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Advanced Tactical Laser

The Advanced Tactical Laser (ATL) was an experimental high-energy chemical laser weapon system developed by Boeing for the United States Air Force, designed to enable precision aerial strikes from tactical aircraft such as the AC-130 gunship by delivering directed energy to disable or destroy ground targets with minimal collateral damage.^[1]^[2] Initiated around 2002 under sponsorship from Air Force Special Operations Command, the program integrated a Chemical Oxygen Iodine Laser (COIL) module, beam control optics, and a rotating turret mounted on a modified NC-130H Hercules testbed aircraft, with initial ground demonstrations validating laser firing through the full weapon system in August 2008 at Kirtland Air Force Base, New Mexico.^[1] The system's architecture emphasized rapid target acquisition and engagement, leveraging sensors and battle management consoles to direct the laser beam against stationary or slow-moving threats like vehicles or structures.^[2] Key achievements included the first in-flight firing of the high-power laser on June 13, 2009, over White Sands Missile Range, where it successfully struck a designated ground target board, demonstrating airborne beam control and propagation under real-world conditions.^[2]^[1] Despite these milestones, which proved the feasibility of tactical laser engagements, the ATL program concluded as a technology demonstrator without transitioning to operational deployment, amid challenges including atmospheric attenuation, power scaling, and integration costs that hindered broader adoption of chemical laser systems in airborne roles.^[3] Subsequent U.S. directed-energy efforts shifted toward more compact solid-state lasers, reflecting empirical limitations of COIL technology for sustained tactical utility.^[3]

Overview

Program Objectives and Capabilities

The Advanced Tactical Laser (ATL) program sought to develop and demonstrate a high-energy laser (HEL) weapon system capable of integration onto tactical airborne platforms, such as transport aircraft and helicopters, to enable precision engagement of ground and surface threats. Primary objectives included creating a modular, roll-on/roll-off HEL configuration for rapid deployment, enhancing intelligence, surveillance, reconnaissance (ISR), and strike capabilities while minimizing collateral damage through pinpoint accuracy.^[4] The system was designed to target stationary and moving assets, including soft targets like personnel and light vehicles, moderately hardened structures such as transport-erector-launchers, and asymmetric threats like patrol boats or anti-ship missiles, with applications in urban, littoral, and air-to-ground scenarios.^[4] ^[5] Key capabilities encompassed line-of-sight engagements at the speed of light, allowing near-instantaneous effects without the ballistic trajectory limitations of kinetic munitions. The laser aimed for power outputs in the 50-100 kW class, scalable to higher levels, sufficient to destroy or disable targets at slant ranges up to 15 km under operational conditions, with precision beam control to maintain effectiveness in turbulent atmospheres.^[4] ^[5] Unlike conventional weapons, the ATL offered potential for unlimited shots constrained only by onboard power and fuel supplies, lower cost per engagement due to reduced logistics, and unique damage mechanisms such as heating or ablating specific components like sensors, fuel tanks, or missile domes without widespread explosive effects.^[4] Integration focused on platforms like the C-130 transport or CV-22 tiltrotor, supporting both lethal and non-lethal modes for versatile tactical utility.^[5]

Platform and System Integration

The Advanced Tactical Laser (ATL) system was integrated onto a specially modified NC-130H aircraft, a C-130 Hercules variant operated by the U.S. Air Force's 46th Test Wing for experimental purposes. This platform was selected for its proven tactical utility in special operations, including extended loiter times and payload capacity suitable for accommodating the laser module and support equipment without requiring a new airframe design. The high-energy chemical oxygen-iodine laser (COIL) was housed internally, with the beam director turret mounted beneath the fuselage to enable multi-azimuth targeting during low-altitude operations.^[2]^[6]^[7] Engineering efforts focused on adapting the system to the aircraft's constraints, including generation of operational power through chemical reaction fuels supplemented by the platform's auxiliary systems, rather than relying solely on engine bleed air or generators. Thermal management systems were incorporated to handle heat dissipation from the laser's reaction chamber and optics, preventing performance degradation in sustained engagements. Beam stabilization mechanisms, integral to the turret's beam control subsystem, compensated for airframe vibrations, turbulence, and platform motion, as validated in ground and flight integration tests prior to airborne demonstrations.^[8]^[9] In contrast to ground-based laser systems, the ATL's airborne integration emphasized dynamic flight envelopes, with design adaptations for beam quality maintenance amid altitude-induced atmospheric variations and aircraft speed effects on propagation stability. This configuration provided tactical advantages in mobility, allowing repositioning for optimal engagement geometry and elevated line-of-sight targeting that mitigated ground-level obscurants and terrain limitations inherent to stationary installations. Flight tests on June 13, 2009, confirmed the system's ability to maintain beam coherence and acquire targets under these conditions.^[10]^[11]

