While it has become a word, laser used to be an acronym: “light amplification by stimulated emission of radiation”. But there is an even older technology called a maser, which is the same acronym but with light switched out for microwaves. If you’ve never heard of masers, you might be tempted to dismiss them as early proto-lasers that are obsolete. But you’d be wrong! Masers keep showing up in places you’d never expect: radio telescopes, atomic clocks, deep-space tracking, and even some bleeding-edge quantum experiments. And depending on how a few materials and microwave engineering problems shake out, masers might be headed for a second golden age.
Simplistically, the maser is — in one sense — a “lower frequency laser.” Just like a laser, stimulated emission is what makes it work. You prepare a bunch of atoms or molecules in an excited energy state (a population inversion), and then a passing photon of the right frequency triggers them to drop to a lower state while emitting a second photon that matches the first with the same frequency, phase, and direction. Do that in a resonant cavity and you’ve got gain, coherence, and a remarkably clean signal.
The Same but Different
However, there are many engineering challenges to building a maser. For one thing, cavities are bigger than required for lasers. Sources of noise and the mitigations are different, too.
The maser grew out of radar research in the early 1950s. Charles Townes and others at Columbia University used ammonia in a cavity to produce a 24 GHz maser, completing it in 1953. For his work, he would share the 1964 Nobel Prize for physics with two Soviet physicists, Nikolay Basov and Alexander Prokhorov, who had also built a maser.
Eclipsed but Useful
By 1960, the laser appeared, and the maser was nearly forgotten. After all, a visible-light laser is something anyone can immediately appreciate, and it has many spectacular applications.
At the time, the naming of maser vs laser was somewhat controversial. Townes wanted to recast the “M” in maser to mean “molecular,” and pushed to call lasers “optical masers.” But competitors wanted unique names for each type of emission, so lasers for light, grasers for gamma rays, xasers for X-rays, and so on. In the end, only maser and laser stuck.
Masers have uses beyond fancy physics experiments. Trying to detect signals that are just above the noise floor? Try a cryogenic maser amplifier. That’s one way the NASA Deep Space Network pulls in signals. (PDF) You cool a ruby, or other material, to just a bit of 4 °K and use the output of the resulting maser to pull out signals without adding much noise. This works well for radio astronomy, too.
Need an accurate time base? Over the long term, a cesium clock is the way to go. But over a short period, a hydrogen maser clock will offer less noise and drift. This is also important to radio astronomy for building systems to use very long baseline interferometry. The NASA network also uses masers as a frequency standard.
All Natural
While we didn’t have our own masers until 1953, nature forms them in space. Water, hydroxyl, and silicon monoxide molecules in space can form natural masers. Scientists can use these astrophysical masers to map regions of space and measure velocities using Doppler shifts.
Harold Weaver found these in 1965 and, as you might expect, they operate without cavities, but still emit microwaves and are an important source of data for scientists studying space.
Future
While traditional masers are difficult to build, modern material science may be setting the stage for a maser comeback. For example, using nitrogen-vacancy centers in diamonds rather than rubies can lead to masers that don’t require cryogenic cooling. A room-temperature maser could open up applications in much the same way that laser diodes made things possible that would not have been practical with high-voltage tubes and special gases.
Masers can produce signals that may be useful in quantum computing, too. So while you might think of the maser as a historical oddity, it is still around and still has an important job to do.
In a world where lasers are so cheap that they are a dollar-store cat toy, we’d love to see a cheap “maser on a chip” that works at room temperature might even put the maser in reach of us hackers. We hope we get there.
“Molecular amplification” makes no sense.
And now we need to see what we can get out of, Taser.
Toast amplification by stimulated emission of radiation? No good for science, Lone Star already jammed it. Delicious though.
That appeals to my Baser instincts.
TASER = Thomas Alva Swift Electric Rifle.
“Tom Swift” was a series of “boy genius inventor” novels and this was one of his inventions. I believe the makers of various oppressive “less lethal” devices nicked the name.
Jeebus I thought this was gonna be a TAYLOR Swift thing. Whew.
We had greasers at our school! Wait, what? Oh. Nevermind.
This article would have been better if it talked about Python. How do masers relate to Python? I like articles that talk about Python.
Next stop, maser CPUs. IMHO, not much remains in the way off, just technological challenges haven’t been addressed properly. Yet.
IMHO, still think photon CPUs are the real way forward. Photon CPUs coupled with the rest of the units via quantum tunneling, so quantum-tunneled bus connecting anything within the vicinity of the motherboard without the wires or PCBs. In short, invent us the Star Trek – you bring a module closer to the “react space”, ie, plug it into an empty slot with zero wires, just like in the series, fake boards with seemingly zero functionality, and then boom, it is connected to the bus and works as it should.
Scifi or not, time to move forward into the 21st century where’ve been for the last quarter century. Bring me not just RP2040/RP2350, but RP10 (nm) and RP100 (nm) – not nanometers of the transistors on the chips, RP is already at 40nm, nanometers of the wavelength of the photons shuttling to/fro, the low end of the ultraviolet, sold for the same $10 including S&H to my door.
Use a maser in a CNC rig to do fancy spot-cooking (as opposed to burning) in something, rather like a pinpoint microwave oven. Okay, I can’t offhand think of a single place where this would be useful, but there are more creative minds here than mine.