Quantum sensor breakthrough could transform Army battlefield signal detection | Article | The United States Army

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Quantum sensor breakthrough could transform Army battlefield signal detection

By DEVCOM Army Research Laboratory Public AffairsJune 4, 2026

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The rubidium vapor cell at the core of ARL's Rydberg quantum sensor enables precise detection of radio-frequency signals that could give Soldiers improved situational awareness, more secure communications and faster decision-making on the battlefield.<br>(Photo Credit: U.S. Army)

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A glass cell containing rubidium atoms sits at the heart of ARL's Rydberg quantum sensor. Lasers excite the atoms to highly sensitive Rydberg states, enabling detection of the full 3D direction of incoming radio-frequency signals from the horn antennas visible in the background.<br>(Photo Credit: U.S. Army)

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This illustration captures the power of ARL's Rydberg quantum sensor. A single atom, excited to a highly sensitive Rydberg state, detects and analyzes radio-frequency signals from distant sources with remarkable precision.<br>(Photo Credit: U.S. Army)

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ADELPHI, Md. –  Army scientists achieved a major milestone in quantum sensing technology that could transform how electromagnetic signals are detected on the battlefield.

For the first time, scientists at the U.S. Army Combat Capabilities Development Command, known as DEVCOM, Army Research Laboratory demonstrated a quantum sensor that can measure the full 3D direction of radio-frequency electromagnetic fields. This breakthrough could provide the Army with tools to improve situational awareness, enhance secure communications and enable faster, more informed decision-making on the battlefield.

“Our work in quantum science is about giving our Soldiers new ways to sense and understand the world around them,” said David Meyer, ARL research physicist. “This research opens the door to detecting and pinpointing signals over a broad frequency range in a single sensing package, even in the most challenging environments.”

In the paper, published in Physical Review Applied, the researchers describe how their new sensor, based on Rydberg atoms, can determine not just the electromagnetic field strength but also the 3D polarization orientation and propagation direction, known as the k-vector. This is the first time such a measurement has been achieved using a quantum sensor.

Traditional sensors can only measure the strength of an electromagnetic field in one direction at a time. The new ARL-developed sensor, however, can “see” the direction and motion of the electromagnetic field, providing a complete 3D picture.

Unlike conventional antennas, which typically must be as large as the signals they detect and are often limited to narrow frequency ranges, ARL’s quantum sensor is independent of signal size, just a few centimeters across and can operate across the entire radio frequency spectrum. This property stems from the broadband capability of Rydberg atoms, which can operate from direct current to terahertz frequencies, and has been explored extensively by ARL scientists.

Despite its small size, the sensor can pinpoint the direction of incoming signals with remarkable accuracy, down to about two degrees, creating an extremely flexible platform for signal detection.

“The modern battlefield is an extremely complicated radio frequency environment,” Meyer said. “With the proliferation of autonomous systems, there can be hundreds of distinct signal sources. Having a single sensor platform that covers the entire radio-frequency spectrum and can measure the 3D direction of those fields represents a potentially transformative capability, especially in spectrum awareness. It is a great example of leveraging a quantum system’s unique properties to open new possibilities that aren’t possible with existing technology.”

The sensor uses a tiny glass cell filled with a vapor of rubidium atoms. By shining lasers through the cell, researchers put the atoms into special Rydberg states, a highly excited state that makes them extremely sensitive to electric fields. When a radio wave passes through, the atoms react in a way that reveals not just the strength, but the full 3D direction and movement of the field.

This means the sensor can not only detect the presence of a radio signal but also determine exactly where the signal is coming from and how it’s moving, in three dimensions.

This latest advance builds on ARL’s previous work developing the Rydberg electrometer. In 2024, the team published results in Physical Review...