A black hole is not sitting inside a lab in Manhattan, but some of its strangest physics just helped shape a tabletop experiment there.
For decades, physicists have wondered whether waves could steal energy from something spinning fast enough. The idea traces back to Roger Penrose, who proposed in the late 1960s that a rotating black hole could, under the right conditions, give up some of its energy. Yakov Zel’dovich soon extended that logic to waves, predicting that a wave meeting a rapidly rotating object could come away stronger than it arrived.
Now a team at the Advanced Science Research Center at the CUNY Graduate Center says it has demonstrated a new version of that effect, not by spinning a physical object to extraordinary speeds, but by building an electronic system that only behaves as if it were rotating. The result, reported in Nature, turns a long-theoretical idea into a controllable device that amplifies selected waves by drawing energy from what the researchers call synthetic rotation.

“Our approach facilitates a new method of wave–matter interaction in which waves with selected rotational properties extract energy from synthetic time-engineered rotation, producing a form of broadband selective amplification,” said Andrea Alù, the study’s principal investigator, Distinguished Professor and Einstein Professor of Physics at the CUNY Graduate Center, and founding director of the CUNY ASRC’s Photonics Initiative.
The central question was deceptively simple. Could electromagnetic waves sent into a device that never physically moves behave as though they were interacting with something rotating at ultrafast speed, and then extract energy from that apparent motion?
The team’s answer came in the form of a ring-shaped network of electronic resonators. Instead of spinning the ring, the researchers rapidly modulated the resonators’ properties in a carefully timed pattern that traveled around the circle. To incoming waves, that moving pattern looked like rotation.
That distinction matters because ordinary mechanics quickly runs into limits. In earlier work on rotational wave amplification, extending the effect to electromagnetic waves and especially to optics has been difficult. Reaching the needed rotational speeds is hard, and larger rotating objects can create other problems, including poor overlap with the kinds of waves used in the experiments.
The CUNY device sidesteps those obstacles by replacing physical motion with engineered modulation in space and time. The system remains still, but its electromagnetic properties sweep around the ring in sequence, creating what the researchers describe as a synthetic form of ultrafast rotation.

Because that synthetic motion is not bound by the same practical limits as mechanically spinning matter, it can reach effective rotational speeds that would otherwise be out of reach in the lab. That, in turn, lets researchers probe a regime tied to extreme rotational Doppler shifts, the frequency changes that waves experience in rotating systems.
“Waves with the appropriate rotational characteristics extracted energy from the system and became amplified, reproducing the essential physics of the Penrose–Zel’dovich process,” said co-lead author Hady Moussa, a former PhD student with the CUNY ASRC Photonics Initiative. “Our approach relies on engineered metamaterials that are designed to control how waves propagate.”
The experiment used radio-frequency circuitry rather than an astronomical object or a rapidly spinning cylinder, but the underlying theme is similar. If a wave enters the right rotational regime, the theory says it can tap energy from the rotating system and emerge stronger.
In the team’s setup, the key signature appeared when the modulation rate became high enough to push a downconverted signal into what the researchers describe as a negative Doppler-shift regime. In that regime, the wave’s orbital angular momentum, or OAM, reversed sign, a marker of time-reversed dynamics in the fast-rotating frame.
That reversal was not just mathematical bookkeeping. It coincided with amplification.
The prototype itself was small, a loop of three resonators configured in a delta topology and modulated by varactor diodes. The researchers drove the system with an input signal at 100 megahertz and tracked what happened as they changed the modulation frequency. At lower modulation rates, the downconverted subharmonic weakened as expected. Once the modulation frequency rose past the input frequency, the behavior changed. The OAM order flipped, and the signal entered the amplification regime.

Experimentally, the maximum net gain reached about 7.8 decibels.
Lead author Hadiseh Nasari, a post-doctoral researcher with the CUNY ASRC’s Photonics Initiative, said the result moves a long-standing concept into an experimental setting with broader reach. “This successful experiment moves ideas about extreme rotational dynamics from theory to practice and creates a versatile experimental platform for exploring a broad range of phenomena at the intersection of astrophysics, wave physics, and quantum science,” she said. “The work has implications for advances in fundamental science and in communications, optics and photonics.”
The paper argues that the amplification in this system does not reproduce every detail of the original Penrose or Zel’dovich scenarios. The device is not a one-to-one mechanical analog. But the authors say it is driven by the same thermodynamic logic: when a mode effectively crosses into a negative-frequency regime in a rotating frame, dissipation can open a channel for net energy extraction from the external drive.
One of the study’s more unusual conclusions is that loss, usually treated as an obstacle, can help here. The analysis showed that parasitic losses and modulation strength work together in enabling the amplification process. In fact, at a fixed output frequency in the synthetic superluminal regime, larger losses increased the effective amplification and broadened the gain response.
The broader framework behind the experiment involves what the authors call rotating space-time crystals and angular-momentum bandgaps. In this system, modulation patterns shift the device from a space-like regime, associated with frequency gaps, into a time-like regime, where gaps open in angular momentum instead. Inside those gaps, parametric coupling allows energy transfer that selectively amplifies certain rotational wave modes.

That selectivity could matter for technology. Because the platform can be tuned to favor waves with particular rotational properties, it points to possible uses in wave control and data encoding. The paper also suggests possible applications in wireless communications, classical optics and quantum optics.
The current experiment operated in a radio-frequency circuit, but the authors argue the same principles could be extended to higher frequencies, including photonic and possibly optical systems, through all-optical modulation schemes. They also say larger ring networks with more resonators could expand the range of accessible orbital angular momentum states.
For now, the deeper appeal may be conceptual. A phenomenon inspired by black hole energy extraction has been brought into a controlled lab device that never actually spins.
The work offers researchers a new way to study extreme rotational wave behavior without relying on mechanically rotating objects, which are hard to push into the necessary speed range. That could make experiments on unusual Doppler effects, wave amplification and time-varying media far more practical.
It also points to devices that selectively amplify signals with specific rotational properties, which may prove useful in communications and photonics.
Longer term, the same approach could help scientists manipulate light in new ways, process information with greater control, and test wave effects linked to astrophysics and quantum systems in ordinary laboratory settings.
Research findings are available online in the journal Nature.
The original story “CUNY researchers bring black hole theory to life in the lab” is published in The Brighter Side of News.
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