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Measurement of ultralow radiation-induced charge densities using picosecond laser induced breakdown
Author(s) -
Woodbury, Daniel,
Schwartz, Robert,
Milchberg, Howard
Publication year - 2019
Publication title -
figshare
Language(s) - English
Resource type - Reports
DOI - 10.6084/m9.figshare.c.4510967.v1
Subject(s) - ionization , picosecond , photomultiplier , laser , avalanche breakdown , materials science , atomic physics , electron avalanche , photon , electron , photoionization , optoelectronics , infrared , ion , photon counting , optics , laser induced breakdown spectroscopy , ionization chamber , electron density , above threshold ionization , atmospheric pressure laser ionization , impact ionization , chemistry , spectral line
We demonstrate that avalanche ionization breakdown of air with picosecond mid-infrared (mid-IR) laser pulses is an exceptionally sensitive and quantitative probe of extremely low concentrations of charged species. By exponentially increasing the electron density in the vicinity of a single seed atom or molecule to detectable levels, mid-IR electron avalanche is an analogue of single photon detection in photomultiplier tubes and can be useful in a range of applications. We apply the technique to meter-scale standoff detection of a radioactive source, sensitive to extremely low concentrations of radiation-induced negative ions down to ∼103  cm−3, limited only by background. By imaging the location of spatially isolated avalanche breakdown sites, we directly measure these low densities and benchmark the performance of standoff detection diagnostics. We discuss implementation of this radiation detection scheme at ranges of 10–100 m and adapting the avalanche probe to detection of other low-density plasmas.

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