Spectral Clustering to Analyze the Hidden Events in Single-Molecule Break Junctions

Lin, Luchun; Tang, Chun; Dong, Gang; Chen, Zhuo; Pan, Zhichao; Liu, Junyang; Yang, Yang; Shi, Jia; Ji, Rongrong; Hong, Wenjing

doi:10.1021/acs.jpcc.0c11473

Cited by 35 publications

(38 citation statements)

References 56 publications

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“…Here the classification accuracy is defined as the proportion of correctly classified traces in the test set (by comparing the algorithm-generated class label of each conductance trace against its manual label). For comparison, we also apply alternative models to sort the conductance traces in the test set, including five unsupervised methods [tdistributed stochastic neighbor embedding (t-SNE) combined with graph average linkage (GAL), [32][33][34]18] uniform manifold approximation and projection (UMAP) combined with Gaussian mixed model (GMM), [35,36,18] DAK, [11] PCA combined with Kmeans + + [12,13] and spectral clustering [19] ], one supervised method (directly trained CNN) and one semi-supervised method (label propagation [37] ). For the former two unsupervised methods, the cosine (cos.) distance measure approach is used.…”

Section: Resultsmentioning

confidence: 99%

“…Recently machine learning has been introduced into molecular electronics, [10][11][12][13][14][15][16][17][18][19][20][21][22][23][24][25][26][27] as a powerful tool to analyze break junction data. Supervised and unsupervised learning are the two main classes of machine learning algorithms, their main difference being whether or not a manually labeled training set is needed.…”

Section: Introductionmentioning

confidence: 99%

“…Supervised and unsupervised learning are the two main classes of machine learning algorithms, their main difference being whether or not a manually labeled training set is needed. Due to limited labor costs and the potential advantage of avoiding predefined bias in solving specific problems, many previous studies prefer unsupervised learning methods, [10][11][12][13][14][15][16][17][18][19][20][21][22] such as multi-parameter vector-based classification (MPVC), [10] deep auto-encoder K-means (DAK), [11] K-means + + , [12] principal component analysis (PCA), [13] Alexnet-enhanced autoencoder [14] and spectral clustering. [19] In general, the conductance traces collected for a certain molecule or different molecules are grouped by their mutual similarities to uncover the underlying features.…”

Section: Introductionmentioning

confidence: 99%

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Using Weakly Supervised Deep Learning to Classify and Segment Single‐Molecule Break‐Junction Conductance Traces

et al. 2021

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In order to design molecular electronic devices with high performance and stability, it is crucial to understand their structure-to-property relationships. Single-molecule break junction measurements yield a large number of conductancedistance traces, which are inherently highly stochastic. Here we propose a weakly supervised deep learning algorithm to classify and segment these conductance traces, a method that is mainly based on transfer learning with the pretrain-finetune technique. By exploiting the powerful feature extraction capabilities of the pretrained VGG-16 network, our convolutional neural network model not only achieves high accuracy in the classification of the conductance traces, but also segments precisely the conductance plateau from an entire trace with very few manually labeled traces. Thus, we can produce a more reliable estimation of the junction conductance and quantify the junction stability. These findings show that our model has achieved a better accuracy-to-manpower efficiency balance, opening up the possibility of using weakly supervised deep learning approaches in the studies of single-molecule junctions.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Using Weakly Supervised Deep Learning to Classify and Segment Single‐Molecule Break‐Junction Conductance Traces

et al. 2021

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“…One strategy for separating qualitatively different behaviors that may overlap in 1D and 2D histograms is to employ clustering. Indeed, over the past five years several clustering approaches have been designed specifically for breaking traces 34,[43][44][45][46][47][48][49][50][51][52][53] and related data, 54,55 and these approaches have had varied success in extracting known and potential features, including "hidden" features, from real and simulated datasets. However, clustering algorithms by definition look for groupings of similar data, and so they will always struggle with truly rare behaviors that may not be common enough to form a clear grouping.…”

Section: Introductionmentioning

confidence: 99%

Grid-Based Correlation Analysis to Identify Rare Quantum Transport Behaviors

et al. 2021

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Most single-molecule transport experiments produce large and stochastic datasets containing a wide range of behaviors, presenting both a challenge to their analysis, but also an opportunity for discovering new physical insights. Recently, several unsupervised clustering algorithms have been developed to help extract and separate distinct features from single-molecule transport data. However, these clustering approaches are in general neither designed nor appropriate for identifying very rare features and behaviors, such as switching events, chemical reactions, or particular binding modes, which may nonetheless contain physically meaningful information. In this work we introduce a completely new analysis framework specifically designed for rare event detection in singlemolecule break junction data as a necessary component to enable such studies in the future. Our approach leverages the concept of correlations of breaking traces with their own history to robustly identify paths through distanceconductance space that correspond to reproducible rare behaviors. As both a demonstrative and important example, we focus on rare conductance plateaus for short molecules, which can be essentially invisible when examining raw data. We show that our grid-based correlation tools successfully and reproducibly locate these rare plateaus in real experimental datasets. This result provides useful insight into the nanoscopic junction environment, enables a broader variety of molecules to be considered in the future, and validates our new approach as a powerful tool for detecting rare yet meaningful behaviors in single molecule transport data.