Development History

Inception and Initial Funding

The Advanced Tactical Laser (ATL) program originated in the early 2000s as part of U.S. military efforts to develop directed-energy weapons for precision engagement of tactical targets, amid heightened focus on asymmetric warfare following the September 11, 2001, attacks. The program was formalized as an Advanced Concept Technology Demonstration (ACTD) in fiscal year 2002 (starting October 2001), with initial emphasis on integrating a high-energy chemical oxygen-iodine laser onto an airborne platform to enable rapid, non-kinetic strikes against threats such as small surface vessels and improvised explosive devices, reducing reliance on conventional munitions logistics.^[12]^[13] This approach leveraged the inherent advantages of laser systems, including instantaneous energy delivery at the speed of light and scalability limited primarily by electrical power generation rather than projectile supply chains.^[4] Boeing served as the lead contractor, collaborating with the U.S. Air Force Research Laboratory (AFRL) Directed Energy Directorate to build and test an initial demonstrator, drawing on Boeing's internal research and development funds alongside government support.^[13] The Air Force identified ATL as a pathway to counter low-cost, high-volume threats in operations like those emerging in Afghanistan and Iraq, prioritizing empirical validation of laser efficacy over traditional kinetic options through ground-based prototyping at facilities such as the Davis Advanced Laser Facility at Kirtland Air Force Base.^[13] Early decisions centered on a modular design suitable for integration onto platforms like the C-130 Hercules, with the ACTD structured as a two-year effort to assess feasibility for tactical deployment.^[14] Initial funding was provided by the Office of the Secretary of Defense, specifically through the Deputy Under Secretary of Defense for Advanced Systems and Concepts (DUSD AS&C), to kickstart the ACTD without immediate reliance on service-specific budgets.^[12] By 2005, program expenditures were projected at approximately $180 million, covering laser development, optics, and control systems, though DARPA's role remained peripheral compared to Air Force-led initiatives in parallel directed-energy research.^[14] These allocations reflected a strategic pivot toward high-energy lasers as a cost-effective means to engage fleeting targets, informed by prior demonstrator work dating to 1998 but accelerated by post-9/11 operational imperatives.^[13]

Key Milestones and Partnerships

In fiscal year 2002, Boeing received an initial contract from the U.S. Special Operations Command and Air Force to develop the Advanced Tactical Laser weapon system, focusing on integration of a high-energy chemical laser for airborne applications.^[14] On December 4, 2007, Boeing achieved a significant integration milestone by installing a high-energy chemical laser module aboard a modified C-130H aircraft, in collaboration with U.S. Air Force partners for subsystem development including optics and beam control.^[8] In May 2008, Boeing commenced firing tests of the high-energy laser integrated on the ATL aircraft platform, advancing toward tactical aircraft compatibility.^[15] August 2008 marked the completion of the first ground test of the full weapon system aboard the aircraft, reflecting progress in system-level integration with Air Force oversight.^[1] October 2008 saw Boeing awarded a U.S. Air Force contract valued at up to $30 million to sustain testing and refinement efforts.^[16] On June 13, 2009, the program reached the milestone of the first airborne firing of the high-power laser from an NC-130H aircraft, conducted in partnership with the 46th Test Wing at Eglin Air Force Base over White Sands Missile Range, New Mexico.^[10]^[17]

