming of Dynamic Processes To gain even deeper insights into the smallest of worlds,
Time increments from a few quadrillionths of a second (femtoseconds) up to the second range can be selected for individual images. his makes our nanoscope suitable for viewing ultra-fast physical processes as well as for biological process,
Combining two methods guarantees high spatial and temporal resolutionthe nanoscope is based on the further development of near-field microscopy
the teams led by the two Dresden physicists have managed to combine all the advantages of both methods in their nanoscope. e have developed software with a special demodulation technology with whichn addition to the outstanding resolution of near-field
The clever electronic method enables the nanoscope to exclusively record only the changes actually occurring in the sample's properties due to the excitation.
Although other research groups have reported only recently good temporal resolution with their nanoscopes they could not,
Universal in every respectith our nanoscope considerable wavelength coverage, dynamic processes can be studied with the best suited wavelengths for the specific process under study.
The Dresden nanoscope is universally adaptable to respective scientific questions. The probe pulse wavelengths can,
"This makes our nanoscope suitable for viewing ultra-fast physical processes as well as for biological process, which are often very slow,
Combining two methods guarantees high spatial and temporal Resolution The nanoscope is based on the further development of near-field microscopy, in
the teams led by the two Dresden physicists have managed to combine all the advantages of both methods in their nanoscope."
The clever electronic method enables the nanoscope to exclusively record only the changes actually occurring in the sample's properties due to the excitation.
Although other research groups have reported only recently good temporal resolution with their nanoscopes, they could not, however,
Universal in every respect"With our nanoscope's considerable wavelength coverage, dynamic processes can be studied with the best suited wavelengths for the specific process under study.
The Dresden nanoscope is universally adaptable to respective scientific questions. The probe pulse wavelengths can,
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