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High Energy Fiber Laser Components
Navy SBIR 2018.1 - Topic N181-080 ONR - Ms. Lore-Anne Ponirakis - [email protected] Opens: January 8, 2018 - Closes: February 7, 2018 (8:00 PM ET)
TECHNOLOGY AREA(S):
Materials/Processes, Weapons ACQUISITION PROGRAM: ONR
Solid State Laser Technology Maturation (SSL-TM), PEO-IWS 2-Surface Naval Laser
Weapon System The technology within this
topic is restricted under the International Traffic in Arms Regulation (ITAR),
22 CFR Parts 120-130, which controls the export and import of defense-related
material and services, including export of sensitive technical data, or the
Export Administration Regulation (EAR), 15 CFR Parts 730-774, which controls
dual use items. Offerors must disclose any proposed use of foreign nationals
(FNs), their country(ies) of origin, the type of visa or work permit possessed,
and the statement of work (SOW) tasks intended for accomplishment by the FN(s)
in accordance with section 5.4.c.(8) of the Announcement. Offerors are advised
foreign nationals proposed to perform on this topic may be restricted due to
the technical data under US Export Control Laws. OBJECTIVE: Development of
fiber coupled optical isolators with high power handling capability, low
insertion loss, and high isolation, while minimizing volume and weight over
current state-of-the-art.� Higher power fiber-coupled isolators are needed to
reduce required gain at each stage, enabling multi-kW output fiber lasers and
enabling amplifiers suitable for laser beam combining, thereby reducing the
number of beams required to be combined, and making overall system Size,
Weight, and Power (SWaP) requirement reductions possible. DESCRIPTION: Scaling High
Energy Laser (HEL) output power requires increasing the output power per fiber
from the current values of approximately 1.5 kiloWatts (kW), and then combining
several fiber laser sources to form a single monolithic laser beam.�
Multi-stage Master Oscillator Power Amplifier (MOPA) architectures have been
developed that mitigate the risks of damage to optical components by increasing
fiber core diameter in each stage.� Fiber-coupled isolators, which are required
to limit back reflections between stages, are currently limited to less than 30
Watts (W) forward and 3 W backward propagating power handling capability.� This
requires final stage amplifier gains of greater than 20 decibel (dB) as output
power per fiber is scaled to the 2 to 3 kW range.� This could lead to parasitic
lasing, increased Amplified Spontaneous Emission (ASE), and increased risk of
damage to optical components.� Higher power capable fiber-coupled isolators are
needed to reduce the required gain at each stage, enabling multi-kW output
fiber lasers and amplifiers suitable for beam combining, hence reducing the
number of combined beams, and overall system SWaP requirements.� This
solicitation seeks improvements in the backward power handling capability to
reach values greater than or equal to (=) 40 W.� Also desired is a reduction by
half in mass and volume over current state-of-the-art (currently 20x14x50mm, 57g),
with an insertion loss of less than (<) 1.5 dB, and isolation greater than
or equal to (=) 25 dB. PHASE I: Phase I will include
development and/or use of detailed modeling tools to analyze the performance of
fiber coupled isolator suitable for use in fiber lasers/amplifiers suitable for
beam combining.� Issues that impact and limit the performance of the
fiber-coupled isolators will be examined to determine specific figures of merit
that improve the power handling capability, while improving insertion loss, and
isolation.� The results of this modeling will be used to develop prototype
fiber-coupled isolator�s designs, with recommendations for the down-selection
of a specific design or designs.� Consideration shall also be given to reducing
the volume and mass of the device.� The deliverables will be a detailed
technical report of all analysis including discussions on the power scaling
limits, and expected performance in terms of forward and backward power
handling capability, insertion loss, and isolation.� Computer models, including
and developed or modified analysis analytical codes, will be delivered on an
accompanying CD/DVD.� The analysis should consider the practicalities of any
proposed material processing required to produce prototype fiber-coupled
isolators, or other fiber laser modifications required. Included with the
report shall be a detailed fabrication plan for fiber-coupled isolators for
Phase II, with alternatives considered with documentation for technical risks,
cost, and schedule.� Recommended quantities of fiber-coupled isolator designs
to be prototyped shall be included, with plans for testing and verification of
analytical results.� The Phase I final report shall include the fiber-coupled
isolator development plan, fabrication and testing timeline, with performance
goals and key milestones, for Phase II. PHASE II: In the first year,
based upon the results of Phase I analysis and the development plan reported,
fiber-coupled isolator samples will be fabricated and subjected initially to
low power (approximately 5 to 10 W) evaluation.� Careful measurements of
insertion loss and isolation shall be collected and compared to previous results
from Phase I, along with any associated thermal performance data.� In the
second year, high-power fiber-coupled isolators shall be evaluated at a level
of approximately 40 W and, if possible, higher powers.� Data on resulting power
handling capability, insertion loss, isolation, and thermal performance of the
fiber-coupled isolators shall be collected, compiled into a provided database,
and reported.� The goals will be increasing of power handling capability,
improving insertion loss and isolation, while minimizing volume and mass.
Stable device performance shall be demonstrated for operating times of ten (10)
minutes or more at stable continuous-wave (CW) high power levels.� The final
report shall include all data collected, and a discussion of any remaining
steps required to develop a commercial version of the device. PHASE III DUAL USE
APPLICATIONS: The primary applications of high power fiber lasers are defense
related.� However, the techniques employed in fiber laser amplifiers can find
use in applications such as high-speed laser cutting and welding, broadband
communication, and free space satellite data streaming utilizing lasers with
consistently high power lasers with excellent beam quality.� The contractor in
Phase III shall support the transition of resulting components and design
efforts to a ship based laser system and shall further develop the laser
technology to support system integration for surface Navy shipboard
implementation.� A shipboard laser system comprised of multiple fiber lasers
which are beam-combined into a single militarily useful laser beam at a very
high power levels is expected. REFERENCES: 1. Augst, S. J., Goyal, A.
K., Aggarwal, R. L., Fan, T. Y., and Sanchez, A. "Wavelength beam
combining of ytterbium fiber lasers"; Optical Society of America (OSA)
Optics Letters; Vol. 28, Issue 5, pp. 331-333; 2003; https://doi.org/10.1364/OL.28.000331 2. Paschotta, R., Nilsson,
J., Tropper, A. C., and Hanna, D. C. "Ytterbium-doped fiber
amplifiers," in IEEE Journal of Quantum Electronics, vol. 33, no. 7, pp.
1049-1056, Jul 1997; doi: 10.1109/3.594865 3. Padula, C. and Young, C.
"5.4 - Optical isolators for high-power 1.06-micron glass laser
system," in IEEE Journal of Quantum Electronics, vol. 3, no. 11, pp.
493-498, November 1967; doi: 10.1109/JQE.1967.1074385 KEYWORDS: High Energy Lasers;
HELs; Fiber Lasers; High Power Lasers; Fiber Amplifiers; Fiber Laser Coupled
Isolators
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