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Understanding chemical processes at the single-molecule scale represents the ultimate limit of analytical chemistry. Single-molecule detection techniques allow one to reveal the detailed dynamics and kinetics of a chemical reaction with unprecedented accuracy. It has also enabled the discoveries of new reaction pathways or intermediates/transition states that are inaccessible in conventional ensemble experiments, which is critical to elucidating their intrinsic mechanisms. Thanks to the rapid development of single-molecule junction (SMJ) techniques, detecting chemical reactions via monitoring the electrical current through single molecules has received an increasing amount of attention and has witnessed tremendous advances in recent years. Research efforts in this direction have opened a new route for probing chemical and physical processes with single-molecule precision. This review presents detailed advancements in probing single-molecule chemical reactions using SMJ techniques. We specifically highlight recent progress in investigating electric-field-driven reactions, reaction dynamics and kinetics, host–guest interactions, and redox reactions of different molecular systems. Finally, we discuss the potential of single-molecule detection using SMJs across various future applications.
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Nanosecond-scale single-molecule reaction dynamics for scalable synthesis on a chip
ABSTRACT Reaction mechanism studies typically involve the characterization of products, and intermediates are often characterized by (sub)millisecond techniques, such as nuclear magnetic resonance, while femto/attosecond spectroscopies are used to elucidate the evolution of transition states and electron dynamics. However, due to the lack of detection techniques in the microsecond to nanosecond range, as well as the emergent complexity with increasing scale, most of the proposed intermediates have not yet been detected, which significantly hinders reaction optimization. Here, we present such a nanosecond-scale real-time single-molecule electrical monitoring technique. Using this technique, a series of hidden intermediates in an example Morita-Baylis-Hillman reaction were directly observed, allowing the visualization of the reaction pathways, clarification of the two proposed proton transfer pathways, and quantitative description of their contributions to the turnover. Moreover, the emergent complexity of the catalysis, including the catalysis oscillation effect and the proton quantum tunneling effect, is further unveiled. Finally, this useful yet low-yield reaction was successfully catalyzed by the application of an electric field, leading to a high turnover frequency (∼5000 s−1 at a 1 V bias voltage). This new paradigm of mechanistic study and reaction optimization shows potential application in scalable synthesis by integrated single-molecule electronic devices on chip.
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- Award ID(s):
- 2153972
- PAR ID:
- 10627615
- Publisher / Repository:
- Oxford University Press
- Date Published:
- Journal Name:
- National Science Review
- Volume:
- 12
- Issue:
- 9
- ISSN:
- 2095-5138
- Format(s):
- Medium: X
- Sponsoring Org:
- National Science Foundation
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