Technical Specifications

Laser Technology and Power Output

The Advanced Tactical Laser (ATL) utilized a chemical oxygen-iodine laser (COIL) system, which generates directed energy through an exothermic chemical reaction where singlet delta oxygen excites iodine atoms to produce stimulated emission.^[5] This design achieves high beam quality, with a near-diffraction-limited output suitable for focusing on small targets such as vehicles at tactical ranges of 1-3 km, dependent on atmospheric conditions and optics.^[18] COIL operates at a wavelength of 1.315 μm, selected for its relatively low absorption in the atmosphere compared to other chemical lasers, enabling better propagation through aerosols and water vapor.^[18] ^[19] The laser requires adaptive optics to mitigate beam distortions from platform vibration and thermal blooming, maintaining coherence for precise energy deposition.^[4] Power output targeted the 100 kW class, scaled from laboratory demonstrations of tens of kilowatts to aircraft-compatible modules, though full integration demanded complex fuel systems involving hydrogen peroxide, potassium hydroxide, and chlorine for oxygen generation.^[5] ^[20] Unlike emerging solid-state lasers that use electrical pumping without consumables, COIL's reliance on chemical precursors imposes logistical constraints, including storage, handling, and exhaust management for sustained operation.^[19]

Aircraft Modifications and Turret Design

The NC-130H Hercules variant served as the primary testbed for the Advanced Tactical Laser system, requiring extensive structural modifications to integrate the high-energy laser payload. These included fuselage reinforcements to bear the system's substantial weight, estimated at around 5,000 to 7,000 kilograms, and accommodations for chemical storage, power generation, and thermal management subsystems. Auxiliary power units were installed to supply the elevated electrical demands of the chemical oxygen iodine laser, while dedicated cooling infrastructure—drawing from closed-cycle mechanisms—was added to dissipate heat from laser excitation and beam generation processes, preventing performance degradation during sustained operation.^[14]^[4] Central to the integration was a low-profile, retractable turret mounted beneath the fuselage, designed by L-3 Communications/Brashear as part of the beam control subsystem. This aero-optic turret featured gimbaled optics capable of fine angular adjustments, providing precise line-of-sight pointing over tactical ranges up to approximately 15 kilometers. The design prioritized minimal aerodynamic drag to reduce aero-optic distortions from turbulent airflow, incorporating stabilization mechanisms to counteract line-of-sight jitter induced by aircraft vibrations, structural flexing, and atmospheric turbulence.^[6]^[21] Engineering efforts emphasized causal factors in beam propagation, such as aircraft motion effects and atmospheric beam heating leading to thermal blooming, where energy absorption expands the beam path and reduces focus. Turret systems employed inertial stabilization and adaptive beam control to maintain beam coherence and mitigate these distortions, ensuring effective energy delivery despite platform dynamics. These adaptations reflected first-principles constraints on airborne directed-energy systems, balancing payload mass with flight envelope preservation.^[22]^[23]

Testing and Demonstrations

Ground-Based Trials

In August 2008, Boeing completed the first integrated ground test of the Advanced Tactical Laser (ATL) weapon system aboard a modified C-130H aircraft at Kirtland Air Force Base, New Mexico, verifying the end-to-end functionality of the chemical laser, beam control director, and acquisition optics in a static configuration.^[1] This pre-flight validation focused on safe demonstration of beam generation and targeting without airborne variables, building on prior component-level firings conducted since the program's 2003 inception.^[14] The trials successfully engaged static mock targets, such as metal plates simulating vehicle components, demonstrating material ablation through sustained energy deposition. Key metrics included a beam diameter of approximately 4 inches (10 cm) at the focus point and dwell times of around 5 seconds to achieve cuts through metal, confirming the kilowatt-class laser's ability to deliver sufficient fluence for thermal damage without collateral explosive effects.^[6] These tests established baseline energy delivery rates, with the system propagating a coherent beam capable of precision spotting at short ranges, providing empirical thresholds for ignition and structural compromise on metals and composites akin to truck or missile truck surrogates.^[1] Outcomes underscored the ATL's proof-of-concept for non-kinetic kill chains, yielding data on required irradiance levels (typically in the range of thousands of watts per square centimeter for effective engagement) and validating subsystem integration prior to flight risks, though full-power ground engagements remained classified in detail.^[4] Such static validations mitigated uncertainties in laser pointing stability and atmospheric effects at ground level, informing subsequent airborne adaptations.^[14]

