Atomic-scale Control of Tunnel Coupling
Xiqiao Wang, Jonathan Wyrick, Ranjit V. Kashid, Pradeep Namboodiri,, Scott W. Schmucker, Andrew Murphy, M. D. Stewart, Jr., Neil Zimmerman, and, Richard M. Silver

TL;DR
This paper demonstrates atomic-scale control of tunnel coupling in single-electron transistors on silicon surfaces, enabling precise engineering for quantum computing applications.
Contribution
It introduces a method for atomically precise fabrication of tunnel junctions with exponential resistance scaling, advancing quantum device design.
Findings
Exponential scaling of tunneling resistance with atomic precision.
Intrinsic limit of hydrogen lithography on Si (100) surfaces.
Fourfold resistance difference due to atomic-scale variation.
Abstract
Atomically precise donor-based quantum devices are a promising candidate for scalable solid-state quantum computing. Atomically precise design and implementation of the tunnel coupling in these devices is essential to realize gate-tunable exchange coupling, and electron spin initialization and readout. Current efforts in atomically precise lithography have enabled deterministic placement of single dopant atoms into the Si lattice with sub-nm precision. However, critical challenges in atomically precise fabrication have meant systematic, atomic-scale control of the tunneling coupling has not been demonstrated. Here using a room-temperature grown locking layer and precise control over the entire atomic-scale fabrication process, we demonstrate atomic-scale control of the tunnel coupling in atomically precise single-electron transistors (SETs). Using the naturally occurring Si (100) 2x1…
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Taxonomy
TopicsQuantum and electron transport phenomena · Advancements in Semiconductor Devices and Circuit Design · Surface and Thin Film Phenomena
