# TCAD Simulation Study of Electrical Performance of a Novel High-Purity Germanium Drift Detector

**Authors:** Mingyang Wang, Zheng Li, Bo Xiong, Yongguang Xiao

PMC · DOI: 10.3390/mi16020229 · 2025-02-17

## TL;DR

A new high-purity germanium detector design reduces capacitance while maintaining a large detection area, improving performance for radiation detection.

## Contribution

Proposes a novel HPGe drift detector design with concentric anode rings and resistive chains to minimize capacitance.

## Key findings

- The detector design achieves smooth electric potential distribution and lateral hole drift toward the central cathode.
- Simulations show fast signal response and short carrier collection time under heavy ion incidence.
- The design balances small capacitance with a large active area, improving detector performance.

## Abstract

High-purity germanium (HPGe) detectors occupy a prominent position in fields such as radiation detection and aerospace because of their excellent energy resolution and wide detection range. To achieve a broader detection range, conventional HPGe detectors often need to be expanded to cubic-centimeter-scale volumes. However, this increase in volume leads to a large detector area, which in turn increases the detector capacitance, affecting the detector’s noise level and performance. To address this issue, this study proposes a novel high-purity germanium drift detector (HPGeDD). The design features a small-area central collecting cathode surrounded by concentric anode rings, with a resistive chain interposed between the anode rings to achieve self-dividing voltage. This design ensures that the detector’s capacitance is only related to the area of the central collecting cathode, independent of the overall active area, thus achieving a balance between a small capacitance and large active area. Electrical performance simulations of the novel detector were conducted using the semiconductor simulation software Sentaurus TCAD (P-2019.03). The results show a smooth electric potential distribution within the detector, forming a lateral electric field, as well as a lateral hole drift channel precisely directed toward the collecting cathode. Furthermore, simulations of heavy ion incidence were performed to investigate the detector’s carrier collection characteristics. The simulation results demonstrate that the HPGeDD exhibits advantages such as fast signal response and short collection time. The design proposal presented in this study offers a new solution to the problem of excessive capacitance in conventional HPGe detectors, expands their application scope, and provides theoretical guidance for subsequent improvements, optimizations, and practical manufacturing.

## Figures

8 figures with captions in the complete paper: https://tomesphere.com/paper/PMC11857351/full.md

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Source: https://tomesphere.com/paper/PMC11857351