Dear colleagues and friends of the Helmholtz Institute Jena,
we are glad to provide you with the latest issue of our institute newsletter. Below you find informations and news about recent activities of our institute.
Kind Regards, Helmholtz Institute Jena
New tests of quantum electrodynamics in extreme fields with the heaviest two-electron ion
Pioneering experiment exploits quantum properties of X-ray light
The experiment was conducted at the experimental storage ring of ESR of GSI/FAIR in the framework of the FAIR Phase 0 research program. (Photo: A. Zschau, GSI/FAIR)
Recently, an international research team has successfully carried out a high precision x-ray spectroscopy measurement on helium-like uranium, the simplest and heaviest many-electron atomic system. The obtained results allow, for the first time in this regime, to disentangle and to test separately high-order (two-loop) one-electron and two-electron quantum electrodynamics (QED) effects and set a new important benchmark for QED in the strong field domain. Moreover, the achieved accuracy of 37 parts per million allows to discriminate between different theoretical approaches developed throughout the last decades for describing He-like systems. The measurement took place at the Experimental Storage Ring (ESR) at GSI/FAIR in Darmstadt within the FAIR Phase0 research program. The research team, led by the CNRS and Sorbonne University (Institut des nanosciences de Paris), France, and comprising (among others) scientists from GSI/FAIR, the Helmholtz Institute Jena, and the Friedrich Schiller University of Jena, presents the results in the scientific journal Nature.
Quantum electrodynamics (QED), the quantum field theory that describes the interaction between light and matter, is one of the important cornerstones of the Standard Model. QED is generally considered as the best tested quantum field theory. However, recent precision measurements of the gyromagnetic factor of the muon and the fine structure of positronium show significant disagreements with theoretical predictions, stressing the need for new complementary tests.
At present, most stringent tests of QED are based on extremely precise studies performed in the domain of relatively low electromagnetic field strengths and light atoms and ions, where perturbation methods can be efficiently implemented in the QED calculations. In the regime of extreme fields of heavy ions, the QED calculations enter a qualitatively different non-perturbative regime (with respect to the nuclear charge), making accurate theoretical predictions challenging. Experiments in this domain are equally challenging and thus QED tests in strong fields currently lack the high precision reached for light atoms. New tests are required, in particular in the regime of extreme fields of heavy ions, where QED effects are greatly enhanced due to the extremely strong electromagnetic field of the heavy nucleus, reaching several orders of magnitude higher than the most intense laser fields available nowadays.
GSI/FAIR is at present the unique place worldwide where the heaviest ions in any desired charge-state can be produced with subsequent acceleration and stripping, followed by cooling and storage in the dedicated storage ring ESR. The international research team used the ESR to perform a new stringent test based on precision x-ray spectroscopy of helium-like uranium (with two bound electrons), the simplest and heaviest many-electron atomic system, and compared its transition energy to the energy of similar transitions in lithium-like (three electrons) and beryllium-like uranium ions (four electrons).
For the measurement, dedicated Bragg crystal spectrometers have been constructed and mounted at the gas-jet interaction chamber of the ESR. Differently from past experiments, a new calibration method based on a combination of moving and stationary energy references is implemented. This new method (along with other improvements) provided a gain in accuracy of almost one order of magnitude on the absolute transition energy. The obtained accuracy of 37 parts per million allows, for the first time for high-Z helium-like ions, to test high-order QED effects and sets a new important benchmark for QED in the strong field domain. In addition, such an accuracy enables the discrimination between different theoretical models and approximations developed throughout the last decades. Moreover, by comparing the transition energies for the different uranium ions, one-electron and many-electron QED contributions could be clearly disentangled for the first time in such a high-field regime. (CP)
The Helmholtz Institute Jena supports the Weltoffenes Thüringen initiative. The decentralized, networked initiative aims to send out a signal that many people,…
On 20 December 2023, scientists from the Laserlab-Europe partners Max Born Institute for Nonlinear Optics and Short-Pulse Spectroscopy (MBI, Berlin) and Helmholtz…
Two PhD candidates from Helmholtz Institute Jena, Wilhelm Eschen and Chang Liu, have received this year’s Siegfried Czapski Publication Prize.
The Siegfried Czapski…
Hell S,
Späthe J,
Førre M,
Klas R,
Rothhardt J,
Limpert J,
Moshammer R,
Ott C,
Paulus GG,
Fritzsche S,
Kübel M.
Coincidence measurement of two-photon double ionization of argon through an autoionizing resonance.
Physical review research.
2025 Aug.;
7(3):L032030.
[DOI][File]
Rinderknecht HG,
Dill E,
Macleod AJ,
King B,
Sow K,
Bahk S-,
Begishev IA,
Karbstein F,
Schreiber J,
Zepf KM,
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On measuring stimulated photon–photon scattering using multiple ultraintense lasers.
Physics of plasmas.
2025 Aug.;
32(8):083301.
[DOI][File]
Boller P,
Hornung J,
Dumitru A,
Kanstein C,
Özalp E,
Ohland JB,
Wegert LM,
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Prepulse-induced changes in ion acceleration direction: Insights from TNSA regime experiments and simulations at PHELIX.
Physics of plasmas.
2025 Aug.;
32(8):083105.
[DOI][File]
Wang W,
Fritzsche S,
Li Y.
Search for variations of the fine-structure constant via the hyperfine electronic bridge in highly charged Th 229 ions.
Physical review / A.
2025 Aug.;
112(2):022811.
[DOI][File]
Lohse LM,
Andrejić P,
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Vassholz M,
Neuhaus C,
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Collective Nuclear Excitation and Pulse Propagation in Single-Mode X-Ray Waveguides.
Physical review letters.
2025 Jul.;
135(5):053601.
[DOI][File]
Spieß LJ,
Chen S,
Wilzewski A,
Wehrheim M,
Gilles J,
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Excited-State Magnetic Properties of Carbon-like Ca 14 +.
Physical review letters.
2025 Jul.;
135(4):043002.
[DOI][File]
Middents W,
Gumberidze A,
Krings T,
Over-Winter T,
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Vockert M,
Weber G,
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Linear polarization properties of energetic x-rays being Compton-scattered off atomic targets.
New journal of physics.
2025 Jul.;
27(7):073204 -.
[DOI][File]
Silletti L,
Wahid Ab,
Grigorova TF,
Pratolli L,
Silva A,
Hermellin N,
Mullins T,
Trabattoni A,
Heyl C,
Brahms C,
Wanie V,
Travers JC,
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Multi-pass cell driven multi-kHz dispersive wave emission of broadband deep-UV pulses.
APL photonics.
2025 Jul.;
10(7):070801.
[DOI][File]
Over-Winter T,
Middents W,
Weber G,
Stöhlker T.
Polarization Reconstruction Based on Monte Carlo Simulations for a Compton Polarimeter.
Atoms.
2025 Jul.;
13(7):65 -.
[DOI][File]
Huang HK,
Wen WQ,
Huang ZK,
Yuan Y,
Zhang CY,
Si R,
Wu SJ,
Chen CY,
Fritzsche S,
Schippers S,
Wang HB,
Wang SX,
Liu C,
Ma WL,
Zhou XP,
Wan MY,
Mao LJ,
Li J,
Tang MT,
Yan KY,
Zhou YB,
Yuan YJ,
Yang JC,
Zhang SF,
Zhu LF,
Ma X.
Absolute Rate Coefficients for Dielectronic Recombination of Sodium-like Iron Ions: Experiment and Theory.
The astrophysical journal / Supplement series.
2025 Jun.;
278(2):44 -.
[DOI][File]
