Variation in the Bandgap of Amorphous Zinc Tin Oxide: Investigating the Thickness Dependence via In Situ STS

dc.contributor.author	Callaghan, Peter J.
dc.contributor.author	Caffrey, David
dc.contributor.author	Zhussupbekov, Kuanysh
dc.contributor.author	Berman, Samuel
dc.contributor.author	Zhussupbekova, Ainur
dc.contributor.author	Smith, Christopher M.
dc.contributor.author	Shvets, Igor V.
dc.date.accessioned	2024-09-18T04:55:46Z
dc.date.available	2024-09-18T04:55:46Z
dc.date.issued	2024
dc.identifier.issn	2470-1343
dc.identifier.other	doi.org/10.1021/acsomega.3c09958
dc.identifier.uri	http://rep.enu.kz/handle/enu/16552
dc.description.abstract	Amorphous transparent conducting oxides (aTCOs) have seen substantial interest in recent years due to the significant benefits that they can bring to transparent electronic devices. One such material of promise is amorphous ZnxSn1−xOy (a-ZTO). a-ZTO possesses many attractive properties for a TCO such as high transparency in the visible range, tunable charge carrier concentration, electron mobility, and only being composed of common and abundant elements. In this work, we employ a combination of UV−vis spectrophotometry, X-ray photoemission spectroscopy, and in situ scanning tunneling spectroscopy to investigate a 0.33 eV blue shift in the optical bandgap of a-ZTO, which we conclude to be due to quantum confinement effects.	ru
dc.language.iso	en	ru
dc.publisher	ACS Omega	ru
dc.relation.ispartofseries	Vol 9;Issue 6
dc.title	Variation in the Bandgap of Amorphous Zinc Tin Oxide: Investigating the Thickness Dependence via In Situ STS	ru
dc.type	Article	ru