Airborne Flight Tests

In June 2009, the Advanced Tactical Laser (ATL) system, integrated aboard a modified NC-130H aircraft from the U.S. Air Force's 46th Test Wing, conducted its inaugural in-flight laser firing on June 13. The aircraft took off from Kirtland Air Force Base, New Mexico, and successfully directed high-power chemical laser energy onto a ground-based target board at White Sands Missile Range, demonstrating beam delivery from a moving airborne platform.^[10]^[24] Subsequent tests advanced to target engagement and defeat. On August 30, 2009, the NC-130H fired its laser at an unoccupied stationary truck at White Sands, resulting in combustion and structural damage confirmed by video footage of the ignition process.^[25] By October 2009, the system engaged a moving ground target, highlighting capabilities in dynamic tracking amid aircraft motion-induced jitter.^[26] These demonstrations occurred at operational altitudes around 10,000 feet and speeds approximating 200 knots, with emphasis on stabilizing the beam against atmospheric turbulence and platform vibrations.^[14]^[27] Outcomes verified remote ignition under flight conditions but revealed constraints inherent to chemical oxygen-iodine laser propagation, including dependency on clear atmospheric paths free of obscurants and effective ranges limited to several kilometers due to beam attenuation and dwell-time requirements.^[28] Tests through 2010 prioritized precision pointing and lethality assessment, yet did not extend to adverse weather or extended standoff distances in airborne configurations.^[2]

Challenges and Criticisms

Technical and Engineering Limitations

Atmospheric attenuation poses a fundamental constraint on the Advanced Tactical Laser's (ATL) beam propagation, with absorption by atmospheric gases such as water vapor and carbon dioxide reducing irradiance over distance, particularly in humid or maritime environments. Scattering from aerosols, dust, and particulates further disperses the beam's energy, empirically limiting effective engagement ranges to under 10 kilometers in non-ideal conditions despite design goals of approximately 20 kilometers. Thermal blooming exacerbates these issues, as the high-power infrared beam (operating at around 1.315 micrometers for the chemical oxygen iodine laser) heats the air along its path, inducing density gradients that cause wavefront distortion and beam defocusing, with effects becoming pronounced at power densities exceeding 10 kW/cm² in clear air and worsening under wind shear or target motion. These phenomena were quantified in simulations and tests for tactical airborne lasers, showing up to 50% reduction in on-target fluence in moderate turbulence.^[29]^[18] Aeromechanical jitter from aircraft platform vibrations and turret gimbal dynamics introduces beam wander, degrading pointing accuracy to sub-microradian levels required for precision targeting. In the ATL system, mounted on a C-130J aircraft with a palletized turret, structural flexure and propeller-induced disturbances generated line-of-sight errors on the order of several microradians, necessitating adaptive optics and fast-steering mirrors for compensation, though full stabilization against dynamic flight conditions remained unresolved in demonstrations. Atmospheric turbulence added further pointing instability, with beam quality degradation modeled via the Fried parameter, limiting dwell times on moving targets to seconds rather than enabling sustained burns. These challenges were addressed through inertial reference units and jitter suppression algorithms, but empirical data from ground and flight tests indicated residual errors sufficient to miss small apertures at extended ranges.^[30]^[31] The ATL's 100-kilowatt-class chemical oxygen iodine laser imposed severe size and power burdens, with the complete system weighing 5,000 to 7,000 kilograms and requiring integration into a large transport aircraft to accommodate coolant, optics, and exhaust systems, straining payload capacities and flight envelopes. High energy extraction relied on continuous chemical reactions involving iodine, oxygen, and hydrogen peroxide precursors, which generated substantial heat (over 300 kW thermal load) and necessitated cryogenic cooling and venting, complicating airborne deployment. Logistics for chemical fuels undermined scalability, as each engagement consumed kilograms of reagents, limiting operational endurance to tens of shots per sortie without specialized resupply chains, contrary to directed energy weapon ideals of deep magazines. Tests confirmed fuel depletion as a binding constraint, with recycling efforts explored but not operationally viable due to efficiency losses exceeding 20%.^[14]^[32]

