Spectral narrowing of x-ray pulses for precision spectroscopy with nuclear resonances

Heeg, Kilian Peter; Kaldun, Andreas; Strohm, C.; Reiser, Patrick; Ott, Christian; Subramanian, Rajagopalan; Lentrodt, Dominik; Haber, Johann; Wille, Hans‐Christian; Goerttler, Stephan; Rüffer, R.; Keitel, Christoph H.; Röhlsberger, Ralf; Pfeifer, Thomas; Evers, Jörg

doi:10.1126/science.aan3512

Cited by 52 publications

(57 citation statements)

References 32 publications

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“…which is the quantum correspondent of the result found in [5]. Note that the phase difference in this case is given by the Doppler-shift factor Ωt and that an additional phase shift φ must be added to it if the phase control technique developed in reference [14] is used.…”

Section: Realization With Mössbauer Foilssupporting

confidence: 53%

“…In our scheme, a phase shifter φ controls the interference of these two contributions in the measured intensity of the scattered light, and thus enables one to recover the quantum dynamical couple correlation function of the target. (b) If the split and overlap units are realized using Mössbauer filter foils, then the required phase control is possible using mechanical displacements of the split foil as demonstrated in [14]. (c) A generic implementation of the phase control is a split-and-delay line, with a phase plate in one of the two arms.…”

mentioning

confidence: 99%

“…As we will show below, this enables control of the interference between the different scattering channels, and thereby provides access to the full ISF. For Mössbauer foils, the required phase control is possible with sub-Ångstrom precision on a nanosecond scale using mechanical displacements of the split foil, as demonstrated in [14] (see Fig. 1 (b)).…”

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confidence: 99%

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Probing Quantum Dynamical Couple Correlations with Time-Domain Interferometry

Castrignano

Evers

2019

Phys. Rev. Lett.

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Time domain interferometry is a promising method to characterizes spatial and temporal correlations at x-ray energies, via the so-called intermediate scattering function and the related dynamical couple correlations. However, so far, it has only been analyzed for classical target systems. Here, we provide a quantum analysis, and suggest a scheme which allows to access quantum dynamical correlations. We further show how TDI can be used to exclude classical models for the target dynamics, and illustrate our results using a single particle in a double well potential.

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Section: Realization With Mössbauer Foilssupporting

confidence: 53%

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confidence: 99%

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Probing Quantum Dynamical Couple Correlations with Time-Domain Interferometry

Castrignano

Evers

2019

Phys. Rev. Lett.

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“…The very large bandwidth has drawbacks as well as advantages. On the one hand, many possible interesting experiments involving temporal control and manipulation, such as the creation of x-ray frequency combs [24] and spectral profile manipulation [25], cannot be performed with these electronic x-ray transitions, since they require temporal control not available at the corresponding short timescales. On the other hand, the large bandwidth means that the brilliance of current x-ray sources may permit multiphoton and nonlinear experiments in the near future.…”

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confidence: 99%

Spectral Control of an X-Ray L -Edge Transition via a Thin-Film Cavity

et al. 2019

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By embedding a thin layer of tantalum in an x-ray cavity, we observe a change in the spectral characteristics of an inner-shell transition of the metal. The interaction between the cavity mode vacuum and the L III-edge transition is enhanced, permitting the observation of the collective Lamb shift, superradiance, and a Fano-like cavity-resonance interference effect. This experiment demonstrates the feasibility of cavity quantum electrodynamics with electronic resonances in the x-ray range with applications to manipulating and probing the electronic structure of condensed matter with high-resolution x-ray spectroscopy in an x-ray cavity setting.

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“…Earlier experimental achievements in this field include demonstrations of the Autler-Townes effect [1], γ-ray echo via abrupt shift of a nuclear absorber [2], controllable storage and release of nuclear excitation by switch of the magnetic field direction [3], electromagnetically induced transparency (EIT) via a nuclear level anti-crossing [4], slowing down of γ-photon in a nuclear absorber with a split line [5] and other effects discussed in the review [6]. Recent experimental advances include demonstration of parametric down-conversion in the Langevin regime [7], cav-ity electromagnetically induced transparency [8], collective Lamb shift [9], vacuum-assisted generation of atomic coherences [10], single-photon revival in nuclear absorbing sandwiches [11], phase-sensitive measurements characterizing the quantum state of a nuclei at hard x-ray energies [12], and group velocity control for 14.4 keV-energy photons [13], spectral enhancement of x-ray radiation via a moving absorber [14] and demonstration of a strong coupling between two nuclear polariton modes [15]. Also, a number of important effects were theoretically predicted recently including dynamical control of x-ray polarization qubits by nuclear Mössbauer resonance [16], heralded entanglement between two crystal-hosted macroscopic nuclear ensembles [17], as well as mapping and storing x-ray pulses in a thin-film planar x-ray cavity with embedded resonant nuclear medium [18].…”

Section: Introductionmentioning

confidence: 99%

Ultimate capabilities for compression of the waveform of a recoilless γ-ray photon into a pulse sequence in an optically deep vibrating resonant absorber

et al. 2018

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Recently, an exponentially decaying waveform (the time-dependence of detection probability) of a Mössbauer γ-ray photon was transformed into a regular sequence of short pulses in a sinusoidally vibrating recoilless resonant absorber [Nature, 508, 80-83 (2014)]. In the present paper, we show that the peak amplitude of the pulses can be considerably increased via joint adjustment of optical depth of the absorber and the initial phase of its vibration. This is due to reduction of the photoelectric absorption and maximizing the constructive temporal interference of spectral content of the single-photon wave packet in optically deep absorber. The ultimate capabilities for transforming a waveform of 14.4 keV photon from 57 Co radioactive source into a regular train of pulses in a harmonically vibrating 57 Fe recoilless resonant absorber are discussed. We show that the shortest pulse duration, produced by this technique, is limited by the highest available vibration frequency of a piezo-transducer and at present can be as short as 7.7 ps. The maximum achievable detection probability of the transformed photon at the experimentally feasible conditions is more than two times higher than peak detection probability of the photon emitted by the source and nearly 5.5 times higher than obtained in the above reference.

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Spectral narrowing of x-ray pulses for precision spectroscopy with nuclear resonances

Cited by 52 publications

References 32 publications

Probing Quantum Dynamical Couple Correlations with Time-Domain Interferometry

Probing Quantum Dynamical Couple Correlations with Time-Domain Interferometry

Spectral Control of an X-Ray L -Edge Transition via a Thin-Film Cavity

Ultimate capabilities for compression of the waveform of a recoilless γ-ray photon into a pulse sequence in an optically deep vibrating resonant absorber

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