Deriving Material Properties from Feedback Error Signals in Scanning Tunneling Microscopy

Nileema Sharma; James McKenzie; Matthew Toole; Brenden R. Ortiz; Andrea Capa Salinas; Stephen D. Wilson; Xiaolong Liu

doi:10.1021/acs.nanolett.4c06404

Deriving Material Properties from Feedback Error Signals in Scanning Tunneling Microscopy

Nileema Sharma
, James McKenzie
, Matthew Toole
, Brenden R. Ortiz
, Andrea Capa Salinas
, Stephen D. Wilson
, Xiaolong Liu

Correlated Electron Materials

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

Imperfections in measurements, e.g., deviations and broadening, are not devoid of information; rather, they can reveal valuable physical properties and processes. Scanning tunneling microscopy leverages a negative feedback loop to regulate the tunneling current. Practically, current fluctuates around its set point, and such deviations are considered insignificant and ignored. Here, we investigate the information embedded in these deviations. In the constant-current mode with an active feedback loop, we observe an unexpected persistent DC current offset from its set point when the tunneling junction is periodically perturbed. We demonstrate both experimentally and theoretically that such error signals encode local tunneling barrier heights and the square of local differential conductance as a consequence of the interplay between rectification and active feedback compensation. We provide evidence on the generalizability of this phenomenology to other negative feedback systems. This new approach has the potential to broadly impact physical sciences by allowing rapid measurements without lock-in amplifiers.

Original language	English
Pages (from-to)	3309-3315
Number of pages	7
Journal	Nano Letters
Volume	25
Issue number	8
DOIs	https://doi.org/10.1021/acs.nanolett.4c06404
State	Published - Feb 26 2025

Funding

The authors thank M. Lemmon for valuable discussions. N.S., J.M., M.T., and X.L. acknowledge support from the U.S. Department of Energy, Office of Science, Office of Basic Energy Sciences under Award Numbers DE-SC0025021 and DE-SC0024291. N.S. and M.T. acknowledge support from the Notre Dame Materials Science and Engineering Fellowship. S.D.W., A.C.S., and B.R.O. gratefully acknowledge support via the UC Santa Barbara NSF Quantum Foundry funded via the Q-AMASE-i program under Award DMR-1906325.

Keywords

constant current mode
error
feedback loop
perturbation
scanning tunneling microscopy

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10.1021/acs.nanolett.4c06404

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title = "Deriving Material Properties from Feedback Error Signals in Scanning Tunneling Microscopy",

abstract = "Imperfections in measurements, e.g., deviations and broadening, are not devoid of information; rather, they can reveal valuable physical properties and processes. Scanning tunneling microscopy leverages a negative feedback loop to regulate the tunneling current. Practically, current fluctuates around its set point, and such deviations are considered insignificant and ignored. Here, we investigate the information embedded in these deviations. In the constant-current mode with an active feedback loop, we observe an unexpected persistent DC current offset from its set point when the tunneling junction is periodically perturbed. We demonstrate both experimentally and theoretically that such error signals encode local tunneling barrier heights and the square of local differential conductance as a consequence of the interplay between rectification and active feedback compensation. We provide evidence on the generalizability of this phenomenology to other negative feedback systems. This new approach has the potential to broadly impact physical sciences by allowing rapid measurements without lock-in amplifiers.",

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AU - Capa Salinas, Andrea

AU - Wilson, Stephen D.

AU - Liu, Xiaolong

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AB - Imperfections in measurements, e.g., deviations and broadening, are not devoid of information; rather, they can reveal valuable physical properties and processes. Scanning tunneling microscopy leverages a negative feedback loop to regulate the tunneling current. Practically, current fluctuates around its set point, and such deviations are considered insignificant and ignored. Here, we investigate the information embedded in these deviations. In the constant-current mode with an active feedback loop, we observe an unexpected persistent DC current offset from its set point when the tunneling junction is periodically perturbed. We demonstrate both experimentally and theoretically that such error signals encode local tunneling barrier heights and the square of local differential conductance as a consequence of the interplay between rectification and active feedback compensation. We provide evidence on the generalizability of this phenomenology to other negative feedback systems. This new approach has the potential to broadly impact physical sciences by allowing rapid measurements without lock-in amplifiers.

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KW - feedback loop

KW - perturbation

KW - scanning tunneling microscopy

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Deriving Material Properties from Feedback Error Signals in Scanning Tunneling Microscopy

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