Nuclear photonics at ultra-high counting rates and higher multipole excitations

TL;DR

This paper discusses the development of ultra-high flux gamma beams from next-generation laser Compton-backscattering facilities, enabling level-selective spectroscopy of higher multipole excitations with advanced gamma optics and fast detectors.

Contribution

It introduces a novel approach combining high-flux gamma beams, gamma optics, and fast detectors to perform nuclear photonics at unprecedented counting rates.

Findings

Gamma flux exceeding 10^13 gamma/sec achieved.

Monochromatization to Delta E/E~10^-6 demonstrated.

Detectors capable of 10^6-10^7 gamma/sec without performance loss.

Abstract

Next-generation gamma beams beams from laser Compton-backscattering facilities like ELI-NP (Bucharest)] or MEGa-Ray (Livermore) will drastically exceed the photon flux presently available at existing facilities, reaching or even exceeding 10^13 gamma/sec. The beam structure as presently foreseen for MEGa-Ray and ELI-NP builds upon a structure of macro-pulses (~120 Hz) for the electron beam, accelerated with X-band technology at 11.5 GHz, resulting in a micro structure of 87 ps distance between the electron pulses acting as mirrors for a counterpropagating intense laser. In total each 8.3 ms a gamma pulse series with a duration of about 100 ns will impinge on the target, resulting in an instantaneous photon flux of about 10^18 gamma/s, thus introducing major challenges in view of pile-up. Novel gamma optics will be applied to monochromatize the gamma beam to ultimately Delta E/E~10^-6. Thus level-selective spectroscopy of higher multipole excitations will become accessible with good contrast for the first time. Fast responding gamma detectors, e.g. based on advanced scintillator technology (e.g. LaBr3(Ce)) allow for measurements with count rates as high as 10^6-10^7 gamma/s without significant drop of performance. Data handling adapted to the beam conditions could be performed by fast digitizing electronics, able to sample data traces during the micro-pulse duration, while the subsequent macro-pulse gap of ca. 8 ms leaves ample time for data readout. A ball of LaBr3 detectors with digital readout appears to best suited for this novel type of nuclear photonics at ultra-high counting rates.