Chad Waltz scite author profile

Chad Waltz

3Publications

23Citation Statements Received

100Citation Statements Given

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Affiliations

Naval Air Warfare Center Weapons Division, Jet Propulsion Laboratory

Publications

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Electron Tunneling through Fluid Solvents

2007

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Despite the biological, chemical, and physical importance of electron tunneling across noncovalent matrices, relatively little is known about the ability of the various nonbonding interactions (hydrogen-bonding and van der Waals forces) to mediate charge transfer. Herein, we report the steady-state current-voltage (I-V) profiles of nanometer junctions filled with water and a variety of organic solvents. The maximum currents for the solvents studied span 6 orders of magnitude. The I-V data can be reasonably fit to a simple electron tunneling model with a rectangular energy barrier representing the solvent. Protic solvents provide the smallest barrier heights (greatest tunneling currents), and nonpolar solvents exhibit the largest energy barriers (lowest currents). Trends in the barrier heights with the strength of the solvent-solvent interactions (hydrogen-bonding < dipoledipole < dispersion interactions) indicate that the solvent's cohesive energy largely determines/limits the barrier heights of the fluid systems rather than the electronic structure of the solvent molecule (e.g., electron affinity or ionization potential). These results demonstrate that facile electron tunneling through nonbonding media must be accompanied by relatively strong intermolecular interactions.

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Multi-Functional Electroactive Polymers (EAPs) as Alternatives for Cadmium Based Coatings

Zarras

Guenthner

Irvin

et al. 2010

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Free Standing Nanocrossbar Arrays with Molecular Throughput

Prokopuk¹,

Son²,

Waltz³

2010

Nanosci Nanotechnol Lett

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We report a new approach for fabricating vacant nanocrossbar arrays using a combination of lithography and selective chemical etch. Two parallel arrays of gold wires are lithographically patterned orthogonal to each other with a chromium layer (2-5 nm thick) sandwiched between the wire arrays. A silicon oxide mesh is sputtered over the metal ensemble leaving the crossing points free of the oxide layer. The chromium layer is subsequently removed via selective chemical etch leaving a gold architecture with vertical separations that are on the order of a few nanometers. The silicon oxide mesh anchors the gold wires in place creating a robust nanoarchitecture. The nanogaps can be filled with fluids resulting in a change of the junction's resistance. The variability in the vertical separations between the wires within an array is only a few Angstroms. These results demonstrate that molecular-sized gaps can be created without the use of a molecular template.

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Chad Waltz

Electron Tunneling through Fluid Solvents

Multi-Functional Electroactive Polymers (EAPs) as Alternatives for Cadmium Based Coatings

Free Standing Nanocrossbar Arrays with Molecular Throughput

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