The Auger-Meitner Radioisotope Microscope: an instrument for characterization of Auger electron multiplicities and energy distributions

We describe a new instrument, the Argonne Auger-Meitner Radioisotope Microscope (ARM), capable of characterizing the Auger-Meitner electron emission of radionuclides, including candidates relevant in nuclear medicine. Our approach relies on event-by-event coincidence ion, electron time-of-flight and spatial readout measurement to determine correlated electron multiplicity and energy distributions of Auger-Meitner decays. We present a proof-of-principle measurement with the ARM using X-ray photoionization of stable krypton beyond the K-edge and identify a bifurcation in the electron multiplicity distribution depending on the emission of K-LX electrons. Extension of the ARM to the characterization of radioactive sources of Auger-Meitner electron emissions is enabled by the combination of two recent developments: (1) cryogenic buffer gas beam technology, which enables well-defined initial conditions, gas-phase, high activity introduction of Auger-Meitner emitters into the detection region, and (2) large-area micro-channel plate detectors with multi-hit detection capabilities, which enables the simultaneous detection of many electrons emitted in a single decay. The ARM will generate new experimental data on Auger-Meitner multiplicities that can be used to benchmark atomic relaxation and decay models. As the multiplicities are binned by energy, this data will provide insight into the low-energy regime of Auger-Meitner electrons where intensity calculations are most challenging and experimental data is limited. In particular, accurate multiplicity data of the low-energy regime can be used to inform oncological dosimetry models, where electron energies less than 500 eV are known to be effective in damaging DNA and cell membranes.