A characterization and detection method for x-ray excitation of M\"ossbauer nuclei beyond the low-excitation regime

TL;DR

This paper proposes a method to detect nonlinear excitations of Mössbauer nuclei beyond the low-excitation regime by comparing coherent and incoherent x-ray scattering, enabling experimental verification of high-excitation states.

Contribution

It introduces a novel detection technique based on scattering ratios to identify excitations beyond the low-excitation regime in Mössbauer nuclei embedded in x-ray waveguides.

Findings

The ratio of coherent to incoherent scattering remains constant within the low-excitation regime.

Deviations from the ratio indicate nonlinear excitations beyond the low-excitation regime.

The method applies to both impulsive and extended x-ray excitations.

Abstract

Up to now, experiments involving M\"ossbauer nuclei have been restricted to the low-excitation regime. The reason for this is the narrow spectral line width of the nuclei. This defining feature enables M\"ossbauer spectroscopy with remarkable resolution and convenient control and measurements in the time domain, but at the same time implies that only a tiny part of the photons delivered by accelerator-based x-ray sources with orders-of-magnitude larger pulse bandwidth are resonant with the nuclei. X-ray free-electron lasers promise a substantial enhancement of the number of nuclear-resonant photons per pulse, such that excitations beyond the low-excitation (LER) regime come within reach. This raises the question, how the onset of non-linear excitations could be experimentally verified. Here, we develop and explore a method to detect an excitation of nuclear ensembles beyond the LER for ensembles of nuclei embedded in x-ray waveguides. It relies on the comparison of the x-rays coherently and incoherently scattered off of the nuclei. As a key result, we show that the ratio of the two observables is constant within the LER, essentially independent of the details of the nuclear system and the characteristics of the exciting x-rays. Conversely, deviations from this equivalence serve as a direct indication of excitations beyond the LER. Building upon this observation, we develop a variety of experimental signatures both, for near-instantaneous impulsive and for temporally-extended non-impulsive x-ray excitation. Correlating coherently and incoherently scattered intensities further allows one to compare theoretical models of nonlinear excitations more rigorously to corresponding experiments.