Large area silicon microdosimeter for dosimetry in high LET space radiation fields: Charge collection study

Jayde Livingstone; Dale A. Prokopovich; Michael L.F. Lerch; Marco Petasecca; Mark I. Reinhard; Hiroshi Yasuda; Marco Zaider; James F. Ziegler; Vincent L. Pisacane; John F. Dicello; Vladimir L. Perevertaylo; Anatoly B. Rosenfeld

doi:10.1109/TNS.2012.2219069

Large area silicon microdosimeter for dosimetry in high LET space radiation fields: Charge collection study

Jayde Livingstone, Dale A. Prokopovich, Michael L.F. Lerch, Marco Petasecca, Mark I. Reinhard, Hiroshi Yasuda, Marco Zaider, James F. Ziegler, Vincent L. Pisacane, John F. Dicello, Vladimir L. Perevertaylo, Anatoly B. Rosenfeld

Research output: Contribution to journal › Article › peer-review

17 Scopus citations

Abstract

Silicon microdosimeters for the characterisation of mixed radiation fields relevant to the space radiation environment have been under continual development at the Centre for Medical Radiation Physics for over a decade. These devices are useful for the prediction of single event upsets in microelectronics and for radiation protection of spacecraft crew. The latest development in silicon microdosimetry is a family of large-area n-SOI microdosimeters for real-time dosimetry in space radiation environments. The response of n-SOI microdosimeters to 2 MeV H and 5.5 MeV He ions has been studied to investigate their charge collection characteristics. The studies have confirmed 100% yield of functioning cells, but have also revealed a charge sharing effect due to diffusion of charge from events occurring outside the sensitive volume and an enhanced energy response due to the collection of charge created beneath the insulating layer. The use of a veto electrode aims to reduce collection of diffused charge. The effectiveness of the veto electrode has been studied via a coincidence analysis using IBIC. It has been shown that suppression of the shared events allows results in a better defined sensitive volume corresponding to the region under the core electrode where the electric field is strongest.

Original language	English (US)
Article number	6329464
Pages (from-to)	3126-3132
Number of pages	7
Journal	IEEE Transactions on Nuclear Science
Volume	59
Issue number	6
DOIs	https://doi.org/10.1109/TNS.2012.2219069
State	Published - 2012
Externally published	Yes

Keywords

Heavy ion therapy
ion beams
microdosimetry
silicon-on-insulator (SOI)
space radiation

ASJC Scopus subject areas

Nuclear and High Energy Physics
Nuclear Energy and Engineering
Electrical and Electronic Engineering

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10.1109/TNS.2012.2219069

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Livingstone, J., Prokopovich, D. A., Lerch, M. L. F., Petasecca, M., Reinhard, M. I., Yasuda, H., Zaider, M., Ziegler, J. F., Pisacane, V. L., Dicello, J. F., Perevertaylo, V. L., & Rosenfeld, A. B. (2012). Large area silicon microdosimeter for dosimetry in high LET space radiation fields: Charge collection study. IEEE Transactions on Nuclear Science, 59(6), 3126-3132. Article 6329464. https://doi.org/10.1109/TNS.2012.2219069

Livingstone, J, Prokopovich, DA, Lerch, MLF, Petasecca, M, Reinhard, MI, Yasuda, H, Zaider, M, Ziegler, JF, Pisacane, VL, Dicello, JF, Perevertaylo, VL & Rosenfeld, AB 2012, 'Large area silicon microdosimeter for dosimetry in high LET space radiation fields: Charge collection study', IEEE Transactions on Nuclear Science, vol. 59, no. 6, 6329464, pp. 3126-3132. https://doi.org/10.1109/TNS.2012.2219069

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title = "Large area silicon microdosimeter for dosimetry in high LET space radiation fields: Charge collection study",

abstract = "Silicon microdosimeters for the characterisation of mixed radiation fields relevant to the space radiation environment have been under continual development at the Centre for Medical Radiation Physics for over a decade. These devices are useful for the prediction of single event upsets in microelectronics and for radiation protection of spacecraft crew. The latest development in silicon microdosimetry is a family of large-area n-SOI microdosimeters for real-time dosimetry in space radiation environments. The response of n-SOI microdosimeters to 2 MeV H and 5.5 MeV He ions has been studied to investigate their charge collection characteristics. The studies have confirmed 100% yield of functioning cells, but have also revealed a charge sharing effect due to diffusion of charge from events occurring outside the sensitive volume and an enhanced energy response due to the collection of charge created beneath the insulating layer. The use of a veto electrode aims to reduce collection of diffused charge. The effectiveness of the veto electrode has been studied via a coincidence analysis using IBIC. It has been shown that suppression of the shared events allows results in a better defined sensitive volume corresponding to the region under the core electrode where the electric field is strongest.",

