Your search keyword '"Christine K. Luscombe"' showing total 208 results

1. The effect of weathering environments on microplastic chemical identification with Raman and IR spectroscopy: Part I. polyethylene and polypropylene

Author

Samantha Phan, Jacqueline L. Padilla-Gamiño, and Christine K. Luscombe

Subjects

Microplastics, Weathering, IR spectroscopy, Raman spectroscopy, Marine environment, Puget sound microplastics, Polymers and polymer manufacture, TP1080-1185

Abstract

Chemical identification of microplastics is a crucial step in understanding the sources of microplastics and studying the effects of microplastic pollution. A major challenge to microplastics identification is that weathered microplastics undergo surface chemical changes that differ from their unweathered counterparts which hinders spectroscopic matching and thus identification. While IR spectroscopy is a common technique used for microplastics identification, Raman spectroscopy is a complementary technique and its higher spatial resolution capabilities (capable of analyzing particles as small as 1 μm) make it a popular tool to identify smaller microplastics that can otherwise go undetected by IR techniques. Currently, there is limited Raman spectroscopic information on weathered microplastics. Herein, we investigate the effects of artificial weathering on polyethylene and polypropylene microplastics for 0–26 weeks in four different weathering conditions (air, DI water, artificial seawater, and Puget Sound seawater) using Raman and IR spectroscopy. Microplastics weathering in different environments reveal that they can lead to different IR spectra, suggestive of varying degradation pathways for plastics, but relatively similar Raman spectra. Raman spectra, however, do show variations in peaks associated with the crystallinity and amorphous regions in the polymers which indicate morphological changes in the weathered microplastics. Overall, Raman spectroscopy acts as a practical interrelated method that can be used in lieu of IR spectroscopy in cases where weathering can complicate plastics identification by spectroscopic matching. This work aims to provide spectral information to facilitate marine microplastic chemical identification and encourage more investigations on the conditions that influence microplastic weathering.

Published

2022

2. Room-temperature Pd/Ag direct arylation enabled by a radical pathway

Author

Amy L. Mayhugh and Christine K. Luscombe

Subjects

direct arylation, indole, palladium radical, visible light, Science, Organic chemistry, QD241-441

Abstract

Direct arylation is an appealing method for preparing π-conjugated materials, avoiding the prefunctionalization required for traditional cross-coupling methods. A major effort in organic electronic materials development is improving the environmental and economic impact of production; direct arylation polymerization (DArP) is an effective method to achieve these goals. Room-temperature polymerization would further improve the cost and energy efficiencies required to prepare these materials. Reported herein is new mechanistic work studying the underlying mechanism of room temperature direct arylation between iodobenzene and indole. Results indicate that room-temperature, Pd/Ag-catalyzed direct arylation systems are radical-mediated. This is in contrast to the commonly proposed two-electron mechanisms for direct arylation and appears to extend to other substrates such as benzo[b]thiophene and pentafluorobenzene.

Published

2020

3. The Role of Tie Chains on the Mechano‐Electrical Properties of Semiconducting Polymer Films

Author

Kaichen Gu, Jonathan W. Onorato, Christine K. Luscombe, and Yueh‐Lin Loo

Subjects

chain alignment, charge transport, conjugated polymers, field‐effect transistors, organic electronics, Electric apparatus and materials. Electric circuits. Electric networks, TK452-454.4, Physics, QC1-999

Abstract

Abstract The mechano‐electrical properties of poly(3‐hexylthiophene) thin films are investigated as a function of their tie‐chain content. Tie chains play an indispensable role in enabling strain‐induced structural alignment and charge‐transport enhancement in the strain direction. In the absence of sufficient tie chains, the external mechanical force cannot induce any significant polymer backbone alignment locally or crystallite reorientation at the mesoscale. These samples instead undergo brittle fracture on deformation, with cracks forming normal to the direction of strain; charge transport in this direction is hindered as a consequence. This mechanistic insight on strain alignment points to the promise of leveraging tie‐chain fraction as a practical tuning knob for effecting the mechano‐electrical properties in conjugated polymer systems.

Published

2020

4. Recent Developments in C–H Activation for Materials Science in the Center for Selective C–H Activation

Author

Junxiang Zhang, Lauren J. Kang, Timothy C. Parker, Simon B. Blakey, Christine K. Luscombe, and Seth R. Marder

Subjects

π-conjugated materials, electron-acceptors, direct arylation, C–H activation, living polymerization, Organic chemistry, QD241-441

Abstract

Organic electronics is a rapidly growing field driven in large part by the synthesis of π-conjugated molecules and polymers. Traditional aryl cross-coupling reactions such as the Stille and Suzuki have been used extensively in the synthesis of π-conjugated molecules and polymers, but the synthesis of intermediates necessary for traditional cross-couplings can include multiple steps with toxic and hazardous reagents. Direct arylation through C–H bond activation has the potential to reduce the number of steps and hazards while being more atom-economical. Within the Center for Selective C–H Functionalization (CCHF), we have been developing C–H activation methodology for the synthesis of π-conjugated materials of interest, including direct arylation of difficult-to-functionalize electron acceptor intermediates and living polymerization of π-conjugated polymers through C–H activation.

Published

2018

5. Resonant X-ray Diffraction Reveals the Location of Counterions in Doped Organic Mixed Ionic Conductors

Author

Lucas Q. Flagg, Jonathan W. Onorato, Christine K. Luscombe, Vinayak Bhat, Chad Risko, Ben Levy-Wendt, Michael F. Toney, Christopher R. McNeill, Guillaume Freychet, Mikhail Zhernenkov, Ruipeng Li, and Lee J. Richter

Subjects

General Chemical Engineering, Materials Chemistry, General Chemistry

Published

2023

6. Engineered hierarchically ordered structures in conducting polymers enabling enhanced performance of lithium-ion batteries

Author

Isha Sanskriti, Aditya Singh, and Christine K. Luscombe

Subjects

General Energy

Published

2023

7. Ligand Decomposition during Nanoparticle Synthesis: Influence of Ligand Structure and Precursor Selection

Author

Breena M. Sperry, Nadzeya A. Kukhta, Yunping Huang, and Christine K. Luscombe

Subjects

General Chemical Engineering, Materials Chemistry, General Chemistry

Published

2023

8. Influence of Side Chain Interdigitation on Strain and Charge Mobility of Planar Indacenodithiophene Copolymers

Author

Parker J. W. Sommerville, Alex H. Balzer, Garrett Lecroy, Lorenzo Guio, Yunfei Wang, Jonathan W. Onorato, Nadzeya A. Kukhta, Xiaodan Gu, Alberto Salleo, Natalie Stingelin, and Christine K. Luscombe

Subjects

alkyl side chains, stretchable electronics, organic field effect transistors, conjugated polymers, General Medicine, indacenodithiophene copolymers

