U.S. Military Freaking Out: Why Lasers Aren’t the 'Magic Bullet' Against Hypersonic Missiles

DragonFire
October 18, 2024 Topic: Security Region: Americas Blog Brand: The Buzz Tags: Military LasersLasersMilitaryHypersonic WeaponsDefense

U.S. Military Freaking Out: Why Lasers Aren’t the 'Magic Bullet' Against Hypersonic Missiles

While lasers have long been viewed as a potential solution to advanced missile threats, current technology falls short of countering hypersonic missiles. Lasers face several challenges, including insufficient power output, limited range due to atmospheric conditions, and difficulty tracking fast-moving targets.

 

The Problem and NOT The Solution: While lasers have long been viewed as a potential solution to advanced missile threats, current technology falls short of countering hypersonic missiles. Lasers face several challenges, including insufficient power output, limited range due to atmospheric conditions, and difficulty tracking fast-moving targets.

-Hypersonic missiles, which travel at speeds over Mach 5 and change course unpredictably, remain hard to intercept. Although solid-state lasers are becoming effective for close-range defense, they are not yet capable of neutralizing these advanced threats.

 

-For now, kinetic missile interceptors remain the most reliable option for missile defense.

Can Lasers Defend Against Hypersonic Missiles? Not Yet

Lasers may be the cure for whatever ails you in science fiction, but if America is looking for a real solution to the myriad problems posed by modern hypersonic weapons, lasers – or directed energy weapons – won’t be able to provide the magic bullet that we’re looking for.

Modern hypersonic missiles, which combine flying at speeds in excess of Mach 5 with the ability to change course unpredictably, pose a unique challenge for even today’s most advanced integrated air defense systems. While the air defense enterprise is an incredibly complex one, the job itself is somewhat simple: Air defense systems identify and track inbound weapons using sensors, like radar, and then use computers to calculate the remainder of the weapon’s inbound flight path. With its course determined, air defense systems, like America’s MIM-104 Patriot, then launch a missile of their own, known as an interceptor, to fly toward a point further along the inbound weapon’s flight path to intercept it.

It’s the same basic principle as a quarterback leading a receiver: you don’t throw the ball to where the receiver is, but rather, to where the receiver will be by the time the ball gets there.

This approach to missile defense has proven very effective against ballistic missiles, which do travel at hypersonic speeds, but along a fairly predictable ballistic flight path. Cruise missiles pose a different type of risk, as they fly at much lower altitudes under power, more like an aircraft or suicide drone, which makes them less predictable. However, because of their lower relative speeds, air defense systems are often capable of intercepting cruise missiles using the same sort of arithmetic.

But modern hypersonic missiles complicate matters a great deal. Rather than achieving hypersonic speeds by flying along a predictable ballistic flight path, hypersonic boost-glide weapons and hypersonic cruise missiles both change course unpredictably while flying at these extreme speeds. As a result, an air defense system’s calculations to predict the remainder of the weapon’s flight path are rendered more or less moot, and because of their high closing speed, there’s little to no time left to attempt a recalculation to launch another interceptor.

The solution to this problem may be directed energy weapons or lasers. Rather than launching a missile to close with a target at supersonic speeds, lasers travel at the speed of light, and while a Patriot launch station may only carry four interceptors… you don’t run out of lasers unless you run out of energy.

In theory, it’s a perfect solution. But in practice… things get more complicated.

THE CURRENT STATE OF LASERS IN THE US MILITARY

While massive and powerful chemical lasers were all the rage in the 1980s, in recent years, the vast majority of developmental efforts have been focused on the comparably smaller, safer, and less powerful solid-state laser approach.

 

Chemical lasers work by sending an electric current through a gas to generate light through a process known as population inversion. In other words, operating a chemical laser means toting a bunch of hazardous chemicals around with you and adding size, weight, and danger to operators. 

Solid-state lasers, on the other hand, use a solid crystalline material, rather than a gas or liquid, as the “lasing medium.” This makes them far smaller and far safer to operate – but until fairly recently, they were simply unable to produce enough consistent power for weapons applications. 

Today, solid-state lasers are an increasingly promising technology, with numerous developmental efforts ongoing and a number of laser systems already deployed on U.S. Navy vessels.

