Role of External Field in Polymerization: Mechanism and Kinetics

Zhou, Yin‐Ning; Li, Jin‐Jin; Wu, Yi‐Yang; Luo, Zheng‐Hong

doi:10.1021/acs.chemrev.9b00744

Cited by 165 publications

(160 citation statements)

References 1,131 publications

(1,901 reference statements)

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“…While the groundwork has been laid by a body of impressive work from previous researchers, there remains room for improvement to help pave the road for MPBs to transition into industrial application and scale-up. For example, recent developments in polymer brushes synthesis, including oxygen tolerance [60,81], metal-free polymerization [82], and external regulation [81,83,84,[174][175][176][177][178][179][180] have the potential to make MPB fabrication more user friendly than ever before. Newly described orthogonal approaches in solution will increase synthetic precision: in contrast to sequential SI-FRP/SI-RDRP, orthogonal polymerization techniques and "click" reactions do not compete for the same initiating sites and improve control over grafting ratios.…”

Section: Challenges and Future Directionsmentioning

confidence: 99%

Mixed Polymer Brushes for “Smart” Surfaces

Pester

2020

Polymers

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Mixed polymer brushes (MPBs) are composed of two or more disparate polymers covalently tethered to a substrate. The resulting phase segregated morphologies have been extensively studied as responsive “smart” materials, as they can be reversible tuned and switched by external stimuli. Both computational and experimental work has attempted to establish an understanding of the resulting nanostructures that vary as a function of many factors. This contribution highlights state-of-the-art MPBs studies, covering synthetic approaches, phase behavior, responsiveness to external stimuli as well as novel applications of MPBs. Current limitations are recognized and possible directions for future studies are identified.

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Section: Challenges and Future Directionsmentioning

confidence: 99%

Mixed Polymer Brushes for “Smart” Surfaces

Pester

2020

Polymers

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“…A unique feature of electrochemical reactions is the possibility of modulating reaction rates in a temporal fashion by regulating the current and potential input. 28 As an example, Modestino et al applied electrochemical pulsing techniques—which are often used to study reaction kinetics and mechanisms—to optimize the electrochemical transformation of acrylonitrile ( 7 - 1 ) to adiponitrile ( 7 - 5 ) ( Figure 7 ). 29 Currently, this largest organic electrochemical process in industry suffers from low selectivity at high current densities owing to the difficulty in balancing mass and electron transport.…”

Section: Electrochemistrymentioning

confidence: 99%

New Redox Strategies in Organic Synthesis by Means of Electrochemistry and Photochemistry

et al. 2020

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As the breadth of radical chemistry grows, new means to promote and regulate single-electron redox activities play increasingly important roles in driving modern synthetic innovation. In this regard, photochemistry and electrochemistry—both considered as niche fields for decades—have seen an explosive renewal of interest in recent years and gradually have become a cornerstone of organic chemistry. In this Outlook article, we examine the current state-of-the-art in the areas of electrochemistry and photochemistry, as well as the nascent area of electrophotochemistry. These techniques employ external stimuli to activate organic molecules and imbue privileged control of reaction progress and selectivity that is challenging to traditional chemical methods. Thus, they provide alternative entries to known and new reactive intermediates and enable distinct synthetic strategies that were previously unimaginable. Of the many hallmarks, electro- and photochemistry are often classified as “green” technologies, promoting organic reactions under mild conditions without the necessity for potent and wasteful oxidants and reductants. This Outlook reviews the most recent growth of these fields with special emphasis on conceptual advances that have given rise to enhanced accessibility to the tools of the modern chemical trade.

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“…Compared with chemical modulations, this flexible yet non-invasive procedure not only provides diversified parameters to establish multi-layer controllability and complexity, but also avoids engaging additional challenges of analysis and purification to DCLs. Actually, this remote kinetic control strategy has been extensively studied among many applied researches like polymerization [31] and drug delivery, [32] which could be suggestive references to its inchoate implementation in DCLs for exploring functions. In this section there will be cases that apply physical transduction signals on DCLs to directly manipulate their covalent/noncovalent processes, in light of which we discuss their potential as prototypes for developing smart materials.…”

Section: Remote Kinetic Controlmentioning

confidence: 99%

Strategies for Exploring Functions from Dynamic Combinatorial Libraries

Jia

Zhang

et al. 2020

ChemSystemsChem

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Dynamic combinatorial chemistry (DCC) is a powerful approach for creating complex chemical systems, giving access to the studies of complexity and exploration of functionality in synthetic systems. However, compared with more advanced living systems, the man‐made chemical systems are still less functional, due to their limited complexity and insufficient kinetic control. Here we start by introducing strategies to enrich the complexity of dynamic combinatorial libraries (DCLs) for exploiting unexpected functions by increasing the species of building blocks and/or templates used. Then, we discuss how dynamic isomerization of photo‐switchable molecules help DCLs increase and alter the systemic complexity in‐situ. Multi‐phase DCLs will also be reviewed to thrive complexity and functionality across the interfaces. Finally, there will be a summary and outlook about remote kinetic control in DCLs that are realized by applying exogenous physical transduction signals of stress, light, heat and ultrasound.

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Role of External Field in Polymerization: Mechanism and Kinetics

Cited by 165 publications

References 1,131 publications

Mixed Polymer Brushes for “Smart” Surfaces

Mixed Polymer Brushes for “Smart” Surfaces

New Redox Strategies in Organic Synthesis by Means of Electrochemistry and Photochemistry

Strategies for Exploring Functions from Dynamic Combinatorial Libraries

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