Abstract

Indacenodithiophene (IDT) copolymers are a class of conjugated polymers that have limited long-range order and high hole mobilities, which makes them promising candidates for use in deformable electronic devices. Key to their high hole mobilities is the coplanar monomer repeat units within the backbone. Poly(indacenodithiophene-benzothiadiazole) (PIDTC16-BT) and poly(indacenodithiophene-thiapyrollodione) (PIDTC16-TPDC1) are two IDT copolymers with planar backbones, but they are brittle at low molecular weight and have unsuitably high elastic moduli. Substitution of the hexadecane (C16) side chains of the IDT monomer with isocane (C20) side chains was performed to generate a new BT-containing IDT copolymer: PIDTC20-BT. Substitution of the methyl (C1) side chain on the TPD monomer for an octyl (C8) and 6-ethylundecane (C13B) afford two new TPD-containing IDT copolymers named PIDTC16-TPDC8 and PIDTC16-TPDC13B, respectively. Both PIDTC16-TPDC8 and PIDTC16-TPDC13B are relatively well deformable, have a low yield strain, and display significantly reduced elastic moduli. These mechanical properties manifest themselves because the lengthened side chains extending from the TPD-monomer inhibit precise intermolecular ordering. In PIDTC16-BT, PIDTC20-BT and PIDTC16-TPDC1 side chain ordering can occur because the side chains are only present on the IDT subunit, but this results in brittle thin films. In contrast, PIDTC16-TPDC8 and PIDTC16-TPDC13B have disordered side chains, which seems to lead to low hole mobilities. These results suggest that disrupting the interdigitation in IDT copolymers through comonomer side chain extension leads to more ductile thin films with lower elastic moduli, but decreased hole mobility because of altered local order in the respective thin films. Our work, thus, highlights the trade-off between molecular packing structure for deformable electronic materials and provides guidance for designing new conjugated polymers for stretchable electronics.

Published

2022

9. Recent trends in marine microplastic modeling and machine learning tools: Potential for long-term microplastic monitoring

Author

Samantha, Phan, Christine K., Luscombe, Samantha, Phan, and Christine K., Luscombe

Abstract

The increase in the global demand for plastics, and more recently during the pandemic, is a major concern for the future of plastic waste pollution and microplastics. Efficient microplastic monitoring is imperative to understanding the long-term effects and progression of microplastic effects in the environment. Numerical models are valuable in studying microplastic transport as they can be used to examine the effects of different parameters systematically to help elucidate the fate and transport processes of microplastics, thus providing a holistic view of microplastics in the ocean environment. By incorporating physical parameters (such as size, shape, density, and identity of microplastics), numerical models have gained better understanding of the physics of microplastic transport, predicted sinking velocities more accurately, and estimated microplastic pathways in marine environments. However, availability of large amounts of information about microplastic physical and chemical parameters is sparse. Machine learning and computer-vision tools can aid in acquiring environmental information and provide input to develop more accurate models and verify their predictions. More accurate models can further the understanding of microplastic transport, facilitate monitoring efforts, and thus optimize where more data collection can take place to ultimately improve machine learning tools. This review offers a perspective on how image-based machine learning can be exploited to help uncover the physics of microplastic transport behaviors. Additionally, the authors hope the review inspires studies that can bridge the gap between numerical modeling and machine learning for microplastic analysis to exploit their joined potential., source:https://pubs.aip.org/aip/jap/article/133/2/020701/2869069/Recent-trends-in-marine-microplastic-modeling-and

Published

2023

10. Influence of Side Chain Interdigitation on Strain and Charge Mobility of Planar Indacenodithiophene Copolymers

Author

Parker J. W., Sommerville, Alex H., Balzer, Garrett, Lecroy, Lorenzo, Guio, Yunfei, Wang, Jonathan W., Onorato, Nadzeya A., Kukhta, Xiaodan, Gu, Alberto, Salleo, Natalie, Stingelin, Christine K., Luscombe, Parker J. W., Sommerville, Alex H., Balzer, Garrett, Lecroy, Lorenzo, Guio, Yunfei, Wang, Jonathan W., Onorato, Nadzeya A., Kukhta, Xiaodan, Gu, Alberto, Salleo, Natalie, Stingelin, and Christine K., Luscombe

Abstract

Indacenodithiophene (IDT) copolymers are a class of conjugated polymers that have limited long-range order and high hole mobilities, which makes them promising candidates for use in deformable electronic devices. Key to their high hole mobilities is the coplanar monomer repeat units within the backbone. Poly(indacenodithiophene-benzothiadiazole) (PIDTC16-BT) and poly(indacenodithiophene-thiapyrollodione) (PIDTC16-TPDC1) are two IDT copolymers with planar backbones, but they are brittle at low molecular weight and have unsuitably high elastic moduli. Substitution of the hexadecane (C16) side chains of the IDT monomer with isocane (C20) side chains was performed to generate a new BT-containing IDT copolymer: PIDTC20-BT. Substitution of the methyl (C1) side chain on the TPD monomer for an octyl (C8) and 6-ethylundecane (C13B) afford two new TPD-containing IDT copolymers named PIDTC16-TPDC8 and PIDTC16-TPDC13B, respectively. Both PIDTC16-TPDC8 and PIDTC16-TPDC13B are relatively well deformable, have a low yield strain, and display significantly reduced elastic moduli. These mechanical properties manifest themselves because the lengthened side chains extending from the TPD-monomer inhibit precise intermolecular ordering. In PIDTC16-BT, PIDTC20-BT and PIDTC16-TPDC1 side chain ordering can occur because the side chains are only present on the IDT subunit, but this results in brittle thin films. In contrast, PIDTC16-TPDC8 and PIDTC16-TPDC13B have disordered side chains, which seems to lead to low hole mobilities. These results suggest that disrupting the interdigitation in IDT copolymers through comonomer side chain extension leads to more ductile thin films with lower elastic moduli, but decreased hole mobility because of altered local order in the respective thin films. Our work, thus, highlights the trade-off between molecular packing structure for deformable electronic materials and provides guidance for designing new conjugated polymers for stretchable electronics., source:https://pubs.acs.org/doi/10.1021/acspolymersau.2c00034

Published

2023

11. Cross‐Dehydrogenative Coupling Polymerization via C−H Activation for the Synthesis of Conjugated Polymers

Author

Baitan, Chakraborty, Christine K., Luscombe, Baitan, Chakraborty, and Christine K., Luscombe

Abstract

Owing to their versatile (opto)electronic properties, conjugated polymers have found application in several organic electronic devices. Cross-coupling reactions such as Stille, Suzuki, Kumada couplings, and direct arylation reactions have proved to be effective for their synthesis. More atom-efficient oxidative direct arylation polymerization has also been reported for making homopolymers. However, growing interest toward donor-acceptor polymers has led to the recent emergence of cross-dehydrogenative coupling (CDC) polymerization to synthesize alternating copolymers without any prefunctionalization of monomers. Metal-catalyzed cross-coupling of two simple arenes via double C−H activation, or of an arene with an alkene via oxidative Heck-type reaction have been used so far for CDC polymerization. In this article, we discuss the development of CDC polymerization protocols along with the relevant small molecule CDC reactions for an improved understanding of these reactions., source:https://onlinelibrary.wiley.com/doi/10.1002/anie.202301247

Published

2023

12. Circular Discovery in Small Molecule and Conjugated Polymer Synthetic Methodology

Author

Amy L. Mayhugh, Preeti Yadav, and Christine K. Luscombe

Subjects

Colloid and Surface Chemistry, Polymers, General Chemistry, Biochemistry, Catalysis, Polymerization

Abstract

Simple and efficient methods are a key consideration for small molecule and polymer syntheses. Direct arylation polymerization (DArP) is of increasing interest for preparing conjugated polymers as an effective approach compared to conventional cross-coupling polymerizations. As DArP sees broader utilization, advancements are needed to access materials with improved properties and different monomer structures and to improve the scalability of conjugated polymer synthesis. Presented herein are considerations for developing new methods of conjugated polymer synthesis from small molecule transformations, exploring how DArP has successfully used this approach, and presenting how emerging polymerization methodologies are developing similarly. While it is common to adapt small molecule methods to polymerizations, we demonstrate the ways in which information gained from studying polymerizations can inform and inspire greater advancements in small molecule transformations. This circular approach to organic synthetic method development underlines the value of collaboration between small molecule and polymer-based synthetic research groups.