Cost Overruns and Program Viability

The Advanced Tactical Laser (ATL) program experienced progressive cost growth from its inception in the early 2000s, with initial Pentagon allocations of up to $49 million over two years for solid-state high-power laser development precursors, expanding to projected expenditures of $180 million through 2005 for full system integration including laser, optics, and control elements on a modified C-130 aircraft.^[33]^[14] Additional contracts, such as a $30 million award to Boeing in 2008 for advanced testing phases, reflected mounting expenses driven by aircraft modifications and beam control complexities, though specific overrun figures were not publicly detailed beyond these baselines.^[34] Program viability faced scrutiny due to the chemical oxygen iodine laser's inherent logistical burdens, including the need for frequent replenishment of hazardous chemical fuels, which inflated per-mission operational costs and complicated forward deployment compared to conventional munitions.^[18] While ground and airborne demonstrations in 2008–2009 validated target engagement capabilities, such as disabling stationary vehicles from 10,000 feet, scalability for combat fleets proved elusive amid these fiscal and sustainment hurdles.^[35] An Air Force Scientific Advisory Board assessment underscored technical and operational limitations, recommending restructuring without altering core funding at the time, yet empirical realities of integration delays and budget pressures eroded confidence in tactical fielding. By 2010–2012, the ATL effectively transitioned from active development to archival status without procurement or operational deployment, as real-world engineering constraints—prioritizing deployability over prototype successes—outweighed theoretical precision advantages in cost-benefit analyses.^[36] Defense analyses attributed this outcome to the program's failure to demonstrate economically viable scaling, with total investments yielding proof-of-concept rather than a sustainable weapon system amid competing directed-energy priorities.^[18]

Strategic and Ethical Considerations

Potential Military Advantages

High-energy laser systems, exemplified by the Advanced Tactical Laser (ATL), provide precision strike capabilities through focused energy delivery at the speed of light, enabling minimal collateral damage compared to conventional munitions. This pinpoint accuracy is ideal for engaging small, maneuverable targets such as unmanned aerial vehicles (UAVs) and small surface vessels, where the narrow beam reduces unintended effects on surrounding areas.^[37]^[38] The near-instantaneous propagation of laser energy facilitates rapid response to dynamic threats, effectively countering saturation attacks involving swarms of drones or missiles by engaging multiple targets sequentially within line-of-sight ranges. Such systems have demonstrated the potential to track and neutralize incoming projectiles, including mortar rounds and UAVs of varying sizes, in operational testing environments.^[39]^[40] Logistically, directed energy weapons like the ATL offer advantages by eliminating the need for physical projectiles, substituting ammunition weight with electrical power derived from onboard fuel sources, which supports extended engagements without frequent resupply. This reduction in payload mass enhances aircraft endurance and simplifies sustainment in prolonged missions.^[41] In tactical airborne applications, such as the ATL integrated on the NC-130H platform, these lasers bolster air dominance in contested airspace by delivering scalable effects against low-cost, high-volume threats, where empirical tests indicate superiority over kinetic interceptors in terms of engagement speed and repeatability.^[2]^[42]

Controversies Regarding Deployment and Effects

The potential deployment of the Advanced Tactical Laser (ATL), a high-energy chemical laser system developed by Boeing for the U.S. Air Force, has sparked debates over its human effects, particularly the risk of permanent blindness from beam exposure. While the ATL is engineered to deliver thermal damage to material targets such as vehicles or missiles at ranges exceeding 5 kilometers, incidental exposure to the eye could cause irreversible retinal burns, as laser-induced injuries often result in permanent visual impairment due to focused energy absorption.^[43] This raises compliance questions with Protocol IV to the 1980 Convention on Certain Conventional Weapons, which bans lasers "specifically designed" to cause permanent blindness but exempts incidental blinding during legitimate attacks on optical systems or hardware. Proponents maintain that the ATL's targeting protocols prioritize non-personnel assets, rendering human blinding a collateral outcome akin to shrapnel or fire from conventional munitions, and thus permissible under the protocol's exceptions; the U.S. Department of Defense has historically argued that such effects do not uniquely violate prohibitions on unnecessary suffering, as similar outcomes occur with existing weapons.^[44] Critics, including Human Rights Watch—a nongovernmental organization with a track record of advocating restrictions on military technologies—assert that the beam's power output, exceeding 100 kilowatts, heightens off-axis exposure risks to operators or civilians, potentially breaching Article 35 of Additional Protocol I to the Geneva Conventions by inflicting disproportionate harm relative to military gain, especially given the difficulty in precisely controlling beam divergence in dynamic combat scenarios.^[45] Empirical data from directed energy bioeffects research underscores these concerns, showing that even brief exposures at tactical wavelengths can lead to scotomas or total vision loss, complicating rules of engagement.^[46] Additional controversies center on proliferation risks, as the ATL's modular design and chemical laser technology could facilitate rapid adaptation by adversaries, exacerbating global arms races in directed energy systems. A 2021 Air Force Research Laboratory assessment highlights the "wide proliferation" of lasers achieving destructive effects at militarily relevant distances, warning that tactical platforms like the ATL lower barriers for state and non-state actors to field similar capabilities.^[47] Detractors argue this hype diverts funding from kinetic defenses, citing test demonstrations where atmospheric conditions—such as humidity and aerosols—degraded beam coherence and range, questioning the system's real-world deployability against human-embedded threats without excessive collateral exposure.^[36] Such skepticism, while sometimes framed in media as prudent caution, aligns with observed empirical limits in field trials, prioritizing verifiable kinetic alternatives over speculative energy-based effects.^[48]

