Unexpected Coincidences in Scintillation Detector Measurements on Cosmic Rays

TL;DR

This study investigates rare coincidences of low-amplitude signals from cosmic rays detected by scintillation detectors, revealing unexpected effects that could influence measurements of muon properties in educational experiments.

Contribution

The paper demonstrates the occurrence of rare, unexpected coincidences in cosmic ray measurements using scintillation detectors, highlighting potential implications for muon lifetime and velocity studies.

Findings

Rare coincidences occur at rates over a thousand times lower than individual detector counts.

Low-amplitude signals correspond to energy absorptions around 100 keV.

Measurement of time differences can detect these rare effects effectively.

Abstract

We measured signals of low amplitudes originating from cosmic rays, using two rectangular-block scintillation detectors at various positions. The signals were analyzed by a slightly modified signal analyzer from project 'MuonLab', designed to measure the lifetime and velocity of muons from cosmic radiation in high school education. In our experiment we focused on the possibilities of the apparatus to measure the time difference 'deltatime (DT)' between signals in two scintillation detectors and the signal amplitude 'pulse height (PH)' of the signal in one detector. We performed measurements in two arrangements: first vertical, detectors parallel and above each other, second horizontal, detectors parallel and next to each other. We observed that in both the vertical and horizontal arrangements, low-amplitude signals from cosmic rays in the two detectors showed unexpected coincidences. Under normal experimental conditions these effects were not observed because the amplification in the photomultiplier (PMT) as well as the threshold voltage were intentionally chosen to avoid noise and excessively high count rates. The rate at which the coincidences occur is very small, more than a thousand times smaller than the count rates of the individual detectors. However, the measurement of the deltatime spectrum appears to be a sensitive way to detect the presence of these rare and unexpected effects. The time differences between the signals at the two analyzer inputs were measured with a resolution of 0.5 ns and the pulse height measurement had a resolution of approximately 8 mV. It is estimated that the low-amplitude signals involved in the coincidences must respond to energy absorptions of the order of 100 keV in the scintillator material.