Photonic and Quantum Interactions of Atomic-Scale Junctions

Metadata Updated: March 22, 2019

In this proposal, the fundamental quantum and photonic interactions of bimetallic atomic-scale junctions (ASJs) will be explored, with three major space technology-related applications in focus: 1) chemical sensing, 2) smart/metamaterials, and 3) memristor-based computing. An ASJ is a type of quantum-point contact, created by electrochemically depositing silver between two nanoscale electrodes. This connection can be formed and destroyed by applying the appropriate voltage potential across the electrodes, and thus controlled to the point where the junction narrows to the width of a single atom. At this point, the junction can exhibit a phenomenon known as quantized conductance.  In this region, the junction is especially sensitive to disturbances in the surrounding environment. Previous research has demonstrated the potential of a single ASJ in sensing chemicals bound to the junction at this narrowest section; this proposal will extend on that work by examining parallel and serial arrays of ASJs for chemical sensing and memristive computing, as well as the interaction of the junctions in 3-dimensional configurations with light for metamaterials.

The objectives of this project are to establish control over junction growth in massively parallel arrays both through direct electrical contact and with photo-induced charging, then utilize this control to examine the potential application of these junctions in the areas described above. Junctions will be created using electrochemical deposition between conductive electrodes, which may be lithographically-defined macroscale electrodes on a wafer, a conductive AFM tip, or nanoparticles stimulated with focused lasers.

Achieving these objectives would be highly significant to both NASA and the community at large. Due to the junctions' small space and weight, a massively parallel array of junctions would not take up more than a few square millimeters of area on a silicon wafer yet could perform a wide array of functions; thus, they are ideally suited to the tight weight and size requirements of terrestrially-launched space missions. The applications of ASJs in chemical sensing and memristor-based neural network applications could allow for new experiments and data analysis not possible with existing technology. In addition, the fundamental insights into quantum and photonic phenomena gained by devices that operate at room-temperature and under simple conditions would also greatly benefit the scientific community and science education.

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Public: This dataset is intended for public access and use. License: U.S. Government Work

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Dates

Metadata Created Date August 1, 2018
Metadata Updated Date March 22, 2019

Metadata Source

Harvested from NASA Data.json

Additional Metadata

Resource Type Dataset
Metadata Created Date August 1, 2018
Metadata Updated Date March 22, 2019
Publisher Space Technology Mission Directorate
Unique Identifier TECHPORT_88539
Maintainer
TECHPORT SUPPORT
Maintainer Email
Public Access Level public
Bureau Code 026:00
Metadata Context https://project-open-data.cio.gov/v1.1/schema/catalog.jsonld
Metadata Catalog ID https://data.nasa.gov/data.json
Schema Version https://project-open-data.cio.gov/v1.1/schema
Catalog Describedby https://project-open-data.cio.gov/v1.1/schema/catalog.json
Datagov Dedupe Retained 20190322035503
Harvest Object Id cd025767-cbb3-47af-8d31-cad250eba8c5
Harvest Source Id 39e4ad2a-47ca-4507-8258-852babd0fd99
Harvest Source Title NASA Data.json
Data First Published 2020-08-01
Homepage URL https://techport.nasa.gov/view/88539
License http://www.usa.gov/publicdomain/label/1.0/
Data Last Modified 2018-07-19
Program Code 026:027
Source Datajson Identifier True
Source Hash a6bfdb1a20acf7806beeecedf5c15a50335cff69
Source Schema Version 1.1

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