Found 388 results[ Author] Title Type Year
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Immunological Biosensors. The Immunoassay Handbook: Theory and applications of ligand binding, ELISA and related techniques 203 (2013).
In situ mechanical interferometry of matrigel films. Langmuir 25, 36–39 (2008).
High throughput cell nanomechanics with mechanical imaging interferometry. Nanotechnology 19, 235101 (2008).
Atomic force microscope observation of branching in single transcript molecules derived from human cardiac muscle. Nanotechnology 19, 384021 (2008).
Interferometric profiling of microcantilevers in liquid. Optics and Lasers in Engineering 47, 217–222 (2009).
Single molecule transcription profiling with AFM. Nanotechnology 18, 044032 (2007).
Rapid, massively parallel single-cell drug response measurements via live cell interferometry. Biophysical journal 101, 1025–1031 (2011).
Imaging Interferometry for Investigation of Mechanics of Multiple Cells in a Large Field of View. Digital Holography and Three-Dimensional Imaging DMB3 (Optical Society of America, 2008).
Identifying individual DNA species in a complex mixture by precisely measuring the spacing between nicking restriction enzymes with atomic force microscope. Journal of The Royal Society Interface 9, 2341–2350 (2012).
Mechanical interferometry of nanoscale motion and local mechanical properties of living zebrafish embryos. ACS nano 3, 2090–2094 (2009).
Cells in motion: live cell interferometry (LCI). ABSTRACTS OF PAPERS OF THE AMERICAN CHEMICAL SOCIETY 241, (AMER CHEMICAL SOC 1155 16TH ST, NW, WASHINGTON, DC 20036 USA, 2011).
Applications of imaging interferometry. SPIE Optics+ Photonics 629301–629301 (International Society for Optics and Photonics, 2006).
Unoccupied electronic states of graphite as probed by inverse-photoemission and tunneling spectroscopy. Physical Review B 33, 5770 (1986).
Low-temperature scanning tunneling microscopy. Physica B: Condensed Matter 197, 64–71 (1994).
Local inverse photoemission with the scanning tunneling microscope. Surface Science 211, 156–164 (1989).
Field emission scanning Auger microscope (FESAM). Surface Science 189, 36–43 (1987).
Complementary TEM and AFM force spectroscopy to characterize the nanomechanical properties of nanoparticle chain aggregates. Nano letters 4, 2287–2292 (2004).
Characterization of the first in-plane mode of AlN-actuated microcantilevers. SPIE Microtechnologies 80661G–80661G (International Society for Optics and Photonics, 2011).
Proposal for the simulation of electrochemical charge transfer in the scanning tunneling microscope. Journal of electroanalytical chemistry and interfacial electrochemistry 251, 241–245 (1988).
Solvent dynamical effects in scanning tunneling microscopy with a polar liquid in the gap. Journal of electroanalytical chemistry and interfacial electrochemistry 308, 333–337 (1991).
Theoretical aspects and experimental results of STM studies in polar liquids. Journal of Physics: Condensed Matter 3, S121 (1991).
Micromechanical Thermal Gravimetry Performed on one Single Zeolite Crystal. Helvetica Physica Acta 71, 3–4 (1998).
Combination of single crystal zeolites and microfabrication: Two applications towards zeolite nanodevices. Microporous and mesoporous materials 21, 403–409 (1998).
Size-dependent light emission from mass-selected clusters. The European Physical Journal D-Atomic, Molecular, Optical and Plasma Physics 2, 79–82 (1998).
Design and performance analysis of a three-dimensional sample translation device used in ultrahigh vacuum scanned probe microscopy. Journal of Vacuum Science & Technology B 14, 827–831 (1996).
Single crystals of single-walled carbon nanotubes formed by self-assembly. Science 292, 1136–1139 (2001).
Performance advances in interferometric optical profilers for imaging and testing. Journal of Optics A: Pure and Applied Optics 10, 064001 (2008).
Cellular nanomechanics as drug sensitivity marker for ovarian cancer. ABSTRACTS OF PAPERS OF THE AMERICAN CHEMICAL SOCIETY 241, (AMER CHEMICAL SOC 1155 16TH ST, NW, WASHINGTON, DC 20036 USA, 2011).
Correlative nanoscale imaging of actin filaments and their complexes. Nanoscale 5, 5692–5702 (2013).
Molecular Cooperativity of Drebrin< sub> 1-300 Binding and Structural Remodeling of F-Actin. Biophysical journal 103, 275–283 (2012).
Structural-mechanical characterization of nanoparticle exosomes in human saliva, using correlative AFM, FESEM, and force spectroscopy. ACS nano 4, 1921–1926 (2010).
Nanocharacterization in dentistry. International journal of molecular sciences 11, 2523–2545 (2010).
Correlative nanomechanical profiling with super-resolution F-actin imaging reveals novel insights into mechanisms of cisplatin resistance in ovarian cancer cells. Nanomedicine: Nanotechnology, Biology and Medicine 8, 757–766 (2012).
Atomic force microscopy reveals drebrin induced remodeling of f-actin with subnanometer resolution. Nano letters 11, 825–827 (2010).
Nanofilaments on glioblastoma exosomes revealed by peak force microscopy. Journal of The Royal Society Interface 11, 20131150 (2014).
Quantitative nanostructural and single-molecule force spectroscopy biomolecular analysis of human-saliva-derived exosomes. Langmuir 27, 14394–14400 (2011).
Influence of substrates on hepatocytes: a nanomechanical study. Journal of Scanning Probe Microscopy 4, 7–16 (2009).
Benchtop fabrication of memristive atomic switch networks. Journal of nanoscience and nanotechnology 14, 2792–2798 (2014).
A theoretical and experimental study of neuromorphic atomic switch networks for reservoir computing. Nanotechnology 24, 384004 (2013).
Adsorption behavior of HtBDC on Cu (100). ABSTRACTS OF PAPERS OF THE AMERICAN CHEMICAL SOCIETY 233, (AMER CHEMICAL SOC 1155 16TH ST, NW, WASHINGTON, DC 20036 USA, 2007).
Journal of SCANNING PROBE MICROSCOPY. (Submitted).
The following patents were recently issued by the countries in which the inventions were made. For US patents, titles and names supplied to us by the US Patent Office are reproduced exactly as they appear on the original published patent. (Submitted).
Self-organized atomic switch networks. Japanese Journal of Applied Physics 53, 01AA02 (2014).
Emergent Criticality in Complex Turing B-Type Atomic Switch Networks. Advanced Materials 24, 286–293 (2012).
Vertical inertial sliding drive for coarse and fine approaches in scanning probe microscopy. Review of scientific instruments 78, 036110 (2007).
Memristor Networks 173–209 (Springer International Publishing, 2014).
A flexible, highly stable electrochemical scanning probe microscope for nanoscale studies at the solid-liquid interface. Review of Scientific Instruments 79, 103701 (2008).
Unorganized Machines: Emergent Criticality in Complex Turing B-Type Atomic Switch Networks (Adv. Mater. 2/2012). Advanced Materials 24, 142–142 (2012).
Fundamental and practical aspects of differential scanning tunneling microscopy. Journal of Vacuum Science & Technology B 9, 643–647 (1991).