keywords = "Heavy ion therapy, ion beams, microdosimetry, silicon-on-insulator (SOI), space radiation",

author = "Jayde Livingstone and Prokopovich, {Dale A.} and Lerch, {Michael L.F.} and Marco Petasecca and Reinhard, {Mark I.} and Hiroshi Yasuda and Marco Zaider and Ziegler, {James F.} and Pisacane, {Vincent L.} and Dicello, {John F.} and Perevertaylo, {Vladimir L.} and Rosenfeld, {Anatoly B.}",

note = "Funding Information: Manuscript received July 08, 2012; accepted September 11, 2012. Date of publication October 11, 2012; date of current version December 11, 2012. This work was supported by the Australian Research Council (DP1096600) and the National Space and Biomedical Research Institute. J. Livingstone would like to acknowledge the support of the Australian Institute of Nuclear Science and Engineering (AINSE).",

year = "2012",

doi = "10.1109/TNS.2012.2219069",

language = "English (US)",

volume = "59",

pages = "3126--3132",

journal = "IEEE Transactions on Nuclear Science",

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T1 - Large area silicon microdosimeter for dosimetry in high LET space radiation fields

T2 - Charge collection study

AU - Livingstone, Jayde

AU - Prokopovich, Dale A.

AU - Lerch, Michael L.F.

AU - Petasecca, Marco

AU - Reinhard, Mark I.

AU - Yasuda, Hiroshi

AU - Zaider, Marco

AU - Ziegler, James F.

AU - Pisacane, Vincent L.

AU - Dicello, John F.

AU - Perevertaylo, Vladimir L.

AU - Rosenfeld, Anatoly B.

N1 - Funding Information: Manuscript received July 08, 2012; accepted September 11, 2012. Date of publication October 11, 2012; date of current version December 11, 2012. This work was supported by the Australian Research Council (DP1096600) and the National Space and Biomedical Research Institute. J. Livingstone would like to acknowledge the support of the Australian Institute of Nuclear Science and Engineering (AINSE).

PY - 2012

Y1 - 2012

N2 - Silicon microdosimeters for the characterisation of mixed radiation fields relevant to the space radiation environment have been under continual development at the Centre for Medical Radiation Physics for over a decade. These devices are useful for the prediction of single event upsets in microelectronics and for radiation protection of spacecraft crew. The latest development in silicon microdosimetry is a family of large-area n-SOI microdosimeters for real-time dosimetry in space radiation environments. The response of n-SOI microdosimeters to 2 MeV H and 5.5 MeV He ions has been studied to investigate their charge collection characteristics. The studies have confirmed 100% yield of functioning cells, but have also revealed a charge sharing effect due to diffusion of charge from events occurring outside the sensitive volume and an enhanced energy response due to the collection of charge created beneath the insulating layer. The use of a veto electrode aims to reduce collection of diffused charge. The effectiveness of the veto electrode has been studied via a coincidence analysis using IBIC. It has been shown that suppression of the shared events allows results in a better defined sensitive volume corresponding to the region under the core electrode where the electric field is strongest.

AB - Silicon microdosimeters for the characterisation of mixed radiation fields relevant to the space radiation environment have been under continual development at the Centre for Medical Radiation Physics for over a decade. These devices are useful for the prediction of single event upsets in microelectronics and for radiation protection of spacecraft crew. The latest development in silicon microdosimetry is a family of large-area n-SOI microdosimeters for real-time dosimetry in space radiation environments. The response of n-SOI microdosimeters to 2 MeV H and 5.5 MeV He ions has been studied to investigate their charge collection characteristics. The studies have confirmed 100% yield of functioning cells, but have also revealed a charge sharing effect due to diffusion of charge from events occurring outside the sensitive volume and an enhanced energy response due to the collection of charge created beneath the insulating layer. The use of a veto electrode aims to reduce collection of diffused charge. The effectiveness of the veto electrode has been studied via a coincidence analysis using IBIC. It has been shown that suppression of the shared events allows results in a better defined sensitive volume corresponding to the region under the core electrode where the electric field is strongest.

KW - Heavy ion therapy

KW - ion beams

KW - microdosimetry

KW - silicon-on-insulator (SOI)

KW - space radiation

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Large area silicon microdosimeter for dosimetry in high LET space radiation fields: Charge collection study

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