Timp, Gregory L.
Gregory Timp American academic
Timp, Gregory
![Sudoc [ABES], France](/viaf/images/flags/SUDOC.png "Sudoc [ABES], France")
VIAF ID: 69768379 (Personal)
Permalink: http://viaf.org/viaf/69768379
Preferred Forms
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Gregory Timp
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American academic
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100 1 _ ‡a Timp, Gregory
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Timp, Gregory
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Timp, Gregory L
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100 1 _ ‡a Timp, Gregory L
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100 1 _ ‡a Timp, Gregory L.
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100 1 _ ‡a Timp, Gregory L.
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100 1 _
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Timp, Gregory L.
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100 1 _
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Timp, Gregory L.
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100 1 0
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Timp, Gregory L.
4xx's: Alternate Name Forms (15)
Works
| Title | Sources |
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| Analyzing the forces binding a restriction endonuclease to DNA using a synthetic nanopore |
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| Beyond mass spectrometry, the next step in proteomics |
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| Beyond the Gene Chip |
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| Biological noise abatement: coordinating the responses of autonomous bacteria in a synthetic biofilm to a fluctuating environment using a stochastic bistable switch |
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| Chapter 3: When Does a Wire Become an Electron Waveguide |
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| Detection of DNA sequences using an alternating electric field in a nanopore capacitor |
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| Direct, concurrent measurements of the forces and currents affecting DNA in a nanopore with comparable topography |
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| Direct visualization of single-molecule translocations through synthetic nanopores comparable in size to a molecule |
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| The electromechanics of DNA in a synthetic nanopore |
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| The electronic structure at the atomic scale of ultrathin gate oxides |
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| Epigenetic memory emerging from integrated transcription bursts |
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| Exploring the Prospects for a Nanometer-scale Gene Chip |
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| Fingerprinting Single Living Cells with Molecular Precision |
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| Gene Expression in Electron-Beam-Irradiated Bacteria in Reply to "Live Cell Electron Microscopy Is Probably Impossible". |
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| High-yield transfer printing of metal-insulator-metal nanodiodes |
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| Imaging in real-time with FRET the redox response of tumorigenic cells to glutathione perturbations in a microscale flow. |
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| Jamming prokaryotic cell-to-cell communications in a model biofilm |
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| Laser-guided assembly of heterotypic three-dimensional living cell microarrays |
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| Live Bacterial Physiology Visualized with 5 nm Resolution Using Scanning Transmission Electron Microscopy |
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| Live cell lithography: using optical tweezers to create synthetic tissue |
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| Measurements of the size and correlations between ions using an electrolytic point contact |
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| Molecular diagnostics for personal medicine using a nanopore |
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| Nanopore Sequencing: Electrical Measurements of the Code of Life |
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| Nanotechnology |
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| Optical manipulation of silicon microparticles in biological environments |
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| Optimal optical trap for bacterial viability |
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| Optimal profile for a Gaussian standing-wave atom-optical lens |
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| Reading the primary structure of a protein with 0.07 nm |
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| Simulation of the electric response of DNA translocation through a semiconductor nanopore–capacitor |
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| Single-molecule protein identification by sub-nanopore sensors |
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| Sizing DNA using a nanometer-diameter pore |
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| Slowing the translocation of double-stranded DNA using a nanopore smaller than the double helix |
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| Small-Signal Performance and Modeling of sub-50nm nMOSFETs with f above 460-GHz |
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| Stretching and unzipping nucleic acid hairpins using a synthetic nanopore |
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| The structural, electronic, and lattice ... c1983 |
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| Synthetic Capillaries to Control Microscopic Blood Flow |
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| Think Small: Nanopores for Sensing and Synthesis |
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| Using a nanopore for single molecule detection and single cell transfection. |
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| Wiring Together Synthetic Bacterial Consortia to Create a Biological Integrated Circuit |
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