30.04.2025 • NewsSmartkameras

Smartphone photo sensors works as antimatter camera

A new device can pinpoint antiproton annihilations with a high resolution, 35-fold better than previous real-time methods.

Scientists working together in the “Antihydrogen Experiment: Gravity, Interferometry, Spectroscopy” (AEgIS) and other experiments at CERN’s Antimatter Factory, such as ALPHA and GBAR, are on a mission to measure the free-fall of antihydrogen under Earth's gravity with high precision, each using a different technique. AEgIS’s approach involves producing a horizontal beam of antihydrogen and measuring its vertical displacement using a device called a moiré deflectometer that reveals tiny deviations in motion and a detector that records the antihydrogen annihilation points. “For AEgIS to work, we need a detector with incredibly high spatial resolution, and mobile camera sensors have pixels smaller than 1 micrometer,” says Francesco Guatieri from the research neutron source FRM II at Technical University Munich.

The optical antimatter imager with the 60 photo sensors taken from mobile...
The optical antimatter imager with the 60 photo sensors taken from mobile phones. (Source: A. Heddergott, TUM)

“We have integrated 60 of them in the single photographic detector, the Optical Photon and Antimatter Imager (OPHANIM), with the highest number of pixels currently operational: 3840 Megapixels. Previously, photographic plates were the only option, but they lacked real-time capabilities. Our solution, demonstrated for antiprotons and directly applicable to antihydrogen, combines photographic-plate-level resolution, real-time diagnostics, self-calibration and a good particle collection surface, all in one device”, Guatieri says.

Specifically, the researchers used optical image sensors that had previously been shown to be capable of imaging low-energy positrons in real time with unprecedented resolution. “We had to strip away the first layers of the sensors, which are made to deal with the advanced integrated electronics of mobile phones,” says Guatieri. “This required high-level electronic design and micro-engineering.” Master's students Michael Berghold and Markus Münster at the TUM School of Engineering and Design played a key role in the project.

“This is a game-changing technology for the observation of the tiny shifts due to gravity in an antihydrogen beam travelling horizontally, and it can also find broader applications in experiments where high position resolution is crucial, or to develop high-resolution trackers,” says AEgIS spokesperson Ruggero Caravita. “This extraordinary resolution enables us also to distinguish between different annihilation fragments, paving the way for new research on low-energy antiparticle annihilation in materials,” concludes Caravita. (Source: TUM)

Reference: M. Berghold et al.: Real-time antiproton annihilation vertexing with submicrometer resolution, Sci. Adv. 11, ads1176 (2025); DOI: 10.1126/sciadv.ads1176

Link: Antihydrogen Experiment: Gravity, Interferometry, Spectroscopy” (AEgIS), CERN, Geneva, Switzerland • Research Neutron Source Heinz Maier-Leibnitz (FRM II), Technical University of Munich, Garching bei München, Germany

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