Published

2022

13. Conjugated Metal–Organic Macrocycles: Synthesis, Characterization, and Electrical Conductivity

Author

Leo B. Zasada, Lorenzo Guio, Ashlyn A. Kamin, Diwash Dhakal, Madison Monahan, Gerald T. Seidler, Christine K. Luscombe, and Dianne J. Xiao

Subjects

Colloid and Surface Chemistry, General Chemistry, Biochemistry, Catalysis

Abstract

The dimensional reduction of solids into smaller fragments provides a route to achieve new physical properties and gain deeper insight into the extended parent structures. Here, we report the synthesis of CuTOTP-OR (TOTPn– = 2,3,6,7-tetraoxidotriphenylene), a family of copper-based macrocycles that resemble truncated fragments of the conductive two-dimensional (2D) metal–organic framework Cu3(HHTP)2 (HHTP = 2,3,6,7,10,11-hexahydroxytriphenylene). The planar metal–organic macrocycles self-assemble into ordered nanotubes with internal diameters of ∼2 nm and short interlayer distances of ∼3.20 Å. Strong π–π stacking interactions between macrocycles facilitate out-of-plane charge transport, and pressed pellet conductivities as high as 2(1) × 10–3 S cm–1 are observed. Peripheral alkyl functionalization enhances solution processability and enables the fabrication of thin-film field-effect transistor devices. Ambipolar charge transport is observed, suggesting that similar behavior may be operative in Cu3(HHTP)2. By coupling the attractive features of metal–organic frameworks with greater processability, these macrocycles enable facile device integration and a more nuanced understanding of out-of-plane charge transport in 2D conductive metal–organic frameworks.

Published

2022

14. An Exception to the Carothers Equation Caused by the Accelerated Chain Extension in a Pd/Ag Cocatalyzed Cross Dehydrogenative Coupling Polymerization

Author

Liwen Xing, Ji-Ren Liu, Xin Hong, Kendall N. Houk, and Christine K. Luscombe

Subjects

Colloid and Surface Chemistry, General Chemistry, Biochemistry, Catalysis

Abstract

The Carothers equation is often used to predict the utility of a small molecule reaction in a polymerization. In this study, we present the mechanistic study of Pd/Ag cocatalyzed cross dehydrogenative coupling (CDC) polymerization to synthesize a donor-acceptor (D-A) polymer of 3,3'-dihexyl-2,2'-bithiophene and 2,2',3,3',5,5',6,6'-octafluorobiphenyl, which go counter to the Carothers equation. It is uncovered that the second chain extension cross-coupling proceeds much more efficiently than the first cross-coupling and the homocoupling side reaction (at least 1 order of magnitude faster) leading to unexpectedly low homocoupling defects and high molecular weight polymers. Kinetic analyses show that C-H bond activation is rate-determining in the first cross-coupling but not in the second cross-coupling. Based on DFT calculations, the high cross-coupling rate in the second cross-coupling was ascribed to the strong Pd-thiophene interaction in the Pd-mediated C-H bond activation transition state, which decreases the energy barrier of the Pd-mediated C-H bond activation. These results have implications beyond polymerizations and can be used to ease the synthesis of a wide range of molecules where C-H bond activation may be the limiting factor.

Published

2022

15. Reconsidering terms for mechanisms of polymer growth: the 'step-growth' and 'chain-growth' dilemma

Author

Chin Han Chan, Jiun-Tai Chen, Wesley S. Farrell, Christopher M. Fellows, Daniel J. Keddie, Christine K. Luscombe, John B. Matson, Jan Merna, Graeme Moad, Gregory T. Russell, Patrick Théato, Paul D. Topham, and Lydia Sosa Vargas

Subjects

Polymers and Plastics, Organic Chemistry, Bioengineering, Biochemistry

Abstract

The terms “step-growth polymerization” and “chain-growth polymerization” are used widely in both written and oral communications to describe the two main mechanisms of polymer growth. As members of the Subcommittee on Polymer Terminology (SPT) in the Polymer Division of the International Union of Pure and Applied Chemistry (IUPAC), we are concerned that these terms are confusing because they do not describe the fundamental differences in the growth of polymers by these methods. For example, both polymerization methods are comprised of a series of steps, and both produce polymer chains. In an effort to recommend comprehensive terms, a 1994 IUPAC Recommendation from the then version of SPT suggested polycondensation and polyaddition as terms for the two variants of “step-growth polymerization”, and similarly chain polymerization and condensative chain polymerization for the two variants of “chain-growth polymerization”. However, these terms also have shortcomings. Adding to the confusion, we have identified a wide variety of other terms that are used in textbooks for describing these basic methods of synthesizing polymers from monomers. Beyond these issues with “step-growth” and “chain-growth”, synthesis of polymers one monomer unit at a time presents a related dilemma in that this synthetic strategy is wholly encompassed by neither of the traditional growth mechanisms. One component of the mission of IUPAC is to develop tools for the clear communication of chemical knowledge around the world, of which recommending definitions for terms is an important element. Here we do not endorse specific terms or recommend new ones; instead, we aim to convey our concerns with the basic terms typically used for classifying methods of polymer synthesis, and in this context we welcome dialogue from the broader polymer community in a bid to resolve these issues.

Published

2022

16. Triarylborane-BODIPY conjugate: An efficient non-fullerene electron acceptor for bulk heterojunction organic solar cell

Author

Upendra K. Pandey, Pakkirisamy Thilagar, Christine K. Luscombe, Samir Kumar Sarkar, and Lauren J. Kang

Subjects

chemistry.chemical_classification, Materials science, Fullerene, Organic solar cell, Renewable Energy, Sustainability and the Environment, Energy conversion efficiency, Polymer, Electron acceptor, Photochemistry, Acceptor, Polymer solar cell, chemistry.chemical_compound, chemistry, General Materials Science, BODIPY

Abstract

A new X-type, structurally twisted, highly soluble TAB-BODIPY based electron acceptor (BDY) is designed and synthesized. Organic solar devices are fabricated using poly(3-hexylthiophene-2,5-diyl) (P3HT) as donor polymer and BDY as an electron acceptor. A promising power conversion efficiency of 4.46% is obtained for this new class of acceptor, which is the first-ever reported on TAB-BODIPY as a non-fullerene acceptor in organic solar cells.

