Proof-of-principle experiment for the dark-field detection concept for measuring vacuum birefringence

Šmíd, Michal; Khademi, Pooyan; Ahmadiniaz, Naser; Andrzejewski, Michal; Baehtz, Carsten; Brambrink, Erik; Bulička, Jakub; Burian, Tomáš; Cafiso, Samuele Di Dio; Chalupský, Jaromír; Cowan, Thomas E.; Göde, Sebastian; Grenzer, Jörg; Hájková, Věra; Hilz, Peter; Hippler, Willi; Höppner, Hauke; Horynová, Alžběta; Huang, Lingen; Humphries, Oliver; Jelínek, Šimon; Juha, Libor; Karbstein, Felix; Kohlfürst, Christian; Garcia, Alejandro Laso; Lötzsch, Robert; Masruri, Masruri; Matheron, Aimé; Nakatsutsumi, Motoaki; Paulus, Gerhard G.; Pelka, Alexander; Preston, Thomas R.; Rahul, Sripati V.; Randolph, Lisa; Sävert, Alexander; Schlenvoigt, Hans-Peter; Schützhold, Ralf; Schwinkendorf, Jan Patrick; Stöhlker, Thomas; Toncian, Monika; Toncian, Toma; Valialshchikov, Maksim; Vozda, Vojtěch; Weckert, Edgar; Wessel, Colin; Wild, Jan; Zastrau, Ulf; Zepf, Matt

Proof-of-principle experiment for the dark-field detection concept for measuring vacuum birefringence

Šmíd, Michal; Khademi, Pooyan; Ahmadiniaz, Naser; Andrzejewski, Michal; Baehtz, Carsten; Brambrink, Erik; Bulička, Jakub; Burian, Tomáš; Cafiso, Samuele Di Dio; Chalupský, Jaromír; Cowan, Thomas E.; Göde, Sebastian; Grenzer, Jörg; Hájková, Věra; Hilz, Peter; Hippler, Willi; Höppner, Hauke; Horynová, Alžběta; Huang, Lingen; Humphries, Oliver; Jelínek, Šimon; Juha, Libor; Karbstein, Felix; Kohlfürst, Christian; Garcia, Alejandro Laso; Lötzsch, Robert; Masruri, Masruri; Matheron, Aimé; Nakatsutsumi, Motoaki; Paulus, Gerhard G.; Pelka, Alexander; Preston, Thomas R.; Rahul, Sripati V.; Randolph, Lisa; Sävert, Alexander; Schlenvoigt, Hans-Peter; Schützhold, Ralf; Schwinkendorf, Jan Patrick; Stöhlker, Thomas; Toncian, Monika; Toncian, Toma; Valialshchikov, Maksim; Vozda, Vojtěch; Weckert, Edgar; Wessel, Colin; Wild, Jan; Zastrau, Ulf; Zepf, Matt

2025

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Abstract

Vacuum fluctuations give rise to effective nonlinear interactions between electromagnetic fields. These generically modify the characteristics of light traversing a strong-field region. X-ray free-electron lasers (XFELs) constitute a particularly promising probe, due to their brilliance, the possibility of precise control and favorable frequency scaling. However, the nonlinear vacuum response is very small even when probing a tightly focused high-intensity laser field with XFEL radiation and direct measurement of light-by-light scattering of real photons and the associated fundamental physics constants of the quantum vacuum has not been possible to date. Achieving a sufficiently good signal-to-background separation is key to a successful quantum vacuum experiment. To master this challenge, a dark-field detection concept has recently been proposed. Here we present the results of a proof-of-principle experiment validating this approach by demonstrating that using real-world x-ray optics the background signal can be suppressed sufficiently to measure the weak nonlinear response of the vacuum.