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“…In the past decade, numerous data analysis methods were introduced to process the conductance traces, including statistical methods, [4][5][6][7] analytical modeling, [8,9] electronic noise analysis, [10][11][12][13][14][15] and machine learning and deep learning methods. [16][17][18] Among these methods, analysis of flicker noise from the single-molecule junctions has suggested to shed new light on the understanding of charge transport mechanisms of singlemolecule junctions. [19][20][21][22] The electronic noise of single-molecule junctions can be categorized into highfrequency noise and low-frequency noise, and the latter, including flicker noise and random telegraph signal (RTS) noise (that is 1/f noise and 1/f 2 noise, respectively due to their frequency dependence nature), is the result of rearrangement of metal atom on the electrode surface and the fluctuation of the microenvironment of molecule junctions.…”

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confidence: 99%

The Evolution of the Charge Transport Mechanism in Single‐Molecule Break Junctions Revealed by Flicker Noise Analysis

Pan

Chen

Tang

et al. 2021

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challenging to reveal the evolution of the charge transport mechanism from the conductance characterization of singlemolecule conductance. In the past decade, numerous data analysis methods were introduced to process the conductance traces, including statistical methods, [4][5][6][7] analytical modeling, [8,9] electronic noise analysis, [10][11][12][13][14][15] and machine learning and deep learning methods. [16][17][18] Among these methods, analysis of flicker noise from the single-molecule junctions has suggested to shed new light on the understanding of charge transport mechanisms of singlemolecule junctions. [19][20][21][22] The electronic noise of single-molecule junctions can be categorized into highfrequency noise and low-frequency noise, and the latter, including flicker noise and random telegraph signal (RTS) noise (that is 1/f noise and 1/f 2 noise, respectively due to their frequency dependence nature), is the result of rearrangement of metal atom on the electrode surface and the fluctuation of the microenvironment of molecule junctions. [23] Previous reports have shown that flicker noise exhibits a power-law dependence with conductance that can serve as a probe of the electrode-molecule coupling. [21,22] Specifically, if the dependence exponent is close to 1.0, the electrode-molecule coupling follows the throughbond mechanism, while an exponent close to 2.0 corresponds to a through-space coupling. During the evolution of different junction configurations, the interface coupling may change dramatically with the evolution of electrode-molecule coupling during the break junction process, suggesting that an investigation of the time evolution of flicker noise in molecule junctions can provide a unique tool to understand the evolution of charge transport mechanisms. [24][25][26][27][28][29] However, the time dimension of the conductance traces is hardly deciphered in past studies. Toward the time resolution, time-frequency analysis (TFA) has proven to be an effective tool that combines both time and frequency dimensions in processing signals such as speech signals and polysomnography signals, [30,31] suggesting that TFA can be a promising approach to characterize the time evolution behavior of flicker noise in single-molecule junctions.In this study, we report that flicker noise can serve as an indicator of the evolution of charge transport mechanisms in single-molecule break junctions. By assigning a dependence The electronic noise characterization of single-molecule devices provides insights into the mechanisms of charge transport. In this work, it is reported that flicker noise can serve as an indicator of the time-dependent evolution of charge transport mechanisms in the single-molecule break junction process. By introducing time-frequency analysis, the authors find that flicker noise components of the molecule junction show time evolution behavior in the dynamic break junction process. A further investigation of the power-law dependence of flicker with conductance during the dynamic break junction pro...

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Spectral Clustering to Analyze the Hidden Events in Single-Molecule Break Junctions

Cited by 35 publications

References 56 publications

Using Weakly Supervised Deep Learning to Classify and Segment Single‐Molecule Break‐Junction Conductance Traces

Using Weakly Supervised Deep Learning to Classify and Segment Single‐Molecule Break‐Junction Conductance Traces

Grid-Based Correlation Analysis to Identify Rare Quantum Transport Behaviors

The Evolution of the Charge Transport Mechanism in Single‐Molecule Break Junctions Revealed by Flicker Noise Analysis

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