Published

2021

17. Organic building blocks at inorganic nanomaterial interfaces

Author

Hao A Nguyen, Florence Y. Dou, Laura M. Jacoby, Yunping Huang, Daniel R. Gamelin, Helen Larson, Theodore A. Cohen, Breena M. Sperry, Micaela K Homer, Christine K. Luscombe, and Brandi M. Cossairt

Subjects

Silicon, Materials science, chemistry.chemical_element, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Nanomaterials, Photovoltaics, General Materials Science, Electrical and Electronic Engineering, business.industry, Process Chemistry and Technology, Lasers, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Nanostructures, Semiconductor, chemistry, Semiconductors, Mechanics of Materials, Photocatalysis, Surface modification, Photonics, 0210 nano-technology, business, Carbon

Abstract

This tutorial review presents our perspective on designing organic molecules for the functionalization of inorganic nanomaterial surfaces, through the model of an "anchor-functionality" paradigm. This "anchor-functionality" paradigm is a streamlined design strategy developed from a comprehensive range of materials (e.g., lead halide perovskites, II-VI semiconductors, III-V semiconductors, metal oxides, diamonds, carbon dots, silicon, etc.) and applications (e.g., light-emitting diodes, photovoltaics, lasers, photonic cavities, photocatalysis, fluorescence imaging, photo dynamic therapy, drug delivery, etc.). The structure of this organic interface modifier comprises two key components: anchor groups binding to inorganic surfaces and functional groups that optimize their performance in specific applications. To help readers better understand and utilize this approach, the roles of different anchor groups and different functional groups are discussed and explained through their interactions with inorganic materials and external environments.

Published

2022

18. Strategies for the Development of Conjugated Polymer Molecular Dynamics Force Fields Validated with Neutron and X‑ray Scattering

Author

Viktoria Pakhnyuk, Lilo D. Pozzo, Lorenzo Guio, Caitlyn M. Wolf, Christine K. Luscombe, and Sage C. Scheiwiller

Subjects

chemistry.chemical_classification, Molecular dynamics, Materials science, TP1080-1185, chemistry, Scattering, X-ray, Neutron, General Medicine, Polymer, Polymers and polymer manufacture, Conjugated system, Molecular physics

Published

2021

19. Correlating conductivity and Seebeck coefficient to doping within crystalline and amorphous domains in poly(3‐(methoxyethoxyethoxy)thiophene)

Author

Oleg G. Poluektov, Tengzhou Ma, Ban Xuan Dong, Christine K. Luscombe, Jens Niklas, Shrayesh N. Patel, and Jonathan W. Onorato

Subjects

Materials science, Polymers and Plastics, Condensed matter physics, Doping, Conductivity, Thermoelectric materials, Amorphous solid, chemistry.chemical_compound, chemistry, Electrical resistivity and conductivity, Seebeck coefficient, Materials Chemistry, Thiophene, Physical and Theoretical Chemistry

Published

2021

20. Room Temperature C–H Arylation of Benzofurans by Aryl Iodides

Author

Amy L. Mayhugh and Christine K. Luscombe

Subjects

Heat sensitive, chemistry.chemical_compound, chemistry, Aryl, Organic Chemistry, Regioselectivity, Physical and Theoretical Chemistry, Benzofuran, Biochemistry, Combinatorial chemistry

Abstract

A robust method of room temperature direct arylation for benzofuran is reported. This discovery allows for mild arylation by commercially available aryl iodides with complete C-2 regioselectivity and tolerates a range of functional groups, including heat sensitive groups. Mechanistically, a Heck-type oxyarylation product from a direct arylation process is reported as a key piece of evidence for a carbopalladation intermediate.

Published

2021

21. Recent Advances in Room-Temperature Direct C-H Arylation Methodologies

Author

Christine K. Luscombe, Preeti Yadav, and Nivedha Velmurugan

Subjects

Photocatalyzed, Electrocatalyzed, Organic Chemistry, Direct C-H arylation, transition metal-catalyzed, room temperature, Catalysis, mild reaction conditions

Abstract

In recent decades, direct C–H arylation has become a preferred tool for biaryl coupling over traditional cross-coupling methods owing to its operationally simple protocol, inherent atom and step economy, and reduced metallic waste. Several elegant methods have been developed that offer the facile transformation of usually inert Csp2–H bonds into Csp2–Csp2 bonds in a single synthetic operation. Despite many merits, a major drawback to this chemistry comes from the low reactivity of aryl C–H bonds, which often mandate harsh reaction conditions compromising sustainability. Hence, developing reaction protocols that require milder conditions has become an important goal in this area of research. This review article comprehensively highlights the synthesis and mechanistic aspects of direct C–H arylation reactions, which proceed at or below room temperature.1 Introduction2 Concepts and Examples2.1 Transition-Metal-Catalyzed Procedures2.1.1 Pd Catalysis2.1.2 Other Metal-Based Procedures2.1.3 Additive-Free Procedures2.2 Direct Arylation Polymerization2.3 Photocatalyzed Procedures2.3.1 Organometallic C–H-Activation-Based Procedures2.3.2 Radical-Addition-Based Procedures2.4 Transition-Metal-Free Procedures2.4.1 Base-Mediated Procedures2.4.2 Iodonium- and Diazonium-Salt-Based Procedures2.5 Electrocatalyzed Procedures3 Summary and Outlook

Published

2022

22. Terminology for chain polymerization (IUPAC Recommendations 2021)

Author

Christopher M. Fellows, Richard G. Jones, Daniel J. Keddie, Christine K. Luscombe, John B. Matson, Krzysztof Matyjaszewski, Jan Merna, Graeme Moad, Tamaki Nakano, Stanislaw Penczek, Gregory T. Russell, and Paul D. Topham

Subjects

controlled polymerization, radical, coordination, living polymerization, General Chemical Engineering, insertion polymerization, General Chemistry, catalyst-transfer, radical polymerization, reverible deactivation polymerization, chain polymerization, anionic, coordination polymerization, group transfer polymerization, cationic, ionic polymerization

Abstract

Chain polymerizations are defined as chain reactions where the propagation steps occur by reaction between monomer(s) and active site(s) on the polymer chains with regeneration of the active site(s) at each step. Many forms of chain polymerization can be distinguished according to the mechanism of the propagation step (e.g., cyclopolymerization - when rings are formed, condensative chain polymerization - when propagation is a condensation reaction, group-transfer polymerization, polyinsertion, ring-opening polymerization - when rings are opened), whether they involve a termination step or not (e.g., living polymerization - when termination is absent, reversible-deactivation polymerization), whether a transfer step is involved (e.g., degenerative-transfer polymerization), and the type of chain carrier or active site (e.g., radical, ion, electrophile, nucleophile, coordination complex). The objective of this document is to provide a language for describing chain polymerizations that is both readily understandable and self-consistent, and which covers recent developments in this rapidly evolving field. IUPAC [2010-007-1-400] Published version This work was prepared under project 2010-007-1-400 of IUPAC (Funder ID: 10.13039/100006987).

