Simulation of the Electrostatic Distribution in the Proximity Focusing Structure of an EBCMOS

Simulation of the Electrostatic Distribution in the Proximity Focusing Structure of an EBCMOS

The electrostatic distribution of an electron bombarded CMOS (EBCMOS) was simulated by Ansoft Maxwell 3D software. Specifically, we studied how the electrostatic distribution was affected by the structure of a back-side bombarded CMOS (BSB-CMOS) and the anode position in electron-bombarded sensors....

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Main Authors: Wei Wang, Ye Li, Weijun Chen, De Song, Xin Wang
Format: Article
Language:English
Published: IEEE 2020-01-01
Series:IEEE Photonics Journal
Subjects:
Electron bombarded CMOS
proximity focusing structure
simulation of electrostatic distribution
Online Access:https://ieeexplore.ieee.org/document/9072589/
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spelling doaj-4448da8322184d7489da223cf2aa903a2021-03-29T18:01:29ZengIEEEIEEE Photonics Journal1943-06552020-01-0112311010.1109/JPHOT.2020.29890959072589Simulation of the Electrostatic Distribution in the Proximity Focusing Structure of an EBCMOSWei Wang0https://orcid.org/0000-0002-0230-2542Ye Li1https://orcid.org/0000-0002-1978-7670Weijun Chen2De Song3https://orcid.org/0000-0003-1646-9092Xin Wang4School of Science, Changchun University of Science and Technology, Changchun, Jilin Province, ChinaSchool of Science, Changchun University of Science and Technology, Changchun, Jilin Province, ChinaSchool of Science, Changchun University of Science and Technology, Changchun, Jilin Province, ChinaSchool of Science, Changchun University of Science and Technology, Changchun, Jilin Province, ChinaSchool of Science, Changchun University of Science and Technology, Changchun, Jilin Province, ChinaThe electrostatic distribution of an electron bombarded CMOS (EBCMOS) was simulated by Ansoft Maxwell 3D software. Specifically, we studied how the electrostatic distribution was affected by the structure of a back-side bombarded CMOS (BSB-CMOS) and the anode position in electron-bombarded sensors. The simulation results reveal that the electrostatic field may cause a fault in the signal readout of the BSB-CMOS when the anode is positioned under the BSB-CMOS. In contrast, we found that the structure of an EBCMOS will aid electron focusing when the anode is positioned above the BSB-CMOS and the doping concentration of the electron multiplier layer is high. However, the high doping concentration of the electron multiplier layer will reduce the electron collection efficiency due to its rapid electron-hole recombination. We then designed a structure in which the multiplier layer has an overlying ultra-thin highly-doped layer, with an electrostatic distribution that functions to focus electrons. At the same time, this configuration can effectively prevent most of the multiplier electrons from recombining because ultra-thin highly-doped layer is much thinner than incident depth for the high-energy electron. This simulation study will provide a theoretical foundation for the fabrication of high-performance EBCMOS devices. Graphic abstract: a) EBCMOS physical model in Ansoft Maxwell 3D; b) The distribution of electrostatic distribution for BSB-CMOS with an ultra-thin heavily-doped layer. Electrostatic distribution of EBCMOS with different configurations were simulated. The results reveal that the electrostatic field may cause an erroneous readout of the BSB-CMOS if the anode is positioned under the BSB-CMOS. If the high voltage anode is positioned above the CMOS sensor, this is improved, especially when an ultrathin highly-doped multiplier layer is added to improve electron collection efficiency. This study provides a theoretical foundation for the fabrication of high performance EBCMOS devices.https://ieeexplore.ieee.org/document/9072589/Electron bombarded CMOSproximity focusing structuresimulation of electrostatic distribution
collection DOAJ
language English
format Article
sources DOAJ
author Wei Wang
Ye Li
Weijun Chen
De Song
Xin Wang
spellingShingle Wei Wang
Ye Li
Weijun Chen
De Song
Xin Wang
Simulation of the Electrostatic Distribution in the Proximity Focusing Structure of an EBCMOS
IEEE Photonics Journal
Electron bombarded CMOS
proximity focusing structure
simulation of electrostatic distribution
author_facet Wei Wang
Ye Li
Weijun Chen
De Song
Xin Wang
author_sort Wei Wang
title Simulation of the Electrostatic Distribution in the Proximity Focusing Structure of an EBCMOS
title_short Simulation of the Electrostatic Distribution in the Proximity Focusing Structure of an EBCMOS
title_full Simulation of the Electrostatic Distribution in the Proximity Focusing Structure of an EBCMOS
title_fullStr Simulation of the Electrostatic Distribution in the Proximity Focusing Structure of an EBCMOS
title_full_unstemmed Simulation of the Electrostatic Distribution in the Proximity Focusing Structure of an EBCMOS
title_sort simulation of the electrostatic distribution in the proximity focusing structure of an ebcmos
publisher IEEE
series IEEE Photonics Journal
issn 1943-0655
publishDate 2020-01-01
description The electrostatic distribution of an electron bombarded CMOS (EBCMOS) was simulated by Ansoft Maxwell 3D software. Specifically, we studied how the electrostatic distribution was affected by the structure of a back-side bombarded CMOS (BSB-CMOS) and the anode position in electron-bombarded sensors. The simulation results reveal that the electrostatic field may cause a fault in the signal readout of the BSB-CMOS when the anode is positioned under the BSB-CMOS. In contrast, we found that the structure of an EBCMOS will aid electron focusing when the anode is positioned above the BSB-CMOS and the doping concentration of the electron multiplier layer is high. However, the high doping concentration of the electron multiplier layer will reduce the electron collection efficiency due to its rapid electron-hole recombination. We then designed a structure in which the multiplier layer has an overlying ultra-thin highly-doped layer, with an electrostatic distribution that functions to focus electrons. At the same time, this configuration can effectively prevent most of the multiplier electrons from recombining because ultra-thin highly-doped layer is much thinner than incident depth for the high-energy electron. This simulation study will provide a theoretical foundation for the fabrication of high-performance EBCMOS devices. Graphic abstract: a) EBCMOS physical model in Ansoft Maxwell 3D; b) The distribution of electrostatic distribution for BSB-CMOS with an ultra-thin heavily-doped layer. Electrostatic distribution of EBCMOS with different configurations were simulated. The results reveal that the electrostatic field may cause an erroneous readout of the BSB-CMOS if the anode is positioned under the BSB-CMOS. If the high voltage anode is positioned above the CMOS sensor, this is improved, especially when an ultrathin highly-doped multiplier layer is added to improve electron collection efficiency. This study provides a theoretical foundation for the fabrication of high performance EBCMOS devices.
topic Electron bombarded CMOS
proximity focusing structure
simulation of electrostatic distribution
url https://ieeexplore.ieee.org/document/9072589/
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AT weijunchen simulationoftheelectrostaticdistributionintheproximityfocusingstructureofanebcmos
AT desong simulationoftheelectrostaticdistributionintheproximityfocusingstructureofanebcmos
AT xinwang simulationoftheelectrostaticdistributionintheproximityfocusingstructureofanebcmos
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