Legacy and Successors

Transition from Chemical to Solid-State Lasers

Following the successful airborne demonstrations of the Advanced Tactical Laser (ATL) in 2009, which included firing a chemical oxygen-iodine laser (COIL) from a modified C-130 aircraft to strike stationary and moving ground targets at tactical ranges, U.S. military programs began reevaluating COIL technology.^[24] ^[25] ^[26] These tests validated beam control and integration concepts but underscored COIL's logistical burdens, including the need for onboard storage and handling of toxic fuels and oxidizers, which limited scalability for mobile platforms.^[49] The post-2010 transition to solid-state lasers was propelled by their electrical pumping via high-power diodes, eliminating chemical dependencies and enabling compact, vehicle-agnostic designs with reduced size and weight.^[50] ^[49] Solid-state systems, such as fiber and slab configurations, offered improved beam quality for atmospheric propagation and modular scalability through coherent beam combination, addressing COIL's constraints in fuel resupply and system complexity.^[50] While ATL's COIL achieved device efficiencies around 25-30%, full-system wall-plug performance suffered from auxiliary power demands for chemical flow and exhaust management, contrasting with solid-state advances exceeding 30% overall efficiency.^[49] This empirical pivot favored solid-state for tactical viability, as seen in DARPA initiatives targeting lightweight, kilowatt-class electrified lasers post-ABL lessons.^[51] The ATL's turret and pointing-stabilization data informed these efforts, but chemical logistics proved a non-scalable barrier.^[49]

Influence on Modern Directed Energy Programs

The Advanced Tactical Laser (ATL) program's airborne integration on a C-130 platform yielded empirical data on beam pointing accuracy and platform-induced jitter, which informed subsequent U.S. Air Force efforts to adapt directed energy weapons for gunship applications. Specifically, these lessons contributed to the development of the Airborne High Energy Laser (AHEL) system intended for the AC-130J Ghostrider, where ground-based integration testing began in 2022 and airborne flight tests were scheduled for late 2023 before delays and eventual cancellation in 2024 due to technical and budgetary challenges.^[52]^[53]^[54] ATL's demonstrations of mechanical jitter mitigation—arising from aircraft vibrations and laser aperture instabilities—advanced beam control algorithms applicable to modern high-energy laser systems, countering overly pessimistic assessments of directed energy weapon viability by providing validated engineering baselines for stabilization in dynamic environments. This heritage is evident in the U.S. Navy's HELIOS system, a 60-kilowatt solid-state laser deployed on Arleigh Burke-class destroyers, which successfully engaged and downed an unmanned aerial drone during at-sea testing in fiscal year 2024, with operational validation extending into 2025.^[55]^[56]^[57] On the ground, ATL's focus on tactical-range engagements against moving targets influenced Army and Navy counter-unmanned aerial system (C-UAS) deployments, including the U.S. Army's forward-operating high-energy laser prototypes shipped overseas in April 2024 for real-world drone interception trials, emphasizing scalable power delivery and atmospheric propagation lessons derived from earlier chemical laser experiments. Despite ATL's non-deployment in 2012, its rigorous testing regimen—documenting limits in power scaling and environmental resilience—fostered a pragmatic maturation of directed energy technologies, enabling incremental successes in layered defenses against proliferating low-cost UAV threats by 2025.^[58]^[59]