Published

2022

23. A brief guide to polymerization terminology (IUPAC Technical Report)

Author

Christine K. Luscombe, Graeme Moad, Roger C. Hiorns, Richard G. Jones, Daniel J. Keddie, John B. Matson, Jan Merna, Tamaki Nakano, Gregory T. Russell, and Paul D. Topham

Subjects

IUPAC polymer division, General Chemical Engineering, polymer chemistry, General Chemistry

Abstract

The use of self-consistent terminology to describe polymerizations is important for litigation, patents, research and education. Imprecision in these areas can be both costly and confusing. To address this situation the International Union of Pure and Applied Chemistry (IUPAC) has made recommendations, which are summarized below. In the version shown as the supplementary material, references and hyperlinks lead to source documents; screen tips contain definitions published in IUPAC recommendations. More details can also be found in the IUPAC Purple Book. This guide is one of a series on terminology and nomenclature. Refer to the supplementary material for the complete and interactive version of this brief guide.

Published

2022

24. Direct Patterning of Perovskite Nanocrystals on Nanophotonic Cavities with Electrohydrodynamic Inkjet Printing

Author

Theodore A. Cohen, David Sharp, Kyle T. Kluherz, Yueyang Chen, Christopher Munley, Rayne T. Anderson, Connor J. Swanson, James J. De Yoreo, Christine K. Luscombe, Arka Majumdar, Daniel R. Gamelin, and J. Devin Mackenzie

Subjects

Mechanical Engineering, General Materials Science, Bioengineering, General Chemistry, Condensed Matter Physics

Abstract

Overcoming the challenges of patterning luminescent materials will unlock additive and more sustainable paths for the manufacturing of next-generation on-chip photonic devices. Electrohydrodynamic (EHD) inkjet printing is a promising method for deterministically placing emitters on these photonic devices. However, the use of this technique to pattern luminescent lead halide perovskite nanocrystals (NCs), notable for their defect tolerance and impressive optical and spin coherence properties, for integration with optoelectronic devices remains unexplored. In this work, we additively deposit nanoscale CsPbBr

Published

2022

25. In Situ Studies of the Swelling by an Electrolyte in Electrochemical Doping of Ethylene Glycol-Substituted Polythiophene

Author

Lucas Q. Flagg, Lauren E. Asselta, Nicholas D’Antona, Tommaso Nicolini, Natalie Stingelin, Jonathan W. Onorato, Christine K. Luscombe, Ruipeng Li, and Lee J. Richter

Subjects

General Materials Science

Abstract

Organic mixed ionic electronic conductors (OMIECs) have the potential to enable diverse new technologies, ranging from biosensors to flexible energy storage devices and neuromorphic computing platforms. However, a study of these materials in their operating state, which convolves both passive and potential-driven solvent, cation, and anion ingress, is extremely difficult, inhibiting rational material design. In this report, we present a novel approach to the in situ studies of the electrochemical switching of a prototypical OMIEC based on oligoethylene glycol (oEG) substitution of semicrystalline regioregular polythiophene via grazing-incidence X-ray scattering. By studying the crystal lattice both dry and in contact with the electrolyte while maintaining potential control, we can directly observe the evolution of the crystalline domains and their relationship to film performance in an electrochemically gated transistor. Despite the oEG side-chain enabling bulk electrolyte uptake, we find that the crystalline regions are relatively hydrophobic, exhibiting little (less than one water per thiophene) swelling of the undoped polymer, suggesting that the amorphous regions dominate the reported passive swelling behavior. With applied potential, we observe that the π-π separation in the crystals contracts while the lamella spacing increases in a balanced fashion, resulting in a negligible change in the crystal volume. The potential-induced changes in the crystal structure do not clearly correlate to the electrical performance of the film as an organic electrochemical transistor, suggesting that the transistor performance is strongly influenced by the amorphous regions of the film.

Published

2022

26. Modular Zwitterion-Functionalized Poly(isopropyl methacrylate) Polymers for Hosting Luminescent Lead Halide Perovskite Nanocrystals

Author

Connor S. Juhl, Christine K. Luscombe, Yunping Huang, Nico A. Bricker, Theodore A. Cohen, Tyler J. Milstein, Daniel R. Gamelin, and J. Devin MacKenzie

Subjects

Materials science, General Chemical Engineering, Halide, 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, Photochemistry, 01 natural sciences, 0104 chemical sciences, Methacrylate polymers, chemistry.chemical_compound, Nanocrystal, chemistry, Zwitterion, Materials Chemistry, 0210 nano-technology, Luminescence, Inorganic lead, Isopropyl, Perovskite (structure)

Abstract

Inorganic lead halide perovskite nanocrystals (NCs) are an exciting class of luminescent materials with high defect tolerance and broad spectral tunability, but such NCs are vulnerable to degradati...

Published

2021

27. Macromolecular Science Turns 100

Author

Gregory T. Russell and Christine K. Luscombe

Subjects

Polymer science, Philosophy, 02 engineering and technology, General Medicine, 010402 general chemistry, 021001 nanoscience & nanotechnology, 0210 nano-technology, 01 natural sciences, 0104 chemical sciences

Abstract

Being 100 years since the birth of macromolecular science, 2020 was meant to be the “Year of Polymers,” but instead it turned into the year of the pandemic. Actually the two are not unrelated —most PPE is made of polymer, and without it the health-care response to COVID-19 would have looked completely different and been far more treacherous. But that’s another story, one with which the IUPAC Polymer Division is engaging [1]. Here is the story behind the centenary year that wasn’t. It all centers on Hermann Staudinger, who changed everything in 1920.

Published

2021

28. Theoretical background on semiconducting polymers and their applications to OSCs and OLEDs

Author

Uday Maitra, Michael G. Walter, Christine K. Luscombe, Susanne K. Wiedmer, Department of Chemistry, Helsinki Institute of Sustainability Science (HELSUS), and Susanne Wiedmer / Principal Investigator

Subjects

Organic electronics, chemistry.chemical_classification, Materials science, 515 Psychology, business.industry, education, 116 Chemical sciences, 02 engineering and technology, Polymer, 010402 general chemistry, 021001 nanoscience & nanotechnology, 7. Clean energy, 01 natural sciences, 0104 chemical sciences, Education, law.invention, chemistry, Chemistry (miscellaneous), law, OLED, Optoelectronics, 0210 nano-technology, business, Light-emitting diode

Abstract

Organic electronics has developed rapidly over the past 40 years. In 1977, a seminal discovery was reported that showed that a polymer known as polyacetylene could conduct electricity as well as metals could. This was a groundbreaking discovery that led to a Nobel Prize in Chemistry in 2000. The polymers that are used in organic electronics have now been widely studied for use in organic solar cells (OSCs), organic field effect transistors (OFETs), printable electronics, flexible electronics, antistatic coatings, actuators, and more recently in bioelectronics. In particular, the utility of organic electronics is seen in the commercial success of using organic electronic materials in organic light-emitting diodes (OLEDs) where OLED displays can be seen in mobile phones and as flat panel displays. In this paper, we provide a tutorial targeting upper secondary students describing how these special classes of polymers function, and how they can be synthesized. The paper further discusses the use of these materials in two applications: organic solar cells and organic light-emitting diodes. The paper ends with a brief discussion about hands-on activities that can be carried out in the upper secondary student science classroom.

