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镀膜型nMCP探测效率和位置分辨优化的蒙特卡罗模拟研究

Monte Carlo Simulation Study on Optimization of Detection Efficiency and Spatial Resolution of Coated nMCP

  • 摘要: 中子敏感微通道板(Neutron sensitive microchannel plate,nMCP)因其具有高探测效率和位置分辨,配合先进的读出电子学可作为能量分辨中子成像探测器的优先选择。相比于基体掺杂型的nMCP,基于原子层沉积技术(Atomic Layer Deposition,ALD)的nMCP具有原材料消耗少、通道内壁具有高的二次电子发射系数等优势。首先,通过实验对掺杂natGd型nMCP的典型中子和伽马信号进行研究。然后,采用Geant4模拟和理论计算对镀膜10B2O3nMCP的孔径、壁厚、倾角和镀膜厚度进行优化。计算结果表明,当nMCP的几何参数选择为镀膜厚度1 μm、孔径10 μm、壁厚1 μm以及倾角3°时,nMCP性能达到约56%的热中子探测效率和约22 μm的位置分辨。计算结果对CSNS能量选择中子成像探测器nMCP的几何参数设计具有重要意义。

     

    Abstract: Since neutron sensitive microchannel plates (nMCP) has high detection efficiency and the spatial resolution, combined with advanced readout electronics it can be a better choice for energy-resolved neutron imaging detectors. Compared with the matrix-doped nMCP, the nMCP based on Atomic Layer Deposition(ALD) has the advantages of less neutron sensitive material consumption and high secondary electron emission coefficient on the inner wall of the channel. Firstly, the typical neutron and gamma signal of natGd-doped nMCP were studied experimentally. Geant4 simulation and theoretical calculation were performed to optimize the pore diameter, wall thickness, bias angle and coating thickness of the coated 10B2O3 nMCP. It was shown that the thermal neutron detection efficiency was about 56% and the spatial resolution was about 22 μm when the coating thickness was 1 μm, the pore diameter was 10 μm, the wall thickness was 1 μm and the bias angle was 3°. The results are of great significance to the geometric parameter design of nMCP used as energy-resolved neutron imaging detectors at CSNS.

     

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