Sentences with phrase «scanning probe microscopy»
During the last 10 years he contributed primarily to the emerging field of time and space resolved (photo) chemistry including scanning probe microscopy, optical microscopy and single molecule spectroscopy., He has published over 600 papers.
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This will require the cooperative efforts of researchers across a wide range of disciplines: scanning probe microscopy, supramolecular chemistry, protein engineering, self assembly, robotics, materials science, computational chemistry, self replicating systems, physics, computer science, and more.
Adding FluidFM ® enables measurements up to 50nN and even higher, giving us a broader range of force control than with any other instrument - scanning probe microscopy (SPM) combination.
Imaging via complete cantilever dynamic detection: general dynamic mode imaging and spectroscopy in scanning probe microscopy This article appears in the collection Nanotechnology Focus on Scanning Probe Microscopy Presenter: Sergei Kalinin
He brings a variety of in situ and ex situ characterization methods to bear on the these materials, including high - resolution x-ray and ultraviolet photoelectron spectroscopy, x-ray diffraction, Rutherford backscattering, scanning transmission electron microscopy, electron energy loss spectroscopy, atom probe tomography and scanning probe microscopy.
Sergei Kalinin describes the impact of the development of data - controlled scanning probe microscopy and the future of big, deep and smart data approaches in the field.
His research interests are focussed on scanning probe microscopy and high resolution optical instrumentation.
As shown by Pacific Northwest National Laboratory's Dr. Michael Henderson and Dr. Igor Lyubinetsky in their invited review article, using scanning probe microscopy techniques, in particular scanning tunneling microscopy or STM, allows scientists to understand fundamental interactions that are key to our energy future.
In the article, Henderson and Lyubinetsky highlight the growing use of scanning probe microscopy techniques.
This image of a growing crystal demonstrates the resolving power of scanning probe microscopy, a newly - emerging method of surface imaging.
«In contrast to many other forms of scanning probe microscopy, scanning quantum dot microscopy can even work at a distance of several nanometres.
Scanning probe microscopy (SPM) resolves only surface features, and transmission electron microscopy is limited to samples readily traversed by electrons.
This detailed assessment called into question the previous identification of ferroelectric materials based solely on scanning probe microscopy (SPM).
Scientists have imaged and manipulated ferroelectric properties using a particular type of scanning probe microscopy called piezo - response force microscopy (PFM).
Not exact matches
To probe further, Bello and her colleagues examined the remains using two types of microscopy: scanning electron and focus variation microscopy.
In atomic force microscopy (AFM), a silicon probe scans across a surface and builds a 3D image of the cells it encounters, much like someone reading a relief map with their fingers.
The experiment is based on atomic force microscopy where sample surfaces are scanned with the apex of a needle - like probe.
Jacobs» team precisely measured the friction between silicon dioxide (SiO2) layers of different thicknesses and the 200 - nm tip of an atomic force microscopy probe by carefully scanning the tip across the wafer surface.
To characterize the threads and strips, the researchers combined high - resolution scanning electron microscopy, electron back - scattered diffraction with energy - dispersive electron probe microanalysis and other analytical methods.
The researchers then used a dynamic force - scanning probe microscope for single - molecule force spectroscopy as well as antibody - recognition force microscopy (Ig - RFM) to map the locations of MtrC and OmcA on the surface of live Shewanella cells.
materials characterization by atomic force scanning probe and electron microscopy, spectrophotometry, custom apparatus for measurement of electrical and thermal transport properties (superconductors) at low temperatures
The research team consisting of Oscar Custance and Tomoko Shimizu, group leader and senior scientist, respectively, at the Atomic Force Probe Group, NIMS, Daisuke Fujita and Keisuke Sagisaka, group leader and senior researcher, respectively, at the Surface Characterization Group, NIMS, and scientists at Charles University in the Czech Republic, Autonomous University of Madrid in Spain, and other organizations combined simultaneous atomic force microscopy (AFM) and scanning tunneling microscopy (STM) measurements with first - principles calculations for the unambiguous identification of the atomic species at the most stable surface of the anatase form of titanium dioxide (hereinafter referred to as anatase) and its most common defects.
This technique is faster and provides a wider field of view than more traditional 3D techniques such as scanning electron microscopy combined with electron energy - loss spectrometry or atom probe tomography.
To celebrate the 30th anniversary of the Nobel Prize in scanning tunnelling microscopy (STM) and the 30th anniversary since the first paper in atomic force microscopy (AFM), Nanotechnology ™ has been organising a focus collection with guest editors Franz Giessibl, Rodolfo Miranda and Johannes Barthes to collate some of the latest cutting - edge progress developing and exploiting these scanning probe techniques.
Acronyms: XRF = x-ray fluoresencence; RBS = Rutherford Backscattering; XRD = x-ray diffraction; SEM = scanning electron microscopy; AFM = atomic force microcopy; PES = photoelectron spectroscopy, with x-rays (XPS) and ultraviolet (UPS); KP = Kelvin probe measurements, SECM = scanning electrochemical microscopy, PL = photoluminescence; FTIR = Fourier transform infrared spectroscopy
Led by the Cavanilles Institute of Biodiversity and Evolutionary Biology at the University of Valencia in Spain, the researchers used confocal laser - scanning microscopy (CLSM) to probe the anatomy and reproductive biology of the pathogens.