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EUV-induced hydrogen desorption as a step towards large-scale silicon quantum device patterning

Procopios Constantinou, Taylor J. Z. Stock, Li‐Ting Tseng, Dimitrios Kazazis, Matthias Muntwiler, C. A. F. Vaz, Yasin Ekinci, Gabriel Aeppli, Neil J. Curson, Steven R. Schofield

2024Nature Communications27 citationsDOIOpen Access PDF

Abstract

Atomically precise hydrogen desorption lithography using scanning tunnelling microscopy (STM) has enabled the development of single-atom, quantum-electronic devices on a laboratory scale. Scaling up this technology to mass-produce these devices requires bridging the gap between the precision of STM and the processes used in next-generation semiconductor manufacturing. Here, we demonstrate the ability to remove hydrogen from a monohydride Si(001):H surface using extreme ultraviolet (EUV) light. We quantify the desorption characteristics using various techniques, including STM, X-ray photoelectron spectroscopy (XPS), and photoemission electron microscopy (XPEEM). Our results show that desorption is induced by secondary electrons from valence band excitations, consistent with an exactly solvable non-linear differential equation and compatible with the current 13.5 nm (~92 eV) EUV standard for photolithography; the data imply useful exposure times of order minutes for the 300 W sources characteristic of EUV infrastructure. This is an important step towards the EUV patterning of silicon surfaces without traditional resists, by offering the possibility for parallel processing in the fabrication of classical and quantum devices through deterministic doping.

Topics & Concepts

Extreme ultraviolet lithographyX-ray photoelectron spectroscopyExtreme ultravioletDesorptionMaterials scienceOptoelectronicsScanning tunneling microscopePhotoemission spectroscopySiliconSemiconductorLithographyResistQuantum efficiencyElectron-beam lithographyUltraviolet photoelectron spectroscopyNanotechnologyOpticsPhysicsChemistryLaserPhysical chemistryLayer (electronics)Nuclear magnetic resonanceAdsorptionSemiconductor materials and devicesSurface and Thin Film PhenomenaAdvanced Electron Microscopy Techniques and Applications
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