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Company Information:

Company Name: Intraband LLC
City: Madison
State: WI
Zip+4: -
Woman-Owned: No
Minority-Owned: No
HUBZone-Owned: No
Website URL: N/A
Phone: N/A

Award Totals:

Program/Phase Award Amount ($) Number of Awards
STTR Phase I $479,601.00 4
STTR Phase II $971,449.00 2

Award List:

On-Chip Passive Phase-Locking for High Coherent Power, Mid-IR Quantum Cascade Lasers

Award Year / Program / Phase: 2010 / STTR / Phase I
Agency / Branch: DOD / ARMY
Research Institution: University of Wisconsin-Madison
Principal Investigator: Dan Botez, Member
Award Amount: $99,999.00
RI Contact: Kim Moreland
Abstract:
The technical objectives of this proposal are: 1) the design of 8 micron-emitting active-photonic-crystal (APC) quantum-cascade (QC) lasers by using passive phase-locking in a monolithic structure in order to achieve multiwatt-range, diffraction-limited powers; and 2) the development of the key… More

Monolithic Scalable Mid-Infrared Phase-Locked Laser Array

Award Year / Program / Phase: 2011 / STTR / Phase I
Agency / Branch: DOD / NAVY
Research Institution: University of Wisconsin-Madison
Principal Investigator: Luke Mawst, Member – (608) 332-2520
Award Amount: $149,883.00
RI Contact: Kim Moreland
Abstract:
The technical objectives of this proposal are: 1) the design of 3.8-4.2 micron-emitting, active-photonic-crystal (APC) quantum-cascade (QC) lasers by using passive phase-locking in a monolithic structure in order to achieve multiwatt-range, diffraction-limited powers; and 2) the development of the… More

High-Power, Continuous-Wave 3.0- to 3.5-Micron Emitting Quantum Cascade Semiconductor Laser

Award Year / Program / Phase: 2012 / STTR / Phase I
Agency / Branch: DOD / NAVY
Research Institution: University of Wisconsin-Madison
Principal Investigator: Luke Mawst, Professor – (608) 332-2520
Award Amount: $149,890.00
RI Contact: Kim Moreland
Abstract:
The technical objectives of this proposal are: 1) the design of 3.0-3.5 micron-emitting quantum cascade laser (QCL) structures grown on metamorphic-buffer-layer (MBL) substrates; 2) the realization of electroluminescent QCL structures on MBLs with emission in the 3.0-3.5-micron wavelength range.… More

On-Chip Passive Phase-Locking for High Coherent Power, Mid-IR Quantum Cascade Lasers

Award Year / Program / Phase: 2012 / STTR / Phase II
Agency / Branch: DOD / ARMY
Research Institution: University of Wisconsin-Madis
Principal Investigator: Dan Botez, Member – (608) 265-4643
Award Amount: $749,714.00
RI Contact: Kim Moreland
Abstract:
The technical objectives of this proposal are: 1) Implement the design developed in Phase I for the realization of 8 micron-emitting active-photonic-crystal (APC) quantum-cascade (QC) lasers of 3 W average, diffraction-limited power and 15 % wallplug efficiency in quasi-CW operation; 2) Design and… More

Surface-Emitting, Monolithic Beam-Combined Mid-Wave IR Quantum Cascade Lasers

Award Year / Program / Phase: 2013 / STTR / Phase I
Agency / Branch: DOD / NAVY
Research Institution: University of Wisconsin-Madison
Principal Investigator: Dan Botez, Professor – (608) 265-4643
Award Amount: $79,829.00
RI Contact: Kim Moreland
Abstract:
The technical objectives of this proposal are: (1) design a grating-coupled surface-emitting (GCSE) active-photonic-crystal (APC) 4.6 micron-emitting quantum-cascade laser (QCL) to deliver 15 W diffraction-limited CW power in the main lobe of the far-field beam pattern; (2) design a GCSE-APC QCL… More

Monolithic Scalable Mid-Infrared Phase-Locked Laser Array

Award Year / Program / Phase: 2013 / STTR / Phase II
Agency / Branch: DOD / NAVY
Research Institution: University of Wisconsin-Madison
Principal Investigator: Luke Mawst, Professor – (608) 332-2520
Award Amount: $221,735.00
RI Contact: Kim Moreland
Abstract:
The technical objectives of this proposal are: 1) Design a metal/semiconductor grating-based (i.e., substrate-emitting) Grating-Coupled Surface-Emitting Distributed Feedback Quantum Cascade Laser (GCSE-DFB QCL) emitting at 4.6 microns with high beam quality; and 2) Demonstrate a GCSE-DFB QCL… More