SBIR-STTR Award

Closed-Loop, Real-Time, Growth-to-Device Semiconductor Modeling
Award last edited on: 4/30/2007

Sponsored Program
STTR
Awarding Agency
DOD : AF
Total Award Amount
$849,941
Award Phase
2
Solicitation Topic Code
AF05-T003
Principal Investigator
Mahmoud Fallahi

Company Information

Nonlinear Control Strategies Inc (AKA: NLCSTR)

3542 North Geronimo Avenue
Tucson, AZ 85705
   (520) 888-5920
   s.dicosola@nlcstr.com
   www.nlcstr.com

Research Institution

----------

Phase I

Contract Number: ----------
Start Date: ----    Completed: ----
Phase I year
2005
Phase I Amount
$99,984
Semiconductor amplifiers and lasers are pervasive as critical components in modern day military and commercial technologies. High quality semiconductor wafer growth can now produce heterostructures of very high quality with stoichiometrically correct growth of individual mono-layers. Despite these significant advances in MBE and MOCVD growth technologies, a critical void remains in predicting the performance of final packaged functional amplifier or laser devices. The lack of predictive semiconductor device design and growth monitoring capability can be traced to the extreme complexity of calculating the semiconductor optical response from first principles. Parallel progress in basic research over the past decade has led to the emergence of the first fully predictive theory of the optical properties of semiconductor heterostructures. A Nonlinear Control Strategies /University of Arizona collaborative project proposes to develop robust commercial PC-based software tools built on such microscopically computed optical gain databases. Individual modules will aid in semiconductor epi design, growth monitoring and overall functional device optimization. Such closed-loop software tools applicable to a broad class of material systems, will enable the laser designer and materials grower to fast track from device design concept through growth to the final packaged device, thereby avoiding costly and wasteful material re-growth and packaging cycles

Phase II

Contract Number: ----------
Start Date: ----    Completed: ----
Phase II year
2006
Phase II Amount
$749,957
Semiconductor amplifiers and lasers are pervasive as critical components in modern day military and commercial technologies. High quality semiconductor wafer growth can now produce heterostructures of very high quality with stoichiometrically correct growth of individual mono-layers. Despite these significant advances in MBE and MOCVD growth technologies, a critical void remains in predicting the performance of final packaged functional amplifier or laser devices. The lack of predictive semiconductor device design and growth monitoring capability can be traced to the extreme complexity of calculating the semiconductor optical response from first principles. Parallel progress in basic research over the past decade has led to the emergence of the first fully predictive theory of the optical properties of semiconductor heterostructures. A Nonlinear Control Strategies /University of Arizona collaborative project proposes to develop robust commercial PC-based software tools built on such microscopically computed optical gain databases. Individual modules will aid in semiconductor epi design, growth monitoring and overall functional device optimization. Such closed-loop software tools applicable to a broad class of material systems, will enable the laser designer and materials grower to fast track from device design concept through growth to the final packaged device, thereby avoiding costly and wasteful material re-growth and packaging cycles

Keywords:
Semiconductor Materials,Wafer Growth,Optical Gain/Absorption,Active Materials,Software Design Tools,