DEW for the destruction of incoming missiles are under development. One example is Boeing
Airborne Laser, deployed inside a
Boeing 747 and designated as
YAL-1. This system was designed to eliminate short- and intermediate-range ballistic missiles during their boost phase. It was canceled in 2012. Another system was studied under the
Strategic Defense Initiative (SDI) and successor programs. This project aimed to employ ground-based or
space-based laser systems to destroy incoming
intercontinental ballistic missiles (ICBMs). However, various practical challenges, such as aiming a laser over a large distance through the atmosphere, complicated implementation. Optical scattering and
refraction bent and distorted the beam, complicating aiming and reducing its efficiency. A related concept was the
nuclear-pumped X-ray laser, an orbiting
atomic bomb surrounded by laser media in the form of glass rods. When a bomb detonated, the rods would be exposed to highly-energetic
gamma-ray photons, causing
spontaneous and
stimulated emission of
X-ray photons within the rod atoms. This process would result in optical amplification of the X-ray photons, generating an X-ray beam that was little affected by atmospheric distortion and capable of destroying ICBMs in flight. However, the
X-ray laser became a single-use device, as it would destroy itself upon activation. Some initial tests were conducted with
underground nuclear testing, but the results were not promising.
Iron Beam Iron Beam is a laser-based
air defense system which was unveiled at the
Singapore Airshow on 11 February 2014 by Israeli
defense contractor Rafael Advanced Defense Systems. The system is designed to destroy short-range rockets, artillery, and
mortar bombs; it has a range of up to , too close for the
Iron Dome system to intercept projectiles effectively. In addition, the system could also intercept
unmanned aerial vehicles (UAVs). Iron Beam will constitute the sixth element of Israel's integrated air defense system, Iron Beam uses a
fiber laser to destroy an airborne target. Whether acting as a stand-alone system or with external cueing as part of an air-defense system, a threat is detected by a surveillance system and tracked by vehicle platforms in order to engage. Iron Beam is expected to be operational by the end of 2025.
Anti-drone systems firing its
HELIOS laser system, 3 February 2025 In the 21st century, several countries have developed anti-drone laser systems to counter the increasing threat of small unmanned aerial vehicles (UAVs). These systems are designed to detect, track, and destroy drones using high-powered lasers, offering a cost-effective and flexible solution for airspace protection. In the United States, Lockheed Martin demonstrated the capabilities of its ATHENA laser system in 2017, which uses a 30-kilowatt ALADIN laser to target and destroy UAVs. Another American company, Raytheon, developed the High-Energy Laser Weapon System (HELWS) in 2019, which is capable of detecting and destroying drones at a distance of up to three kilometers. On 16 May 2025, Ukraine revealed a small laser turret called SlimBeam, fitted to a
remote controlled weapon station, capable of blinding optical sensors at 2 km and destroying drones at 800 meters. It can be remotely operated by a web-based system to reduce the risk to the operators of enemy fire. It could also be used for sabotage by targeting various locks or other objects. == Electrolaser ==