SBIR-STTR Award

Coherent THz Sources and Amplifiers Using Carbon Nanotubes
Award last edited on: 3/29/2019

Sponsored Program
STTR
Awarding Agency
NSF
Total Award Amount
$595,041
Award Phase
2
Solicitation Topic Code
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Principal Investigator
Christian Drouet d'Aubigny

Company Information

TeraVision Inc

1815 West Gardner Lane
Tucson, AZ 85705
   (800) 670-8357
   info@teravision-inc.com
   www.teravision-inc.com

Research Institution

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Phase I

Contract Number: ----------
Start Date: ----    Completed: ----
Phase I year
2006
Phase I Amount
$98,336
This Small Business Technology Transfer (STTR) Phase I reseacrch project will ascertain the technical feasibility of fabricating practical traveling-wave tube (TWT) amplifiers and oscillators at THz frequencies. Preliminary research in this area suggests that by combining recent advances in carbon nanotube technology with those in the field of micromachining, practical THz TWT devices can be realized. Such devices will spur the development of a new family of THz components. The proposed technical approach builds on principles proven at other wavelengths and leverages from the experience and equipment available through collaborations between the proposing company, industry leaders and the University of Arizona. If successful the results from the proposed research will lead to THz components and devices that can be used in applications ranging from communications and remote sensing to medical imaging. The proposed work will serve as the research focus for 1 graduate and 1 undergraduate student at the University of Arizona.

Phase II

Contract Number: ----------
Start Date: ----    Completed: ----
Phase II year
2007
Phase II Amount
$496,705
This Small Business Technology Transfer (STTR) Phase II research project will design and develop practical traveling-wave tube (TWT) amplifiers and oscillators at THz frequencies. During Phase II the research team will 1) optimize the design for low noise operation, 2) add a tuned feedback loop to the 0.345 THz TWT so the unit can function as a stand-alone oscillator, 3) based upon the experience gained at 0.345 THz, develop a detailed design for a TWT for higher frequency operation (e.g. 0.65, 0.82, and 1.5 THz where atmospheric absorption by water is at its minimum at THz frequencies), and 4) package a THz TWT for a wide variety of commercial uses. The proposed developments will increase the coherent output power available at frequencies above ~200GHz by orders of magnitude, while dramatically reducing the cost per milliwatt. The work will also provide a path for the realization of the first THz low-noise amplifiers. If successful the results from the proposed research will lead to the availability of signal sources and amplifiers capable of yielding orders of magnitude more coherent power in the THz regime than is currently available. The devices coming out of the effort will lead to THz components and devices that can be used in applications ranging from communications and remote sensing to medical imaging. . Potential end-users include NASA, aerospace companies, telecommunication companies, the security industry, companies engaged in the development of medical imaging systems, and the military