Fabrication techniques for an arrayed EIS biosensor

Electrolyte-Insulator-Semiconductor (EIS) based biosensors are generally exposed to liquid media that contain biological or chemical entities of specific interest. Such sensors measure change in electrical parameters such as capacitance when charged species attach to the insulator layer. It is commo...

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Main Authors:	Meng Taing, Denis Sweatman
Format:	Conference Proceeding
Published:	2018
Subjects:	Engineering Materials Science Physics and Astronomy
Online Access:	https://www.scopus.com/inward/record.uri?partnerID=HzOxMe3b&scp=77950957378&origin=inward http://cmuir.cmu.ac.th/jspui/handle/6653943832/59562
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Institution:	Chiang Mai University

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spelling	th-cmuir.6653943832-595622018-09-10T03:24:16Z Fabrication techniques for an arrayed EIS biosensor Meng Taing Denis Sweatman Engineering Materials Science Physics and Astronomy Electrolyte-Insulator-Semiconductor (EIS) based biosensors are generally exposed to liquid media that contain biological or chemical entities of specific interest. Such sensors measure change in electrical parameters such as capacitance when charged species attach to the insulator layer. It is common for fluidic media to be contained to protect critical transducer components from liquid contact. Often the sensing region of the transducer is the only region in contact with liquid. This sensing region can be defined by a window in a passivation layer. Well established MEMS processes allow passivation using common spin-on based polymers. This sensing area can be defined by standard exposure, curing and developing techniques which are cost effective. This research focuses on fabrication of a multiarray EIS biosensor device to ensure critical sections of the transducer are protected from contact with liquid and to allow definable sensing regions using standard spin-on polymers. The sensor arrays were created by dicing the silicon-bulk into individual finger-like structures which serve as individual sensors. Bulk-silicon was anodically bonded to a glass support substrate to provide stability and serve as a platform for the sensors. Dicing allowed rapid separation of silicon-bulk compared to chemical or high energy milling techniques. A silicon oxide layer was grown on the silicon bulk to form the sensing layer. Charge based species in the liquid induce an electric field through the oxide. The depletion/space charge region below the oxide is modulated by the electric field which can be measured by capacitance. Specific layers can be attached to the oxide surface to create a sensor which responds to particular charged species. ©2009 IEEE. 2018-09-10T03:17:12Z 2018-09-10T03:17:12Z 2009-12-01 Conference Proceeding 2-s2.0-77950957378 10.1109/EPTC.2009.5416557 https://www.scopus.com/inward/record.uri?partnerID=HzOxMe3b&scp=77950957378&origin=inward http://cmuir.cmu.ac.th/jspui/handle/6653943832/59562
institution	Chiang Mai University
building	Chiang Mai University Library
country	Thailand
collection	CMU Intellectual Repository
topic	Engineering Materials Science Physics and Astronomy
spellingShingle	Engineering Materials Science Physics and Astronomy Meng Taing Denis Sweatman Fabrication techniques for an arrayed EIS biosensor
description	Electrolyte-Insulator-Semiconductor (EIS) based biosensors are generally exposed to liquid media that contain biological or chemical entities of specific interest. Such sensors measure change in electrical parameters such as capacitance when charged species attach to the insulator layer. It is common for fluidic media to be contained to protect critical transducer components from liquid contact. Often the sensing region of the transducer is the only region in contact with liquid. This sensing region can be defined by a window in a passivation layer. Well established MEMS processes allow passivation using common spin-on based polymers. This sensing area can be defined by standard exposure, curing and developing techniques which are cost effective. This research focuses on fabrication of a multiarray EIS biosensor device to ensure critical sections of the transducer are protected from contact with liquid and to allow definable sensing regions using standard spin-on polymers. The sensor arrays were created by dicing the silicon-bulk into individual finger-like structures which serve as individual sensors. Bulk-silicon was anodically bonded to a glass support substrate to provide stability and serve as a platform for the sensors. Dicing allowed rapid separation of silicon-bulk compared to chemical or high energy milling techniques. A silicon oxide layer was grown on the silicon bulk to form the sensing layer. Charge based species in the liquid induce an electric field through the oxide. The depletion/space charge region below the oxide is modulated by the electric field which can be measured by capacitance. Specific layers can be attached to the oxide surface to create a sensor which responds to particular charged species. ©2009 IEEE.
format	Conference Proceeding
author	Meng Taing Denis Sweatman
author_facet	Meng Taing Denis Sweatman
author_sort	Meng Taing
title	Fabrication techniques for an arrayed EIS biosensor
title_short	Fabrication techniques for an arrayed EIS biosensor
title_full	Fabrication techniques for an arrayed EIS biosensor
title_fullStr	Fabrication techniques for an arrayed EIS biosensor
title_full_unstemmed	Fabrication techniques for an arrayed EIS biosensor
title_sort	fabrication techniques for an arrayed eis biosensor
publishDate	2018
url	https://www.scopus.com/inward/record.uri?partnerID=HzOxMe3b&scp=77950957378&origin=inward http://cmuir.cmu.ac.th/jspui/handle/6653943832/59562
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Fabrication techniques for an arrayed EIS biosensor

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