2017
DOI: 10.1002/smtd.201700071
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Single‐Molecule Electrical Detection with Real‐Time Label‐Free Capability and Ultrasensitivity

Abstract: Single‐molecule detection based on electricity can realize direct, real‐time, and label‐free monitoring of the dynamic processes of either chemical reactions or biological functions at the single‐molecule/single‐event level. This provides a fascinating platform to probe detailed information of chemical and biological reactions, including intermediates/transient states and stochastic processes that are usually hidden in ensemble‐averaged experiments, which is of crucial importance to chemical, biological, and m… Show more

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Cited by 39 publications
(36 citation statements)
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“…To directly uncover heterogeneous molecular behaviours in chemical and biological reactions that are usually inaccessible in ensemble experiments, several approaches have been developed to realise single-molecule electrical measurements of molecular interactions by using different device architectures, such as nanotubes 17 20 , nanowires 21 , 22 , nanopores 23 and STM break junctions 14 . Among these approaches, single-molecule techniques 24 , 25 , in particular graphene electrode-molecule single-molecule junctions (GM-SMJs) 26 , are promising because they are able to covalently integrate individual molecular systems tested as the conductive channel into electrical nanocircuits, thus solving the key issues of the device fabrication difficulty and the poor stability. These techniques prove to be a robust platform of single-molecule electrical detection that is capable of probing the dynamic processes of chemical reactions at the single-event level with high temporal resolution and high signal-to-noise ratios, for example photoinduced conformational transition 27 , temperature-dependent σ-bond rotation 28 and host–guest interaction 29 .…”
Section: Introductionmentioning
confidence: 99%
“…To directly uncover heterogeneous molecular behaviours in chemical and biological reactions that are usually inaccessible in ensemble experiments, several approaches have been developed to realise single-molecule electrical measurements of molecular interactions by using different device architectures, such as nanotubes 17 20 , nanowires 21 , 22 , nanopores 23 and STM break junctions 14 . Among these approaches, single-molecule techniques 24 , 25 , in particular graphene electrode-molecule single-molecule junctions (GM-SMJs) 26 , are promising because they are able to covalently integrate individual molecular systems tested as the conductive channel into electrical nanocircuits, thus solving the key issues of the device fabrication difficulty and the poor stability. These techniques prove to be a robust platform of single-molecule electrical detection that is capable of probing the dynamic processes of chemical reactions at the single-event level with high temporal resolution and high signal-to-noise ratios, for example photoinduced conformational transition 27 , temperature-dependent σ-bond rotation 28 and host–guest interaction 29 .…”
Section: Introductionmentioning
confidence: 99%
“…Guo et al. have made much progress in this field, [ 69 ] and although they did not point out that these studies were based on noise characterization, their analysis of the two‐level or multilevel signals was similar to that of RTS noise. Therefore, we consider these studies as one kind of RTS noise characterization.…”
Section: Progress In the Characterization Of Electronic Noise In Molementioning
confidence: 99%
“…However, the advantages of single-molecule devices are their small size and their ability to reflect the unique behaviors of individual molecules. Notably, a special technique that combines chemical stimuli with high time-resolution acquisition was developed to monitor single-molecule junctions [30]. By real-time measurement, the dynamic process of chemical reactions can be revealed at the single-molecule/single-event level.…”
Section: Functional Molecular Electronic Devices Through Environmentamentioning
confidence: 99%