Dawn A. Bonnell

University of Pennsylvania
United States

D-Index & Metrics D-index (Discipline H-index) only includes papers and citation values for an examined discipline in contrast to General H-index which accounts for publications across all disciplines.

Discipline name Citations Publications World Ranking National Ranking

Materials Science D-index 47 Citations 8,573 233 World Ranking 7847 National Ranking 2051

Research.com Recognitions

Awards & Achievements

2013 - Member of the National Academy of Engineering For development of atomic-resolution surface probes, and for institutional leadership in nanoscience.

2005 - Fellow of the American Association for the Advancement of Science (AAAS)

Overview

What is she best known for?

The fields of study Dawn A. Bonnell is best known for:

Semiconductor
Quantum point contact
Conductance quantum

Adsorption combines with fields such as Desorption and Physisorption in her investigation. She integrates Desorption with Adsorption in her study. Her Atomic force microscopy research extends to the thematically linked field of Nanotechnology. Atomic force microscopy connects with themes related to Nanotechnology in her study. As part of her studies on Optoelectronics, Dawn A. Bonnell often connects relevant subjects like Ferroelectricity. Her study connects Optoelectronics and Ferroelectricity. In her study, Dawn A. Bonnell carries out multidisciplinary Chemical physics and Molecule research. Molecule and Inorganic chemistry are two areas of study in which Dawn A. Bonnell engages in interdisciplinary work. She merges Inorganic chemistry with Organic chemistry in her research.

Her most cited work include:

Controlled fabrication of nanogaps in ambient environment for molecular electronics (262 citations)
Atomic Polarization and Local Reactivity on Ferroelectric Surfaces: A New Route toward Complex Nanostructures (216 citations)
Direct in situ determination of the polarization dependence of physisorption on ferroelectric surfaces (192 citations)

What are the main themes of her work throughout her whole career to date

Dawn A. Bonnell links relevant scientific disciplines such as Ceramic, Scanning electron microscope, Nanometre and Layer (electronics) in the realm of Composite material. Her work blends Scanning electron microscope and Microscopy studies together. Her research on Microscopy frequently links to adjacent areas such as Scanning confocal electron microscopy. Her work on Scanning confocal electron microscopy is being expanded to include thematically relevant topics such as Optics. Her Scanning probe microscopy research extends to the thematically linked field of Optics. In her works, Dawn A. Bonnell conducts interdisciplinary research on Scanning probe microscopy and Scanning ion-conductance microscopy. Her research links Composite material with Layer (electronics). She connects relevant research areas such as Electric field and Electron in the realm of Quantum mechanics. Electron and Quantum mechanics are two areas of study in which she engages in interdisciplinary work.

Dawn A. Bonnell most often published in these fields:

Nanotechnology (70.83%)
Composite material (45.83%)
Metallurgy (45.83%)

This overview was generated by a machine learning system which analysed the scientist’s body of work. If you have any feedback, you can contact us here.

Best Publications

Imaging mechanism of piezoresponse force microscopy of ferroelectric surfaces

Sergei V. Kalinin;Dawn A. Bonnell.
Physical Review B (2002)

570 Citations

Local potential and polarization screening on ferroelectric surfaces

Sergei V. Kalinin;Dawn A. Bonnell.
Physical Review B (2001)

419 Citations

Controlled fabrication of nanogaps in ambient environment for molecular electronics

D. R. Strachan;D. E. Smith;D. E. Johnston;T.-H. Park.
Applied Physics Letters (2005)

400 Citations

Atomic Polarization and Local Reactivity on Ferroelectric Surfaces: A New Route toward Complex Nanostructures

S. V. Kalinin;D. A. Bonnell;T. Alvarez;X. Lei.
Nano Letters (2002)

283 Citations

Direct in situ determination of the polarization dependence of physisorption on ferroelectric surfaces

Dongbo Li;Mosha H. Zhao;J. Garra;A. M. Kolpak.
Nature Materials (2008)

218 Citations

Piezoresponse Force Microscopy: A Window into Electromechanical Behavior at the Nanoscale

Dawn A. Bonnell;Sergei Kalinin;Andrei Kholkin;A. Gruverman.
Mrs Bulletin (2009)

211 Citations

Screening Phenomena on Oxide Surfaces and Its Implications for Local Electrostatic and Transport Measurements

Sergei V. Kalinin;Dawn A. Bonnell.
Nano Letters (2004)

208 Citations

Local impedance imaging and spectroscopy of polycrystalline ZnO using contact atomic force microscopy

Rui Shao;Sergei V. Kalinin;Dawn A. Bonnell.
Applied Physics Letters (2003)

199 Citations

Helical wrapping of single-walled carbon nanotubes by water soluble poly(p-phenyleneethynylene).

Youn K. Kang;One Sun Lee;Pravas Deria;Sang Hoon Kim.
Nano Letters (2009)

193 Citations

Quantitative topographic analysis of fractal surfaces by scanning tunneling microscopy

Morgan W. Mitchell;Dawn A. Bonnell.
Journal of Materials Research (1990)

183 Citations

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