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Jan 25, 2024 · Directed energy weapons offer a more cost-efficient means of dealing with fast-proliferating threats. If the technology can be matured, ...
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High-energy laser weapons ready for the front lines
Aug 2, 2022 · The laser was able to track, target and defeat 60-millimeter mortar rounds and drones in three different sizes during a test at White Sands ...Missing: benefits | Show results with:benefits
[41]
Army looks to optimize lethality with high-energy lasers
Feb 8, 2018 · High-energy laser weapons simplify logistical support, requiring only diesel fuel, which is easily converted into electricity to power the laser ...Missing: benefits | Show results with:benefits
[42]
Directed Energy Weapons Are Real . . . And Disruptive - NDU Press
Jan 9, 2020 · They can be very effective in causing pressurized vessels to explode such as missile propellant and oxidizer tanks. They can destroy, degrade or ...
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Military laser weapons: current controversies - PubMed
Eye injuries caused by military lasers are increasingly reported, leading to speculation that these would become an important cause of blinding in modern ...Missing: Advanced deployment Geneva Conventions
[44]
United States, Memorandum of Law: The Use of Lasers as Anti ...
Some laser injury may lead to permanent blindness. The issues are whether the intentional use of a laser for the purpose of blinding necessarily should be ...Missing: Advanced deployment
[45]
blinding laser weapons - Human Rights Watch
Tactical laser weapons do not have a low probability of inflicting "permanent disablement," and blinding is not a "relatively reversible effect." In addition, ...
[46]
[PDF] Millimetre Waves, Lasers, Acoustics for Non-Lethal Weapons ...
Boeing: Advanced Tactical Laser, Advanced Concept Technology Demonstration, 2003, ... Atmospheric Propagation for Tactical. Directed Energy Applications. In ...<|control11|><|separator|>
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[PDF] 2060 directed energy futures - Air Force Research Laboratory
Jul 16, 2021 · Today these laser weapons cause destructive and damaging effects at militarily relevant ranges. Furthermore, there is wide proliferation of ...
[48]
[PDF] Assessment of Long Range Laser Weapon Engagements
At the moment there are two U. S. laser DEW systems which are employing chemical lasers. Those are the Advanced Tactical Laser (ATL) and the Airborne. Laser ( ...
[49]
[PDF] Directed Energy Weapons – Are We There Yet?
The Army had initiated a modest effort in solid-state lasers (SSLs), motivated by a need for a compact laser that did not require toxic chemicals.
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Laser weapons go solid-state
Higher-power solid-state lasers were developed for antisensor weapons, but their use has been limited by treaty restrictions on antipersonnel lasers. Now solid- ...Missing: transition | Show results with:transition
[51]
HELLADS: High Energy Liquid Laser Area Defense System - DARPA
The goal of the HELLADS program is to develop a 150 kilowatt (kW) laser weapon system that is ten times smaller and lighter than current lasers of similar power ...
[52]
AC-130 Gunship Laser Weapon Program's Future Is Looking Blurry
May 11, 2023 · Work on laser weapons on C-130s dates back many years, with the Advanced Tactical Laser system seen here during testing nearly a decade and a ...
[53]
AFSOC AC-130J gunship to fire laser weapon in flight test in 2023
Sep 27, 2022 · Air Force Special Operations Command will test an airborne laser in flight on an AC-130J gunship in 2023, a year later than planned.Missing: Tactical | Show results with:Tactical
[54]
USAF Scraps Plan to Mount Laser Weapon on AC-130J Gunship
Mar 20, 2024 · The AFSOC spokesperson clarified the service is not canceling the entire AHEL program but will only reassess its plans for the weapon system. He ...
[55]
[PDF] Improving the Estimation of Military Worth of the Advanced Tactical ...
... C-130 or. CV-22 aircraft equipped with a low power laser. In comparison, the low power laser for the ATL would be approximately 50 kilowatts (kW) whereas the ...Missing: cooling | Show results with:cooling
[56]
US Navy hits drone with HELIOS laser in successful test - Navy Times
Feb 4, 2025 · The US Navy successfully tested its High-Energy Laser with Integrated Optical Dazzler and Surveillance, or HELIOS, system on one of its warships in fiscal 2024.
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US Navy's Burke-Class Destroyer Unleashes HELIOS Laser in ...
Feb 4, 2025 · One of its most unusual features is its layered defense approach, enabling both hard and soft kills of hostile threats. Hard kill means the ...
[58]
The Army Has Officially Deployed Laser Weapons Overseas to ...
Apr 24, 2024 · The Army has officially deployed a pair of high-energy lasers overseas to blast incoming enemy drones out of the sky, the service recently confirmed.
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Navy still bullish on lasers but widely-deployed directed-energy ship ...
Aug 8, 2024 · The Navy has deployed experimental and prototype lasers and other directed-energy weapons for more than a decade.