Inverted-Mode Scanning Tunneling Microscopy for Atomically Precise Fabrication

Eduardo Barrera; Bheeshmon Thanabalasingam; Rafik Addou; Damian Allis; Aly Asani; Jeremy Barton; Tomass Bernots; Brandon Blue; Adam Bottomley; Doreen Cheng; Byoung Choi; Megan Cowie; Chris Deimert; Michael Drew; Mathieu Durand; Tyler Enright; Robert A. Freitas Jr.; Alan Godfrey; Ryan Groome; Si Yue Guo; Sheldon Haird; Aru Hill; Taleana Huff; Christian Imperiale; Alex Inayeh; Jerry Jeyachandra; Mark Jobes; Matthew Kennedy; Robert J. Kirby; Mykhaylo Krykunov; Sam Lilak; Hadiya Ma; Adam Maahs; Cameron J. Mackie; Oliver MacLean; Michael Marshall; Terry McCallum; Ralph C. Merkle; Mathieu Morin; Jonathan Myall; Alexei Ofitserov; Sheena Ou; Ryan Plumadore; Adam Powell; Max Prokopenko; Henry Rodriguez; Sam Rohe; Luis Sandoval; Marc Savoie; Khalil Sayed-Akhmad; Ben Scheffel; Tait Takatani; D. Alexander Therien; Finley Van Barr; Dusan Vobornik; Janice Wong; Reid Wotton; Ryan Yamachika; Cristina Yu; Marco Taucer

arXiv:2512.24431·cond-mat.mes-hall·January 1, 2026

Inverted-Mode Scanning Tunneling Microscopy for Atomically Precise Fabrication

Eduardo Barrera, Bheeshmon Thanabalasingam, Rafik Addou, Damian Allis, Aly Asani, Jeremy Barton, Tomass Bernots, Brandon Blue, Adam Bottomley, Doreen Cheng, Byoung Choi, Megan Cowie, Chris Deimert, Michael Drew, Mathieu Durand, Tyler Enright, Robert A. Freitas Jr., Alan Godfrey

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TL;DR

This paper introduces inverted-mode STM, a novel technique that allows for precise atom manipulation and chemical reactions at the atomic scale by controlling the probe and sample configurations, enabling scalable atomically precise fabrication.

Contribution

The paper presents inverted-mode STM, a new method that enables controlled chemical reactions and atom manipulation with sub-angstrom precision, addressing longstanding challenges in STM-based fabrication.

Findings

01

Reproducible hydrogen abstraction using alkynyl-terminated molecules.

02

Probe apex imaging with tailored molecules on Si(100).

03

Potential extension to other elements and molecules.

Abstract

Scanning Tunneling Microscopy (STM) enables fabrication of atomically precise structures with unique properties and growing technological potential. However, reproducible manipulation of covalently bonded atoms requires control over the atomic configuration of both sample and probe - a longstanding challenge in STM. Here, we introduce inverted-mode STM, an approach that enables mechanically controlled chemical reactions for atomically precise fabrication. Tailored molecules on a Si(100) surface image the probe apex, and the usual challenge of understanding the probe structure is effectively solved. The molecules can also react with the probe, with the two sides of the tunnel junction acting as reagents positioned with sub-angstrom precision. This allows abstraction or donation of atoms from or to the probe apex. We demonstrate this by using a novel alkynyl-terminated molecule to…

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Taxonomy

TopicsSurface Chemistry and Catalysis · Surface and Thin Film Phenomena · Molecular Junctions and Nanostructures