The Impact of Crystal Light Yield Non-Proportionality on a Typical Calorimetric Space Experiment: Beam Test Measurements and Monte Carlo Simulations

Q3 Physics and Astronomy

Instruments Pub Date : 2022-09-27 DOI:10.3390/instruments6040053

L. Pacini, O. Adriani, E. Berti, P. Betti, G. Bigongiari, L. Bonechi, M. Bongi, S. Bottai, P. Brogi, G. Castellini, C. Checchia, R. D’Alessandro, S. Detti, N. Finetti, P. Maestro, P. Marrocchesi, N. Mori, M. Olmi, P. Papini, C. Poggiali, S. Ricciarini, P. Spillantini, O. Starodubtsev, F. Stolzi, A. Tiberio, E. Vannuccini

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引用次数: 0

Abstract

Calorimetric space experiments were employed for the direct measurements of cosmic-ray spectra above the TeV region. According to several theoretical models and recent measurements, relevant features in both electron and nucleus fluxes are expected. Unfortunately, sizable disagreements among the current results of different space calorimeters exist. In order to improve the accuracy of future experiments, it is fundamental to understand the reasons of these discrepancies, especially since they are not compatible with the quoted experimental errors. A few articles of different collaborations suggest that a systematic error of a few percentage points related to the energy-scale calibration could explain these differences. In this work, we analyze the impact of the nonproportionality of the light yield of scintillating crystals on the energy scale of typical calorimeters. Space calorimeters are usually calibrated by employing minimal ionizing particles (MIPs), e.g., nonshowering proton or helium nuclei, which feature different ionization density distributions with respect to particles included in showers. By using the experimental data obtained by the CaloCube collaboration and a minimalist model of the light yield as a function of the ionization density, several scintillating crystals (BGO, CsI(Tl), LYSO, YAP, YAG and BaF2) are characterized. Then, the response of a few crystals is implemented inside the Monte Carlo simulation of a space calorimeter to check the energy deposited by electromagnetic and hadronic showers. The results of this work show that the energy scale obtained by MIP calibration could be affected by sizable systematic errors if the nonproportionality of scintillation light is not properly taken into account.

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晶体光产率非比例性对典型量热空间实验的影响:光束测试测量和蒙特卡罗模拟

利用空间量热实验直接测量了TeV以上区域的宇宙射线能谱。根据几个理论模型和最近的测量，电子和原子核的通量都有相关的特征。不幸的是，目前不同空间量热计的结果存在相当大的分歧。为了提高未来实验的准确性，了解这些差异的原因是至关重要的，特别是因为它们与引用的实验误差不相容。不同合作的几篇文章表明，与能量刻度校准有关的几个百分点的系统误差可以解释这些差异。在这项工作中，我们分析了闪烁晶体产光率的非比例性对典型量热计能量尺度的影响。空间量热计通常通过使用最小电离粒子(MIPs)来校准，例如，非淋浴质子或氦核，它们与淋浴中包含的粒子具有不同的电离密度分布。利用caloccube合作获得的实验数据和光产率随电离密度函数的极简模型，对几种闪烁晶体(BGO, CsI(Tl)， LYSO, YAP, YAG和BaF2)进行了表征。然后，在空间量热计的蒙特卡罗模拟中实现了一些晶体的响应，以检查电磁和强子阵雨沉积的能量。研究结果表明，如果不充分考虑闪烁光的非比例性，MIP标定得到的能量标度会受到较大的系统误差的影响。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Instruments Physics and Astronomy-Instrumentation

CiteScore

2.60

自引率

0.00%

发文量

审稿时长

11 weeks