Improving single-molecule conductance measurements with change point detection from the econometrics toolbox

TL;DR

This paper introduces change point detection from econometrics to identify rupture points in single-molecule conductance data, significantly improving the accuracy of conductance estimates over traditional histogram methods.

Contribution

It applies change point detection techniques to single-molecule conductance measurements, providing a more precise and robust analysis method than conventional approaches.

Findings

CPD reduces standard deviation of conductance estimates by half

CPD is effective across different molecules and temperature conditions

The method enhances the accuracy of theoretical and machine learning analyses

Abstract

Structural breaks occur in timeseries data across a broad range of fields, from economics to nanosciences. For measurements of single-molecule break junctions, structural breaks in conductance versus displacement data occur when the molecular junction ruptures. This moment is significant because the molecule is likely in its most extended geometry, and therefore resembles most closely the geometry used in theoretical predictions. Conventional single-molecule break junction data analysis, on the other hand, typically uses the entire molecular plateau to estimate the single-molecule conductance, which skews the estimate when the plateau is sloped. Borrowing from econometrics, where the study of structural breaks is well established, we present change point detection (CPD) as a tool to search for junction rupture in single-molecule break junction data, and improve estimates in single-molecule conductance. We demonstrate that using CPD instead of the conventional 1D conductance histogram to determine the mean molecular conductance yields a standard deviation in the estimate of typically half that of the conventional approach, greatly improving accuracy. We apply CPD to three separate data sets, two on 4,4'-bipyridine and one on a silane, two at room temperature and one at 4 K, two in one lab, one in another, to show the wide applicability of even the simplest of CPD algorithms: the Chow test. This versatility and better accuracy will propagate into more accurate theoretical simulations. These improved metrics, in turn, will further improve any downstream analyses, including all emerging machine learning approaches.