國立虎尾科技大學 |

Development of Novel Anodized Thin-Film Radiation Sensors.

紀錄類型:	書目-語言資料,印刷品 : Monograph/item
正題名/作者:	Development of Novel Anodized Thin-Film Radiation Sensors./
作者:	Gagne, Matthew.
出版者:	Ann Arbor : ProQuest Dissertations & Theses, : 2024,
面頁冊數:	69 p.
附註:	Source: Dissertations Abstracts International, Volume: 85-08, Section: B.
Contained By:	Dissertations Abstracts International85-08B.
標題:	Medical imaging. -
電子資源:	http://pqdd.sinica.edu.tw/twdaoapp/servlet/advanced?query=30695468
ISBN:	9798381447163

Development of Novel Anodized Thin-Film Radiation Sensors.
Gagne, Matthew.

Development of Novel Anodized Thin-Film Radiation Sensors. - Ann Arbor : ProQuest Dissertations & Theses, 2024 - 69 p.

Source: Dissertations Abstracts International, Volume: 85-08, Section: B.

Thesis (Ph.D.)--University of Massachusetts Lowell, 2024.

This item must not be sold to any third party vendors.

Classical radiation detection technology relies on the interaction of radiation within the bulky volume of their sensors. Historically, increasing the sensitivity of a radiation detector required using costly materials, increasing the interaction volume, or including complex and fragile amplification technology. These limitations have meant that only incremental changes and improvements in radiation detection systems have been possible. As radiation use in industry, military applications, and medicine continue to increase, the need for a cost effective, light weight, and resilient radiation detectors is at an all-time high. High Energy Current (HEC) technology relies on surface level radiation interaction with thin and inexpensive materials to produce sensitive radiation sensors. Detection systems using macroscopic fabrication techniques to produce HEC technology have shown the potential for this technology in numerous applications.In order to capitalize on the great advantages of HEC technology over historically available radiation sensors, the technology needs to be miniaturized. This work details the development, fabrication, and testing of a novel thin-film flexible and resilient radiation detector based on HEC principals. Dubbed the Anodox sensor, these prototypes are produced using a novel anodization technique using affordable of the shelf materials. They are capable of reliable radiation detection using commercial electronic reading equipment and can operate in a self-powered or minimal voltage-bias mode. These physically resilient detectors are able to accomplish these goals while having a total thickness of approximately 50 μm. In this work, Anodox sensors are also tested for their response to electronically produced kVp x-rays. They are first characterized for their response to x-rays from an industrial x-ray tube. Following characterization, they are tested for their response in two modern medical imaging modalities. Fluoroscopy and computer tomography (CT) are two imaging modalities that play an increasingly important role in modern healthcare while also imparting significant radiation dose to patients and clinicians. These proof-of-concept tests show the viability of HEC sensors as an effective dose monitoring tool in modalities where accurate dose measurement is not currently possible. This research highlights the benefits of HEC technology in radiation detection and medicine and shows the need for the further development of this novel technology.Portions of this work were supported by USAF SBIR contract FA8051-17-C-0003.

ISBN: 9798381447163Subjects--Topical Terms:

1180167
Medical imaging.
Subjects--Index Terms:

Anodization technique

Development of Novel Anodized Thin-Film Radiation Sensors.
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520 $a Classical radiation detection technology relies on the interaction of radiation within the bulky volume of their sensors. Historically, increasing the sensitivity of a radiation detector required using costly materials, increasing the interaction volume, or including complex and fragile amplification technology. These limitations have meant that only incremental changes and improvements in radiation detection systems have been possible. As radiation use in industry, military applications, and medicine continue to increase, the need for a cost effective, light weight, and resilient radiation detectors is at an all-time high. High Energy Current (HEC) technology relies on surface level radiation interaction with thin and inexpensive materials to produce sensitive radiation sensors. Detection systems using macroscopic fabrication techniques to produce HEC technology have shown the potential for this technology in numerous applications.In order to capitalize on the great advantages of HEC technology over historically available radiation sensors, the technology needs to be miniaturized. This work details the development, fabrication, and testing of a novel thin-film flexible and resilient radiation detector based on HEC principals. Dubbed the Anodox sensor, these prototypes are produced using a novel anodization technique using affordable of the shelf materials. They are capable of reliable radiation detection using commercial electronic reading equipment and can operate in a self-powered or minimal voltage-bias mode. These physically resilient detectors are able to accomplish these goals while having a total thickness of approximately 50 μm. In this work, Anodox sensors are also tested for their response to electronically produced kVp x-rays. They are first characterized for their response to x-rays from an industrial x-ray tube. Following characterization, they are tested for their response in two modern medical imaging modalities. Fluoroscopy and computer tomography (CT) are two imaging modalities that play an increasingly important role in modern healthcare while also imparting significant radiation dose to patients and clinicians. These proof-of-concept tests show the viability of HEC sensors as an effective dose monitoring tool in modalities where accurate dose measurement is not currently possible. This research highlights the benefits of HEC technology in radiation detection and medicine and shows the need for the further development of this novel technology.Portions of this work were supported by USAF SBIR contract FA8051-17-C-0003.
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