Publications
Effect of surface contamination and pretreatment on the hydrogen diffusion into and out of titanium under plasma conditions. Journal of Nuclear Materials 103, 465–469 (1981).
Comment on" Single Crystals of Single-Walled Carbon Nanotubes Formed by Self-Assembly". Science 300, 1236–1236 (2003).
Instantaneous Mass Profiling of Live Cells via Live Cell Interferometry. Biophysical Journal 102, 563a (2012).
Photon emission experiments with the scanning tunnelling microscope. Journal of Microscopy 152, 325–336 (1988).
Atomic force microscopy study of the structure–function relationships of the biofilm-forming bacterium Streptococcus mutans. Nanotechnology 17, S1 (2006).
Green tea extract selectively targets nanomechanics of live metastatic cancer cells. Nanotechnology 22, 215101 (2011).
Evaluation of bacteria-induced enamel demineralization using optical profilometry. dental materials 25, 1517–1526 (2009).
Nanomechanical properties of glucans and associated cell-surface adhesion of Streptococcus mutans probed by atomic force microscopy under in situ conditions. Microbiology 153, 3124–3132 (2007).
Room temperature supramolecular repositioning at molecular interfaces using a scanning tunneling microscope. Surface science 371, L231–L234 (1997).
A scanning tunneling microscopy investigation of 4, 4′-dimethylbianthrone molecules adsorbed on Cu (111). Surface science 383, 37–49 (1997).
Repositioning of C\_60 molecules on surfaces at room temperature. APS March Meeting Abstracts 1, 2505 (1997).
Room-temperature repositioning of individual C60 molecules at Cu steps: Operation of a molecular counting device. Applied Physics Letters 69, 3016–3018 (1996).
Supramolecular assembly of individual C 60 molecules on a monolayer of 4, 4′-dimethylbianthrone molecules. Applied Physics A: Materials Science & Processing 66, S745–S748 (1998).
Manipulation of C 60 molecules on Cu (111) surfaces using a scanning tunneling microscope. Applied Physics A: Materials Science & Processing 66, S669–S673 (1998).
Epitaxial growth of C 60 on Ag (110) studied by scanning tunneling microscopy and tunneling spectroscopy. Physical Review B 50, 5810 (1994).
Photon Spectroscopy, Mapping, and Topography of 85-Percent Porous Silicon. Journal of Vacuum Science & Technology B 12, 2064–2066 (1994).
Optical Properties of Low Dimensional Silicon Structures 157–162 (Springer Netherlands, 1993).
Photon spectroscopy, mapping, and topography of 85% porous silicon. Journal of Vacuum Science & Technology B 12, 2064–2066 (1994).
Nanostructuring of porous silicon using scanning tunneling microscopy. Journal of Vacuum Science & Technology B 12, 2067–2069 (1994).
Direct observation of individual nanometer-sized light-emitting structures on porous silicon surfaces. EPL (Europhysics Letters) 23, 197 (1993).
Force Sensing in Scanning Tunneling Microscopy. IBM, Rüschlikon 1 (1986).
. Experimental observation of forces acting during scanning tunneling microscopy. Physical review letters 57, 2403 (1986).
Excitation of Fe 1s core-level photoelectrons with synchrotron radiation. Journal of Physics F: Metal Physics 7, L345 (1977).
Micro Total Analysis Systems’ 9 117–120 (Springer Netherlands, 1998).
CSIS-181 Section 1346. (Submitted).
AN ELECTRONIC NOSE BASED ON A MICROMECHANICAL CANTILEVER ARRAY. Micro Total Analysis Systems' 98: Proceedings of the Utas' 98 Workshop, Held in Banff, Canada, 13-16 October 1998 57 (1998).
Stress at the solid-liquid interface of self-assembled monolayers on gold investigated with a nanomechanical sensor. Langmuir 16, 9694–9696 (2000).
Low-temperature ultra-high-vacuum scanning tunneling microscope. Ultramicroscopy 42, 1621–1626 (1992).
Internal structure of C60 fullerence molecules as revealed by low-temperature STM. Applied Physics A 57, 207–210 (1993).
Internal structure of C60 on Au (110) as observed by low-temperature scanning tunneling microscopy. Journal of Vacuum Science & Technology B 12, 2153–2155 (1994).
Photothermal spectroscopy with femtojoule sensitivity using a micromechanical device. Nature 372, 3 (1994).
. CALORIMETRIC SENSOR. (1995).
. CALORIMETRIC SENSOR. (1997).
. . . Nanodiamond and nanoplatinum liquid, DPV576, activates human monocyte-derived dendritic cells in vitro. Anticancer research 30, 4075–4079 (2010).
Biophysical and morphological effects of nanodiamond/nanoplatinum solution (DPV576) on metastatic murine breast cancer cells in vitro. Nanotechnology 25, 465101 (2014).
Modulation of aged murine T lymphocytes in vivo by DPV576-C, a nanodiamond-and nanoplatinum-coated material. in vivo 24, 141–146 (2010).