Published

2021

29. Complex Relationship between Side-Chain Polarity, Conductivity, and Thermal Stability in Molecularly Doped Conjugated Polymers

Author

Christian Nowak, Christine K. Luscombe, Shrayesh N. Patel, Oleg G. Poluektov, Jens Niklas, Garrett Grocke, Mark DiTusa, Tengzhou Ma, Fernando A. Escobedo, Jonathan W. Onorato, Ban Xuan Dong, and Paul F. Nealey

Subjects

chemistry.chemical_classification, Materials science, Polarity (physics), General Chemical Engineering, Doping, 02 engineering and technology, General Chemistry, Polymer, Conductivity, Conjugated system, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Crystallography, chemistry, Materials Chemistry, Side chain, Polar, Thermal stability, 0210 nano-technology

Abstract

Molecularly doped conjugated polymers with polar side chains are an emerging class of conducting materials exhibiting enhanced and thermally stable conductivity. Here, we study the electronic condu...

Published

2021

30. Side chain engineering control of mixed conduction in oligoethylene glycol-substituted polythiophenes

Author

Christine K. Luscombe, Ban Xuan Dong, Paul F. Nealey, Christian Nowak, Fernando A. Escobedo, Lucas Q. Flagg, Ruipeng Li, Shrayesh N. Patel, Jonathan W. Onorato, Lee J. Richter, Yangyang Sun, and Zhongyang Wang

Subjects

chemistry.chemical_classification, Materials science, Renewable Energy, Sustainability and the Environment, Ionic bonding, chemistry.chemical_element, General Chemistry, Polymer, Thermal conduction, chemistry.chemical_compound, chemistry, Chemical engineering, Side chain, Thiophene, Ionic conductivity, Polythiophene, General Materials Science, Lithium

Abstract

A major limitation for polymeric mixed ionic/electronic conductors (MIECs) is the trade-off between ionic and electronic conductivity; changes made that improve one typically hinder the other. In order to address this fundamental problem, this work provides insight into ways that we could improve one type of conduction without hindering the other. We investigated a common oligoethylene glycol side chain polymer by adjusting the oxygen atom content and position, providing structural insights for materials that better balanced the two conduction pathways. The investigated polymer series showed the prototypical conflict between ionic and electronic conduction for oxygen atom content, with increasing oxygen atom content increasing ionic conductivity, but decreasing electronic conductivity; however, by increasing the oxygen atom distance from the polymer backbone, both ionic and electronic conductivity could be improved. Following these rules, we show that poly(3-(methoxyethoxybutyl)thiophene), when blended with lithium bistrifluoromethanesulfonimide (LiTFSI), matches the ionic conductivity of a comparable MIEC [poly(3-(methoxyethoxyethoxymethyl)thiophene)], while simultaneously showing higher electronic conductivity, highlighting the potential of this design strategy. We also provide strategies for tuning the MIEC performance to fit a desired application, depending on if electronic, ionic, or balanced conduction is most important. These results have implications beyond just polythiophene-based MIECs, as these strategies for balancing backbone crystallization and coordinating group interconnectivity apply for all semicrystalline conjugated polymers.

Published

2021

31. Green syntheses of stable and efficient organic dyes for organic hybrid light-emitting diodes

Author

Theodore A. Cohen, Christine K. Luscombe, Parker J. W. Sommerville, and Yunping Huang

Subjects

chemistry.chemical_classification, Materials science, Photoluminescence, Composite number, Phosphor, General Chemistry, Polymer, Waveguide (optics), law.invention, chemistry, Chemical engineering, law, Materials Chemistry, Solubility, Diode, Light-emitting diode

Abstract

Organic hybrid light-emitting diodes (hybrid-LEDs) employ organic dyes as light converters on top of commercial blue inorganic LEDs, replacing incumbent inorganic phosphor light converters synthesized from rare-earth and/or toxic metallic elements to optimize device environmental sustainability. Here, we present two naturally derived organic dyes for hybrid-LEDs, highlighting stability and efficiency enhancement based on a novel “acceptor–acceptor” molecular design. This “acceptor–acceptor” skeleton comprises theobromine and thiadiazole, two electron-withdrawing groups that lower energy levels and suppress photooxidation. This differentiates these dyes from the widely adopted “donor–acceptor” skeleton, where photooxidation is facilitated by the presence of electron-donating units. Simultaneously, sidechains on organic dyes used to enhance solution processability, crucial for film transparency, introduce an additional photooxidation pathway. With this “acceptor–acceptor” skeleton, the destabilization from sidechains was offset by the stability enhancement from the electronic effects in the backbone. When blended within an industrial polymer, poly(styrene-butadiene-styrene) (SBS), their enhanced solubility enables the formation of highly transparent films, crucial for reducing scattering loss in LEDs. Furthermore, resultant dye-SBS films achieved photoluminescence quantum yields (PLQYs) of around 90% under ambient conditions. Taking advantage of their transparency and solution processability, we fabricated a waveguide with this theobromine-dye-SBS composite, which was subsequentially assembled into an edge-lit LED device of no glare and enhanced aesthetics.

Published

2021

32. Ligand Pyrolysis during Air-Free Inorganic Nanocrystal Synthesis

Author

Breena M. Sperry and Christine K. Luscombe

Subjects

Steric effects, Ligand, General Chemical Engineering, General Chemistry, Metal, chemistry.chemical_compound, Nanocrystal, chemistry, Oleylamine, visual_art, Polymer chemistry, Materials Chemistry, visual_art.visual_art_medium, Pyrolysis

Abstract

Oleylamine (OLA) is a ubiquitous organic ligand used in the synthesis of inorganic nanocrystals (NCs) due to its ability to reduce metal precursors and sterically stabilize NCs. However, attempts t...

Published

2020

33. Gaining control over conjugated polymer morphology to improve the performance of organic electronics

Author

Nadzeya A. Kukhta and Christine K. Luscombe

Subjects

Materials Chemistry, Metals and Alloys, Ceramics and Composites, General Chemistry, Catalysis, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials

Abstract

Conjugated polymers (CPs) are widely used in various domains of organic electronics. However, the performance of organic electronic devices can be variable due to the lack of precise predictive control over the polymer microstructure. While the chemical structure of CPs is important, CP microstructure also plays an important role in determining the charge-transport, optical and mechanical properties suitable for a target device. Understanding the interplay between CP microstructure and the resulting properties, as well as predicting and targeting specific polymer morphologies, would allow current comprehension of organic electronic device performance to be improved and potentially enable more facile device optimization and fabrication. In this Feature Article, we highlight the importance of investigating CP microstructure, discuss previous developments in the field, and provide an overview of the key aspects of the CP microstructure-property relationship, carried out in our group over recent years.

Published

2022

34. Constructing Regioregular Star Poly(3-hexylthiophene) via Externally Initiated Kumada Catalyst-Transfer Polycondensation

Author

Christine K. Luscombe, Mingjian Yuan, Hugo Bronstein, and Ken Okamoto

Subjects

Inorganic Chemistry, Biphenyl, chemistry.chemical_compound, Condensation polymer, Polymers and Plastics, Chemistry, Organic Chemistry, Polymer chemistry, Materials Chemistry, Reactivity (chemistry), Catalysis

Abstract

A synthetic route was developed for the preparation of di- and trifunctional Ni complex-based initiators. Each initiator affords well-defined 2-arm (V-shaped) and 3-arm (Y-shaped) regioregular poly(3-hexylthiophene) (rr-P3HT) with controlled molecular weight and narrow polydispersities by the externally initiated Kumada catalyst-transfer polycondensation. The core spacer length and end o-tolylhalide group of the functional initiators exhibited differences in reactivity and show that the biphenyl spacers are effective for the synthesis of V-shaped and Y-shaped rr-P3HTs.

