Simultaneous measurement of organic scintillator response to carbon and proton recoils

TL;DR

This paper introduces a novel method for simultaneously measuring proton and carbon light yields in organic scintillators, providing new data crucial for understanding their response to neutron interactions.

Contribution

It presents a new approach using extended double time-of-flight to measure both proton and carbon light yields simultaneously, along with new experimental data for EJ-309 and EJ-204 scintillators.

Findings

Measured proton and carbon light yield relations over specified energy ranges.

Provided new data on ionization quenching effects in organic scintillators.

Enhanced understanding of scintillator response for neutron detection applications.

Abstract

Background: Organic scintillators are widely used for neutron detection in both basic nuclear physics and applications. While the proton light yield of organic scintillators has been extensively studied, measurements of the light yield from neutron interactions with carbon nuclei are scarce. Purpose: Demonstrate a new approach for the simultaneous measurement of the proton and carbon light yield of organic scintillators. Provide new carbon light yield data for the EJ-309 liquid and EJ-204 plastic organic scintillators. Method: A 33~MeV $^{2}$H$^{+}$ beam from the 88-Inch Cyclotron at Lawrence Berkeley National Laboratory was impinged upon a 3-mm-thick Be target to produce a high-flux, broad-spectrum neutron beam. The double time-of-flight technique was extended to simultaneously measure the proton and carbon light yield of the organic scintillators, wherein the light output associated with the recoil particle was determined using $np$ and $n$C elastic scattering kinematics. Results: The proton and carbon light yield relations of the EJ-309 liquid and EJ-204 plastic organic scintillators were measured over a recoil energy range of approximately 0.3 to 1~MeV and 2 to 5~MeV, respectively for EJ-309, and 0.2 to 0.5~MeV and 1 to 4~MeV, respectively for EJ-204. Conclusions: These data provide new insight into the ionization quenching effect in organic scintillators and key input for simulation of the response of organic scintillators for both basic science and a broad range of applications.