The U.S. Navy first installed a laser on one of its warships in 2014 in the 33-kilowatt AN/SEQ-3 Laser Weapon System (LaWS), with the stronger 60-kilowatt HELIOS, or High-Energy Laser with Integrated Optical Dazzler and Surveillance system, following in 2019. The Navy believes HELIOS will eventually be able to output as much as 150 kilowatts. It wants to begin testing the 300-kW HELCAP, short for High Energy Laser Counter Anti-ship Cruise missile Program, next year. 

In September of last year, Lockheed Martin delivered the most powerful tactical laser fielded to date, the 300-kW-class Indirect Fires Protection Capability-High Energy Laser (IFPC-HEL), to the U.S. Army. This system delivers only about 1/3 of the power output provided by the massive MIRACL from the 1980s, but is compact enough to be carried by a single truck or inside the fuselage of a variety of aircraft.

In late July, Lockheed Martin announced plans to field a 500kW-class laser which will offer a number of new defense possibilities but will still fall well short of being able to stop an inbound hypersonic missile.

THE BIG PROBLEMS WITH USING LASERS TO SHOOT DOWN HYPERSONIC MISSILES

While lasers are already becoming extremely useful close-range weapons and air defense systems, there are several serious technological limitations that prevent them from being used to take down incoming hypersonic, or even ballistic, missiles.

Power Output

According to Pentagon assessments, power output is the first limiting factor. While a clear consensus on power requirements for different types of targets doesn’t exist, the DoD does have a general rule of thumb for the power output by a system and its potential applications:

  • 100kW-Range Weapons: Can engage unmanned aircraft, small boats, rockets, artillery, or mortars
  • 300kW-Range Weapons: Can engage the side of a cruise missile fuselage to destroy it or knock it off course
  • 1MW (1,000kW)-Range Weapons: Can engage ballistic or hypersonic missiles, but may be limited to burning through the side of the fuselage

As you can tell by looking at those figures, the systems currently deployed on U.S. Navy ships can engage slow-moving drones and even small boats by concentrating a laser beam on the target for an extended period of time and eventually burning through them to damage internal systems. The more powerful 300kW IFPC-HEL and HELCAP, on the other hand, are powerful enough to burn through the side of a cruise missile in flight to destroy it or send it off course, but again, in order to do so, they must keep the beam pointed at the exact same spot on the fuselage as the missile flies by. In 2020, it took 15 seconds of sustained fire from a 150kW-class weapon to destroy an airborne drone.

This approach, some contend, could be easily countered by designing missiles to roll during their flight path, making it impossible to focus the beam on one singular point.

In order to stop a hypersonic missile from reaching its target, the DoD estimates that they’d need at least a 1 megawatt (or 1,000 kilowatt) laser. That’s more than three times the power output of today’s most advanced tactical laser system… but even such a laser would likely struggle to burn through the nosecone of a hypersonic missile. After all, these weapons are designed to withstand temperatures in excess of 1,700 degrees. 

And as the Navy has pointed out, it’s cheaper to build missiles with more heat shielding than it is to field lasers with more power output – so as laser defenses become more commonplace, missiles will almost certainly be better shielded and thus, less susceptible to laser engagement. 

Line of Sight

Unlike interceptors, which can be launched at targets identified beyond the horizon, the very nature of lasers limits them to line of sight. This presents problems when the laser needs time to burn through a target. Hypersonic weapons like China’s DF-ZF may be traveling at 2 miles per second or even faster, meaning there would be precious little time to actually destroy the weapon by the time it appeared in the lasers’ line of sight. 

Atmospheric Scattering

We tend to think of lasers as a thin beam of energy that continues onward forever, but that’s really not the case at all. Water vapor, sand, salt, smoke, air pollution, and other substances found in the atmosphere can all have a scattering effect on laser beams. This atmospheric turbulence is a serious problem – to the point where the Pentagon currently sees lasers as a viable weapon system only at ranges of less than a mile. And even optimistic projections for the near future still only think lasers will be viable at ranges of less than five miles. 

Again, when we’re talking about countering a missile that’s designed to manage heat and traveling at more than 2 miles per second, this leaves almost no time for intercept.