Real-time antiproton annihilation vertexing with submicrometer resolution

Berghold, Michael; Orsucci, Davide; Guatieri, Francesco; Alfaro, Sara; Auzins, Marcis; Bergmann, Benedikt; Burian, Petr; Brusa, Roberto Sennen; Camper, Antoine; Caravita, Ruggero; Castelli, Fabrizio; Cerchiari, Giovanni; Ciuryło, Roman Jerzy; Chehaimi, Ahmad; Consolati, Giovanni; Doser, Michael; Eliaszuk, Kamil; Ferguson, Riley Craig; Germann, Matthias; Giszczak, Anna; Glöggler, Lisa; Graczykowski, Łukasz; Grosbart, Malgorzata; Gusakova, Natali; Gustafsson, Fredrik; Haider, Stefan; Huck, Saiva; Hugenschmidt, Christoph; Janik, Malgorzata Anna; Januszek, Tymoteusz Henryk; Kasprowicz, Grzegorz; Kempny, Kamila; Khatri, Ghanshyambhai; Kłosowski, Łukasz; Kornakov, Georgy; Krumins, Valts; Lappo, Lidia; Linek, Adam; Mariazzi, Sebastiano; Moskal, Pawel; Nowicka, Dorota; Pandey, Piyush; Pęcak, Daniel; Penasa, Luca; Petracek, Vojtech; Piwiński, Mariusz; Pospisil, Stanislav; Povolo, Luca; Prelz, Francesco; Rangwala, Sadiqali; Rauschendorfer, Tassilo; Rawat, Bharat; Rienäcker, Benjamin; Rodin, Volodymyr; Røhne, Ole; Sandaker, Heidi; Sharma, Sushil; Smolyanskiy, Petr; Sowiński, Tomasz; Tefelski, Dariusz; Vafeiadis, Theodoros; Volponi, Marco; Welsch, Carsten Peter; Zawada, Michal; Zielinski, Jakub; Zurlo, Nicola

doi:10.1126/sciadv.ads1176

Primary goal of the AEḡIS experiment is to precisely measure the free fall of antihydrogen within Earth’s gravitational field. To this end, cold (≈ 50 K) antihydrogen will traverse a two-grid moiré deflectometer before annihilating onto a position-sensitive detector, which shall determine the vertical position of the annihilation vertex relative to the grids with micrometric accuracy. Here, we introduce a vertexing detector based on a modified mobile camera sensor and experimentally demonstrate that it can measure the position of antiproton annihilations within 0.62+−0.400.22 μm, a 35-fold improvement over the previous state of the art for real-time antiproton vertexing. These methods are directly applicable to antihydrogen. Moreover, the sensitivity to light of the sensor enables in situ calibration of the moiré deflectometer, substantially reducing systematic errors. This sensor emerges as a breakthrough technology toward the AEḡIS scientific goals and will constitute the basis for t...

Primary goal of the AEḡIS experiment is to precisely measure the free fall of antihydrogen within Earth’s gravitational field. To this end, cold (≈ 50 K) antihydrogen will traverse a two-grid moiré deflectometer before annihilating onto a position-sensitive detector, which shall determine the vertical position of the annihilation vertex relative to the grids with micrometric accuracy. Here, we introduce a vertexing detector based on a modified mobile camera sensor and experimentally demonstrate that it can measure the position of antiproton annihilations within 0.62+−0.400.22 μm, a 35-fold improvement over the previous state of the art for real-time antiproton vertexing. These methods are directly applicable to antihydrogen. Moreover, the sensitivity to light of the sensor enables in situ calibration of the moiré deflectometer, substantially reducing systematic errors. This sensor emerges as a breakthrough technology toward the AEḡIS scientific goals and will constitute the basis for the development of a large-area detector for conducting antihydrogen gravity measurements.

Real-time antiproton annihilation vertexing with submicrometer resolution / Berghold, Michael; Orsucci, Davide; Guatieri, Francesco; Alfaro, Sara; Auzins, Marcis; Bergmann, Benedikt; Burian, Petr; Brusa, Roberto Sennen; Camper, Antoine; Caravita, Ruggero; Castelli, Fabrizio; Cerchiari, Giovanni; Ciuryło, Roman Jerzy; Chehaimi, Ahmad; Consolati, Giovanni; Doser, Michael; Eliaszuk, Kamil; Ferguson, Riley Craig; Germann, Matthias; Giszczak, Anna; Glöggler, Lisa; Graczykowski, Łukasz; Grosbart, Malgorzata; Gusakova, Natali; Gustafsson, Fredrik; Haider, Stefan; Huck, Saiva; Hugenschmidt, Christoph; Janik, Malgorzata Anna; Januszek, Tymoteusz Henryk; Kasprowicz, Grzegorz; Kempny, Kamila; Khatri, Ghanshyambhai; Kłosowski, Łukasz; Kornakov, Georgy; Krumins, Valts; Lappo, Lidia; Linek, Adam; Mariazzi, Sebastiano; Moskal, Pawel; Nowicka, Dorota; Pandey, Piyush; Pęcak, Daniel; Penasa, Luca; Petracek, Vojtech; Piwiński, Mariusz; Pospisil, Stanislav; Povolo, Luca; Prelz, Francesco; Rangwala, Sadiqali; Rauschendorfer, Tassilo; Rawat, Bharat; Rienäcker, Benjamin; Rodin, Volodymyr; Røhne, Ole; Sandaker, Heidi; Sharma, Sushil; Smolyanskiy, Petr; Sowiński, Tomasz; Tefelski, Dariusz; Vafeiadis, Theodoros; Volponi, Marco; Welsch, Carsten Peter; Zawada, Michal; Zielinski, Jakub; Zurlo, Nicola. - In: SCIENCE ADVANCES. - ISSN 2375-2548. - 11:14(2025). [10.1126/sciadv.ads1176]