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A laser concept developed by Pitt physicists could surpass a 60-year-old limitation

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  • Technology & Science
  • Faculty
  • Department of Physics and Astronomy
  • Kenneth P. Dietrich School of Arts and Sciences

Maser? Mamer? Lamer? Whatever it is, it鈥檚 not technically a laser 鈥 but it could soon do the job of one better than any that exist today.

A team of Pitt physicists recently published a design that would surpass a theoretical limit on the effectiveness of lasers that鈥檚 barely changed in more than 60 years, opening new potential applications and maybe even necessitating a name change for the technology.

Ideally, a laser would maintain a pure color no matter how long it shines, a property that physicists refer to as coherence. 鈥淚f a laser is coherent, that鈥檚 like a really good clock,鈥 explained Department of Physics and Astronomy Assistant Professor in the Kenneth P. Dietrich College of Arts and Sciences. 鈥淏ut in real life, that鈥檚 not how lasers work.鈥

Instead, they drift. The frequency of light waves they emit, which influences how pure the beam鈥檚 color is, changes slightly over time. That鈥檚 because the amount of light bouncing around inside of a laser alters the color that the laser ultimately produces. The process is called stimulated emission, a phrase that makes up the S and E in the acronym LASER 鈥 and which the Pitt team鈥檚 design bypasses entirely.

What their design calls for is replacing components of a traditional laser to better control the flow of light, making use of the building blocks of quantum computers that have been developed over the last decade. 鈥淚n quantum computers, you have qubits, these are basically like atoms in the laser, and you have cavities,鈥 Pekker said. 鈥淪o why not just try to build the laser out of quantum computer components?鈥

Their calculations show that the resulting microwave laser design would have a coherence far higher than the previously proposed limit, which has budged only once since 1958. The team, including researchers from the labs of Department of Physics & Astronomy faculty members and , last month.

Few people would ever have the need for a laser with the ultra-high coherence enabled by the new design, but there are several areas where it could come in handy. Pekker cites astronomical uses like making ultra-fine measurements of gravitational waves, as well as precise timekeeping and quantum computation. And the laser may not stay theoretical for long: Pitt physics PhD student Maria Mucci is currently working on building one.

The design got its start not during frustrated solo scribblings or grueling late nights in the lab but from, as Pekker puts it, 鈥渄rinking too much coffee鈥 while the three groups of physicists, each with different specialties, bounced ideas back and forth. 鈥淚t鈥檚 a really good example of how we can do better by talking to each other and not just going to our offices and shutting the door,鈥 he said.

Since the new technology no longer falls under the traditional definition of a laser, the team鈥檚 caffeine-fueled brainstorms also produced a few potential names 鈥 Hatridge鈥檚 addition of an , for instance, created the aforementioned 鈥渓amer.鈥

They鈥檙e still workshopping it.

鈥淐oming up with a good name is important, but we haven鈥檛 managed it yet,鈥 Pekker said. 鈥淣aming stuff is hard.鈥