Home > Research > Publications & Outputs > Radiation Imaging with Fast Organic Liquid Scin...

Research

Associated organisational units

Electronic data

  • abstract_NUPP_2017_KG

    Other version, 17.1 KB, Word document

  • NUPP_conference_KG

    Other version, 115 KB, PDF document

View graph of relations

Radiation Imaging with Fast Organic Liquid Scintillator Detectors

Research output: Contribution to conference - Without ISBN/ISSN Speech

Published

Standard

Radiation Imaging with Fast Organic Liquid Scintillator Detectors. / Akurugoda Gamage, Kelum Asanga.
2017. International Conference on Nuclear Power Plants: Structures, Risk and Decommissioning (NUPP 2017), London, United Kingdom.

Research output: Contribution to conference - Without ISBN/ISSN Speech

Harvard

Akurugoda Gamage, KA 2017, 'Radiation Imaging with Fast Organic Liquid Scintillator Detectors', International Conference on Nuclear Power Plants: Structures, Risk and Decommissioning (NUPP 2017), London, United Kingdom, 6/02/17 - 8/02/17.

APA

Akurugoda Gamage, K. A. (2017). Radiation Imaging with Fast Organic Liquid Scintillator Detectors. International Conference on Nuclear Power Plants: Structures, Risk and Decommissioning (NUPP 2017), London, United Kingdom.

Vancouver

Akurugoda Gamage KA. Radiation Imaging with Fast Organic Liquid Scintillator Detectors. 2017. International Conference on Nuclear Power Plants: Structures, Risk and Decommissioning (NUPP 2017), London, United Kingdom.

Author

Akurugoda Gamage, Kelum Asanga. / Radiation Imaging with Fast Organic Liquid Scintillator Detectors. International Conference on Nuclear Power Plants: Structures, Risk and Decommissioning (NUPP 2017), London, United Kingdom.

Bibtex

@conference{5be8f33867e74335a62891d781864350,
title = "Radiation Imaging with Fast Organic Liquid Scintillator Detectors",
abstract = "Development of technologies for the rapid, in-situ characterisation of contaminated facilities (where man-entry is not possible) is a key requirement to speed up nuclear decommissioning. Similarly prevention of nuclear terrorism is dependent upon the accuracy and strength of the radiation monitoring systems. Organic liquid scintillator detectors are becoming popular in radiation detection applications including nuclear decommissioning, nuclear safety and security as a result of recent advances in digital pulse-shape discrimination methods. They generally sensitive to both neutrons and gamma rays, where pulse shape discrimination can be used to discriminate between neutrons and gamma rays. In this work, experimentally collected events are discriminated between neutrons and gamma-rays using pulse shape discrimination, and images produce for each measurement in terms of the angular distribution (i.e. intensity of the radiation type) of events for total counts, gamma rays and neutrons. Based on these images, it can be easily identified the actual location of the source. ",
author = "{Akurugoda Gamage}, {Kelum Asanga}",
year = "2017",
month = feb,
day = "6",
language = "English",
note = "International Conference on Nuclear Power Plants: Structures, Risk and Decommissioning (NUPP 2017) ; Conference date: 06-02-2017 Through 08-02-2017",

}

RIS

TY - CONF

T1 - Radiation Imaging with Fast Organic Liquid Scintillator Detectors

AU - Akurugoda Gamage, Kelum Asanga

PY - 2017/2/6

Y1 - 2017/2/6

N2 - Development of technologies for the rapid, in-situ characterisation of contaminated facilities (where man-entry is not possible) is a key requirement to speed up nuclear decommissioning. Similarly prevention of nuclear terrorism is dependent upon the accuracy and strength of the radiation monitoring systems. Organic liquid scintillator detectors are becoming popular in radiation detection applications including nuclear decommissioning, nuclear safety and security as a result of recent advances in digital pulse-shape discrimination methods. They generally sensitive to both neutrons and gamma rays, where pulse shape discrimination can be used to discriminate between neutrons and gamma rays. In this work, experimentally collected events are discriminated between neutrons and gamma-rays using pulse shape discrimination, and images produce for each measurement in terms of the angular distribution (i.e. intensity of the radiation type) of events for total counts, gamma rays and neutrons. Based on these images, it can be easily identified the actual location of the source.

AB - Development of technologies for the rapid, in-situ characterisation of contaminated facilities (where man-entry is not possible) is a key requirement to speed up nuclear decommissioning. Similarly prevention of nuclear terrorism is dependent upon the accuracy and strength of the radiation monitoring systems. Organic liquid scintillator detectors are becoming popular in radiation detection applications including nuclear decommissioning, nuclear safety and security as a result of recent advances in digital pulse-shape discrimination methods. They generally sensitive to both neutrons and gamma rays, where pulse shape discrimination can be used to discriminate between neutrons and gamma rays. In this work, experimentally collected events are discriminated between neutrons and gamma-rays using pulse shape discrimination, and images produce for each measurement in terms of the angular distribution (i.e. intensity of the radiation type) of events for total counts, gamma rays and neutrons. Based on these images, it can be easily identified the actual location of the source.

M3 - Speech

T2 - International Conference on Nuclear Power Plants: Structures, Risk and Decommissioning (NUPP 2017)

Y2 - 6 February 2017 through 8 February 2017

ER -