Nanowell Field-Effect Transistors for Highly Sensitive Molecular Detection

Liu, Lijun; Santermans, Sybren; Barge, David; Delport, Jaco; Ray Chaudhuri, Ashesh; Willems, Kherim; Ha, Seungkyu; Severi, Simone; Van Dorpe, Pol; Martens, Koen

doi:10.1109/iedm45741.2023.10413703

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dc.contributor.author	Liu, Lijun
dc.contributor.author	Santermans, Sybren
dc.contributor.author	Barge, David
dc.contributor.author	Delport, Jaco
dc.contributor.author	Ray Chaudhuri, Ashesh
dc.contributor.author	Willems, Kherim
dc.contributor.author	Ha, Seungkyu
dc.contributor.author	Severi, Simone
dc.contributor.author	Van Dorpe, Pol
dc.contributor.author	Martens, Koen
dc.date.accessioned	2026-04-21T09:33:08Z
dc.date.available	2026-04-21T09:33:08Z
dc.date.createdwos	2026-03-24
dc.date.issued	2023
dc.description.abstract	We report a novel, highly sensitive bio-molecular sensor device, a nanowell FET. Its unique structure contains a 25 nm size nanowell in the center of a 35-40 nm wide silicon FinFET. Two extremely narrow, 3-4 nm wide silicon channels are formed on each side of the nanowell. These channels act as enhanced molecular sensing areas. The electrolytically gated nanowell FET exhibits a near-ideal subthreshold swing (SS) of 66 mV/dec, an on-state current of >1.8 mA/μm, peak transconductance of >3.8 mS/μm and hysteresis free characteristics. The nanowell is chemically modified to allow for the binding of target biomolecules. The binding leads to a shift of the FET threshold voltage (Vth), i.e. the signal. Through both end-point and real-time measurements, we obtain a signal of ~40 mV for an estimated number of approximately ten 20-base single-stranded DNA molecules (20T ssDNA). This is a major enhancement compared to our previously demonstrated finFET-based biosensor (~20 mV for ~40 molecules). The nanowell acts as a nanoscale region with an enhanced sensitivity towards molecular charges. Moreover, binding inside the nanowell potentially becomes self-limiting at single-molecule level. These features are major advantages for single molecule sensing.
dc.description.wosFundingText	We thank O. Richard and the imec TEM team, L. Liu acknowledges financial support from the FWO-Flanders (Fonds Wetenschappelijk Onderzoek - Vlaanderen)
dc.identifier.doi	10.1109/iedm45741.2023.10413703
dc.identifier.issn	2380-9248
dc.identifier.uri	https://imec-publications.be/handle/20.500.12860/59141
dc.language.iso	eng
dc.provenance.editstepuser	greet.vanhoof@imec.be
dc.publisher	IEEE
dc.source.conference	International Electron Devices Meeting (IEDM)
dc.source.conferencedate	2023-12-09
dc.source.conferencelocation	San Francisco
dc.source.journal	2023 INTERNATIONAL ELECTRON DEVICES MEETING, IEDM
dc.source.numberofpages	4
dc.title	Nanowell Field-Effect Transistors for Highly Sensitive Molecular Detection
dc.type	Proceedings paper
dspace.entity.type	Publication
imec.internal.crawledAt	2026-04-07
imec.internal.source	crawler
imec.internal.wosCreatedAt	2026-04-07
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Nanowell Field-Effect Transistors for Highly Sensitive Molecular Detection

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