Selective-area atomic layer epitaxy growth of ZnO features on soft lithography-patterned substrates
- 5 September 2001
- journal article
- Published by AIP Publishing in Applied Physics Letters
- Vol. 79 (11) , 1709-1711
- https://doi.org/10.1063/1.1402959
Abstract
Templated ZnO thin-film growth from the vapor phase is achieved on docosyltrichloro- silane-patterned Si substrates using atomic layer epitaxy (ALE) combined with soft lithography. Patterned hydrophobic self-assembled monolayers (SAMs) are first transferred to single-crystal Si surfaces by hot microcontact printing. Using diethylzinc and water as ALE precursors, crystalline ZnO layers are then grown selectively on the SAM-free surface regions where native hydroxy groups nucleate growth from the vapor phase. High-resolution ZnO patterns with 1.0–40 μm feature sizes are readily achieved, demonstrating that soft lithography combined with ALE is a simple and promising methodology for selective area in situ vapor phase fabrication of patterned oxide thin films.Keywords
This publication has 20 references indexed in Scilit:
- New n-Type Transparent Conducting OxidesMRS Bulletin, 2000
- Atomic Layer Deposition of Oxide Thin Films with Metal Alkoxides as Oxygen SourcesScience, 2000
- Atomic layer-controlled growth of transparent conducting ZnO on plastic substratesMaterials Chemistry and Physics, 1999
- Atomic layer epitaxy - a valuable tool for nanotechnology?Nanotechnology, 1999
- Ultraviolet lasing in resonators formed by scattering in semiconductor polycrystalline filmsApplied Physics Letters, 1998
- Transparent and conductive Ga-doped ZnO films grown by low pressure metal organic chemical vapor depositionJournal of Vacuum Science & Technology A, 1997
- ALE-reactor for large area depositionsApplied Surface Science, 1997
- Atomic layer epitaxy growth of doped zinc oxide thin films from organometalsApplied Surface Science, 1994
- Large-Area ZnO Thin Films for Solar Cells Prepared by Photo-Induced Metalorganic Chemical Vapor DepositionJapanese Journal of Applied Physics, 1993
- Atomic layer epitaxyJournal of Applied Physics, 1986