Ana Andrade has abstracted the smallest fragment of the landscape, which were later
developed by a microscope, making visible the most invisible particles of Playas de Tijuana.
Not exact matches
Veeraraghavan said SAVI leans on work
by the California Institute of Technology and the University of California, Berkeley, which
developed the Fourier ptychography technique that allows
microscopes to resolve images beyond the physical limitations of their optics.
They proposed a new way to study a cuprate, one that no other group had tried: a powerful imaging technique
developed by Davis, called sublattice imaging - which is performed using a specialized scanning tunneling
microscope (STM) capable of determining the electronic structure in different subsets of the atoms in the crystal, the so - called sublattices.
Specifically, the MPI / Wyss Institute team
developed the technique for «Spinning Disk Confocal» (SDC)
microscopes that detect fluorescence signals from an entire plane all at once
by sensing them through a rotating disc with multiple pinholes.
Instead of approaching the problem
by creating better imaging software that helps to increase the resolution after the fact, as most high resolution
microscopes do, Shroff and his lab
developed a
microscope with better lenses and mirrors so that the higher resolution is captured in the original image.
The researchers
developed a novel algorithm that can recover the phase information from a stack of bright - field images taken
by a classical
microscope.
A collaborative team led
by researchers from Osaka University has therefore
developed an optical system for use in full - field X-ray
microscopes that offers a more practical way to overcome the chromatic aberration problem.
The technique,
developed by two separate research groups, one at Princeton led
by Thomas Gregor, associate professor of physics and the Lewis - Sigler Institute for Integrative Genomics, and the other led
by Nathalie Dostatni at the Curie Institute in Paris, involves placing fluorescent tags on RNA molecules to make them visible under the
microscope.
Together with Professor Philipp Mayer, who is presently employed at the Technical University of Denmark (DTU), she has
developed a new test setup that allows exposing the ciliates to a concentration gradient while concurrently enabling their observation through a
microscope in real time and measuring the transport of PAH
by means of chromatographic methods.
In recognition of their work in
developing the scanning confocal
microscope to the point where it is used in hundreds of research laboratories worldwide and reveals microstructures not discernible
by other methods.
First
developed by Nobel Laureate Dr. Eric Betzig, the 3i Lattice LightSheet
microscope is capable of imaging biological systems spanning four orders of magnitude in space and time.
Ever since the 1980s, when Gerd Binnig of IBM first heard that «beautiful noise» made
by the tip of the first scanning tunneling
microscope (STM) dragging across the surface of an atom, and he later
developed the atomic force
microscope (AFM), these microscopy tools have been the bedrock of nanotechnology research and development.
Now, Rosso and teams at PNNL, EMSL, the Environmental Molecular Sciences Laboratory, a DOE Office of Science User Facility at PNNL, and the University of Pittsburgh
developed a new approach
by combining an environmental transmission electron
microscope, called an ETEM, with nanocrystal force probes that allows scientists to watch crystals interact in a life - like situation.
A French and Japanese research group has
developed a new way of visualizing the atomic world
by turning data scanned
by an atomic force
microscope into clear color images.
By taking multiple images of the iron - platinum nanoparticle with an advanced electron
microscope at Lawrence Berkeley National Laboratory and using powerful reconstruction algorithms
developed at UCLA, the researchers determined the precise three - dimensional arrangement of atoms in the nanoparticle.
An international research team led
by Mats Nilsson at Uppsala University and Stockholm University / SciLifeLab has
developed a small, 3D - printed
microscope that is connected to an ordinary cell phone.
The project was born in 2011, when Golshani read about a miniaturized
microscope developed at Stanford University that was light enough to be worn
by a laboratory mouse.