Digging through the (Statistical) Dirt: A Reproducible Method for Single-Molecule Flicker Noise Analysis

James M.F. Morris; Jarred Potter; Demetris Bates; Chuanli Wu; Craig M. Robertson; Simon J. Higgins; Richard J. Nichols; Paul J. Low; Andrea Vezzoli

doi:10.1021/acs.jpcc.4c07780

Digging through the (Statistical) Dirt: A Reproducible Method for Single-Molecule Flicker Noise Analysis

James M.F. Morris, Jarred Potter, Demetris Bates, Chuanli Wu, Craig M. Robertson, Simon J. Higgins, Richard J. Nichols, Paul J. Low, Andrea Vezzoli

School of Molecular Sciences

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

Abstract

Flicker noise analysis has found widespread use in the molecular electronics community over the past 9 years. The noise power of the junctions and the value of its scaling exponent n provide information on the spatial overlap of scattering states in single-molecule junctions and give unique insights into quantum transport phenomena at the single-molecule level. The predominant drawback of this analytical tool is the inconsistency of the methodologies employed, resulting in irreproducibility across data sets acquired in different conditions or in different laboratories. Herein, we provide a pathway to a more reproducible methodology, detailing issues with the currently accepted correlation techniques employed and introducing the use of more statistically robust data processing criteria and lower thresholds for data acquisition parameters.

Original language	English
Pages (from-to)	4097-4104
Number of pages	8
Journal	Journal of Physical Chemistry C
Volume	129
Issue number	8
DOIs	https://doi.org/10.1021/acs.jpcc.4c07780
Publication status	Published - 27 Feb 2025

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title = "Digging through the (Statistical) Dirt: A Reproducible Method for Single-Molecule Flicker Noise Analysis",

abstract = "Flicker noise analysis has found widespread use in the molecular electronics community over the past 9 years. The noise power of the junctions and the value of its scaling exponent n provide information on the spatial overlap of scattering states in single-molecule junctions and give unique insights into quantum transport phenomena at the single-molecule level. The predominant drawback of this analytical tool is the inconsistency of the methodologies employed, resulting in irreproducibility across data sets acquired in different conditions or in different laboratories. Herein, we provide a pathway to a more reproducible methodology, detailing issues with the currently accepted correlation techniques employed and introducing the use of more statistically robust data processing criteria and lower thresholds for data acquisition parameters.",

author = "Morris, {James M.F.} and Jarred Potter and Demetris Bates and Chuanli Wu and Robertson, {Craig M.} and Higgins, {Simon J.} and Nichols, {Richard J.} and Low, {Paul J.} and Andrea Vezzoli",

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AU - Wu, Chuanli

AU - Robertson, Craig M.

AU - Higgins, Simon J.

AU - Nichols, Richard J.

AU - Low, Paul J.

AU - Vezzoli, Andrea

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Digging through the (Statistical) Dirt: A Reproducible Method for Single-Molecule Flicker Noise Analysis

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MOLECULAR THERMOELECTRIC MATERIALS: A NEW HOT TOPIC

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Digging through the (Statistical) Dirt: A Reproducible Method for Single-Molecule Flicker Noise Analysis

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MOLECULAR THERMOELECTRIC MATERIALS: A NEW HOT TOPIC

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