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Technology for Producing GaAsP Transparent Photocathodes
Navy SBIR FY2006.3
| Sol No.: |
Navy SBIR FY2006.3 |
| Topic No.: |
N06-166 |
| Topic Title: |
Technology for Producing GaAsP Transparent Photocathodes |
| Proposal No.: |
N063-166-0019 |
| Firm: |
Physical Optics Corporation
Applied Technologies Division
20600 Gramercy Place, Bldg 100
Torrance, California 90501-1821 |
| Contact: |
Michael Reznikov |
| Phone: |
(310) 320-3088 |
| Web Site: |
www.poc.com |
| Abstract: |
To address the Navy need for an innovative process to fabricate gallium arsenide phosphide (GaAsP) photocathodes to improve photosensor performance parameters including wide dynamic range, uniform QE, reduced cost, and high yield, Physical Optics Corporation (POC) proposes to develop a new process for fabricating GaAsP transparent photocathodes directly on glass substrates. The process is based on new, highly efficient fabrication of GaAsP photocathode directly on an n-type silicon layer. Elimination of bonding to the glass substrate and etching of an initial wafer precludes the distortion of photocathode structure and facilitates integrity thus increasing the yield and enhancing quantum efficiency. The process offers better integrity of the photocathode structure, with reduced stress; improved dynamic range, quantum efficiency, and photocathode uniformity; and increased production yield. Photocathode produced by the new process will then be tested in an existing photodevice. In Phase I POC will demonstrate the feasibility of this innovative process and develop a detailed plan for its implementation in the fabrication of existing photodevices. In Phase II POC will conduct a detailed investigation of each production step, implement the innovative process photodevice fabrication, and demonstrate the parameters of the GaAsP photocathode in the device selected. |
| Benefits: |
The proposed photocathodes can be used in the imaging industry; in charge-coupled device sensors and cameras, night vision goggles, and photomultipliers; and for photocontrolled electron beam sources in semiconductor devices and electronic guns. Future applications for photocathode-based systems include high-intensity picosecond pulsed lasers used to produce trains of extremely high current, which may be used for wireless communications in microwave- and millimeter-wave devices. |
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