Published

2022

35. Impact of varying side chain structure on organic electrochemical transistor performance: a series of oligoethylene glycol-substituted polythiophenes

Author

Shinya E. Chen, Lucas Q. Flagg, Jonathan W. Onorato, Lee J. Richter, Jiajie Guo, Christine K. Luscombe, and David S. Ginger

Subjects

Renewable Energy, Sustainability and the Environment, General Materials Science, General Chemistry

Abstract

The electrochemical doping/dedoping kinetics, and the organic electrochemical transistor (OECT) performance of a series of polythiophene homopolymers with ethylene glycol units in their side chains using both kosmotropic and chaotropic anion solutions were studied. We compare their performance to a reference polymer, the polythiophene derivative with diethylene glycol side chains, poly(3-{[2-(2-methoxyethoxy)ethoxy]methyl}thiophene-2,5-diyl) (P3MEEMT). We find larger OECT material figure of merit, μC*, where μ is the carrier mobility and C* is the volumetric capacitance, and faster doping kinetics with more oxygen atoms on the side chains, and if the oxygen atom is farther from the polythiophene backbone. Replacing the oxygen atom close to the polythiophene backbone with an alkyl unit increases the film π-stacking crystallinity (higher electronic conductivity in the undoped film) but sacrifices the available doping sites (lower volumetric capacitance C* in OECT). We show that this variation in C* is the dominant factor in changing the μC* product for this family of polymers. With more oxygen atoms on the side chain, or with the oxygen atom farther from the polymer backbone, we observe both more passive swelling and higher C*. In addition, we show that, compared to the doping speed, the dedoping speed, as measured via spectroelectrochemistry, is both generally faster and less dependent on ion species or side chain oxygen content. Last, through OECT, electrochemical impedance spectroscopy (EIS) and spectroelectrochemistry measurements, we show that the chaotropic anion PF6− facilitates higher doping levels, faster doping kinetics, and lower doping thresholds compared to the kosmotropic anion Cl−, although the exact differences depend on the polymer side chains. Our results highlight the importance of balancing μ and C* when designing molecular structures for OECT active layers.

Published

2022

36. Terminology for chain polymerization (IUPAC Recommendations 2021)

Author

Christopher M., Fellows, Richard G., Jones, Daniel J., Keddie, Christine K., Luscombe, John B., Matson, Krzysztof, Matyjaszewski, Jan, Merna, Graeme, Moad, Tamaki, Nakano, Stanislaw, Penczek, Gregory T., Russell, Paul D., Topham, Christopher M., Fellows, Richard G., Jones, Daniel J., Keddie, Christine K., Luscombe, John B., Matson, Krzysztof, Matyjaszewski, Jan, Merna, Graeme, Moad, Tamaki, Nakano, Stanislaw, Penczek, Gregory T., Russell, and Paul D., Topham

Abstract

Chain polymerizations are defined as chain reactions where the propagation steps occur by reaction between monomer(s) and active site(s) on the polymer chains with regeneration of the active site(s) at each step. Many forms of chain polymerization can be distinguished according to the mechanism of the propagation step (e.g., cyclopolymerization – when rings are formed, condensative chain polymerization – when propagation is a condensation reaction, group-transfer polymerization, polyinsertion, ring-opening polymerization – when rings are opened), whether they involve a termination step or not (e.g., living polymerization – when termination is absent, reversible-deactivation polymerization), whether a transfer step is involved (e.g., degenerative-transfer polymerization), and the type of chain carrier or active site (e.g., radical, ion, electrophile, nucleophile, coordination complex). The objective of this document is to provide a language for describing chain polymerizations that is both readily understandable and self-consistent, and which covers recent developments in this rapidly evolving field., source:https://www.degruyter.com/document/doi/10.1515/pac-2020-1211/html

Published

2022

37. Molecular Design Strategies toward Improvement of Charge Injection and Ionic Conduction in Organic Mixed Ionic–Electronic Conductors for Organic Electrochemical Transistors

Author

Nadzeya A., Kukhta, Adam, Marks, Christine K., Luscombe, Nadzeya A., Kukhta, Adam, Marks, and Christine K., Luscombe

Abstract

Expanding the toolbox of the biology and electronics mutual conjunction is a primary aim of bioelectronics. The organic electrochemical transistor (OECT) has undeniably become a predominant device for mixed conduction materials, offering impressive transconduction properties alongside a relatively simple device architecture. In this review, we focus on the discussion of recent material developments in the area of mixed conductors for bioelectronic applications by means of thorough structure–property investigation and analysis of current challenges. Fundamental operation principles of the OECT are revisited, and characterization methods are highlighted. Current bioelectronic applications of organic mixed ionic–electronic conductors (OMIECs) are underlined. Challenges in the performance and operational stability of OECT channel materials as well as potential strategies for mitigating them, are discussed. This is further expanded to sketch a synopsis of the history of mixed conduction materials for both p- and n-type channel operation, detailing the synthetic challenges and milestones which have been overcome to frequently produce higher performing OECT devices. The cumulative work of multiple research groups is summarized, and synthetic design strategies are extracted to present a series of design principles that can be utilized to drive figure-of-merit performance values even further for future OMIEC materials., source:https://pubs.acs.org/doi/10.1021/acs.chemrev.1c00266

Published

2022

38. The effect of side chain engineering on conjugated polymers in organic electrochemical transistors for bioelectronic applications

Author

Yifei, He, Nadzeya A., Kukhta, Adam, Marks, Christine K., Luscombe, Yifei, He, Nadzeya A., Kukhta, Adam, Marks, and Christine K., Luscombe

Abstract

Bioelectronics focuses on the establishment of the connection between the ion-driven biosystems and readable electronic signals. Organic electrochemical transistors (OECTs) offer a viable solution for this task. Organic mixed ionic/electronic conductors (OMIECs) rest at the heart of OECTs. The balance between the ionic and electronic conductivities of OMIECs is closely connected to the OECT device performance. While modification of the OMIECs’ electronic properties is largely related to the development of conjugated scaffolds, properties such as ion permeability, solubility, flexibility, morphology, and sensitivity can be altered by side chain moieties. In this review, we uncover the influence of side chain molecular design on the properties and performance of OECTs. We summarise current understanding of OECT performance and focus specifically on the knowledge of ionic–electronic coupling, shedding light on the significance of side chain development of OMIECs. We show how the versatile synthetic toolbox of side chains can be successfully employed to tune OECT parameters via controlling the material properties. As the field continues to mature, more detailed investigations into the crucial role side chain engineering plays on the resultant OMIEC properties will allow for side chain alternatives to be developed and will ultimately lead to further enhancements within the field of OECT channel materials., source:https://pubs.rsc.org/en/content/articlelanding/2022/tc/d1tc05229b

Published

2022

39. Gaining control over conjugated polymer morphology to improve the performance of organic electronics

Author

Nadzeya A., Kukhta, Christine K., Luscombe, Nadzeya A., Kukhta, and Christine K., Luscombe

Abstract

Conjugated polymers (CPs) are widely used in various domains of organic electronics. However, the performance of organic electronic devices can be variable due to the lack of precise predictive control over the polymer microstructure. While the chemical structure of CPs is important, CP microstructure also plays an important role in determining the charge-transport, optical and mechanical properties suitable for a target device. Understanding the interplay between CP microstructure and the resulting properties, as well as predicting and targeting specific polymer morphologies, would allow current comprehension of organic electronic device performance to be improved and potentially enable more facile device optimization and fabrication. In this Feature Article, we highlight the importance of investigating CP microstructure, discuss previous developments in the field, and provide an overview of the key aspects of the CP microstructure-property relationship, carried out in our group over recent years., source:https://pubs.rsc.org/en/content/articlelanding/2022/CC/D2CC01430K

Published

2022

40. Circular Discovery in Small Molecule and Conjugated Polymer Synthetic Methodology

Author

Amy L., Mayhugh, Preeti, Yadav, Christine K., Luscombe, Amy L., Mayhugh, Preeti, Yadav, and Christine K., Luscombe

Abstract

Simple and efficient methods are a key consideration for small molecule and polymer syntheses. Direct arylation polymerization (DArP) is of increasing interest for preparing conjugated polymers as an effective approach compared to conventional cross-coupling polymerizations. As DArP sees broader utilization, advancements are needed to access materials with improved properties and different monomer structures and to improve the scalability of conjugated polymer synthesis. Presented herein are considerations for developing new methods of conjugated polymer synthesis from small molecule transformations, exploring how DArP has successfully used this approach, and presenting how emerging polymerization methodologies are developing similarly. While it is common to adapt small molecule methods to polymerizations, we demonstrate the ways in which information gained from studying polymerizations can inform and inspire greater advancements in small molecule transformations. This circular approach to organic synthetic method development underlines the value of collaboration between small molecule and polymer-based synthetic research groups., source:https://pubs.acs.org/doi/10.1021/jacs.1c12455

Published

2022

41. An Exception to the Carothers Equation Caused by the Accelerated Chain Extension in a Pd/Ag Cocatalyzed Cross Dehydrogenative Coupling Polymerization

Author

Liwen, Xing, Ji-Ren, Liu, Xin, Hong, Kendall N., Houk, Christine K., Luscombe, Liwen, Xing, Ji-Ren, Liu, Xin, Hong, Kendall N., Houk, and Christine K., Luscombe

Abstract

The Carothers equation is often used to predict the utility of a small molecule reaction in a polymerization. In this study, we present the mechanistic study of Pd/Ag cocatalyzed cross dehydrogenative coupling (CDC) polymerization to synthesize a donor–acceptor (D–A) polymer of 3,3′-dihexyl-2,2′-bithiophene and 2,2′,3,3′,5,5′,6,6′-octafluorobiphenyl, which go counter to the Carothers equation. It is uncovered that the second chain extension cross-coupling proceeds much more efficiently than the first cross-coupling and the homocoupling side reaction (at least 1 order of magnitude faster) leading to unexpectedly low homocoupling defects and high molecular weight polymers. Kinetic analyses show that C–H bond activation is rate-determining in the first cross-coupling but not in the second cross-coupling. Based on DFT calculations, the high cross-coupling rate in the second cross-coupling was ascribed to the strong Pd-thiophene interaction in the Pd-mediated C–H bond activation transition state, which decreases the energy barrier of the Pd-mediated C–H bond activation. These results have implications beyond polymerizations and can be used to ease the synthesis of a wide range of molecules where C–H bond activation may be the limiting factor., source:https://pubs.acs.org/doi/10.1021/jacs.1c12599

Published

2022

42. Structural and Morphological Characterization of Novel Organic Electrochemical Transistors via Four-dimensional (4D) Scanning Transmission Electron Microscopy

Author

Christine K. Luscombe, Andrew A. Herzing, Lucas Q. Flagg, Lee J. Richter, and Jonathan Ontorato

Subjects

Materials science, business.industry, law, Scanning transmission electron microscopy, Transistor, Optoelectronics, business, Electrochemistry, Instrumentation, law.invention, Characterization (materials science)

Published

2021

43. Terminology of polymers in advanced lithography (IUPAC Recommendations 2020)

Author

Christopher K. Ober, Richard G. Jones, Natalie Stingelin, Christine K. Luscombe, and Teruaki Hayakawa

Subjects

chemistry.chemical_classification, chemistry, 010405 organic chemistry, General Chemical Engineering, Chemical nomenclature, Nanotechnology, General Chemistry, Polymer, 010402 general chemistry, 01 natural sciences, Lithography, 0104 chemical sciences, Terminology

Abstract

As increasingly smaller molecular materials and material structures are devised or developed for technological applications, the demands on the processes of lithography now routinely include feature sizes that are of the order of 10 nm. In reaching such a fine level of resolution, the methods of lithography have increased markedly in sophistication and brought into play 2terminology that is unfamiliar, on the one hand, to scientists tasked with the development of new lithographic materials or, on the other, to the engineers who design and operate the complex equipment that is required in modern-day processing. Publications produced by scientists need to be understood by engineers and vice versa, and these commonly arise from collaborative research that draws heavily on the terminology of two or more of the traditional disciplines. It is developments in polymer science and material science that lead progress in areas that cross traditional boundaries, such as microlithography. This document provides the exact definitions of a selection of unfamiliar terms that researchers and practitioners from different disciplines might encounter.

Published

2020

44. Elucidating the Influence of Side-Chain Circular Distribution on the Crack Onset Strain and Hole Mobility of Near-Amorphous Indacenodithiophene Copolymers

Author

Parker J. W. Sommerville, Yongcao Zhang, Shrayesh N. Patel, Natalie Stingelin, Jonathan W. Onorato, Alex H. Balzer, Ban Xuan Dong, Paul F. Nealey, Yilin Li, Wesley K. Tatum, and Christine K. Luscombe

Subjects

Electron mobility, Morphology (linguistics), Materials science, genetic structures, Polymers and Plastics, Strain (chemistry), Circular distribution, Organic Chemistry, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Amorphous solid, Inorganic Chemistry, Brittleness, Materials Chemistry, Copolymer, Side chain, Composite material, 0210 nano-technology

Abstract

Poly(indacenodithiophene-benzothiadiazole) has received significant interest because of its exceptional hole mobility despite its near-amorphous thin-film morphology and brittleness at low Mn. In c...

Published

2020

45. A Reversible Structural Phase Transition by Electrochemically-Driven Ion Injection into a Conjugated Polymer

Author

Lucas Q. Flagg, Christine K. Luscombe, Connor G. Bischak, Tahir Rehman, Chang-Zhi Li, Jonathan W. Onorato, Ramsess J. Quezada, Daniel W. Davies, David S. Ginger, Ying Diao, and Kangrong Yan

Subjects

chemistry.chemical_classification, Structural phase, Colloid and Surface Chemistry, chemistry, Ion injection, General Chemistry, Polymer, Conjugated system, Photochemistry, Electrochemistry, Biochemistry, Catalysis

Abstract

We find that conjugated polymers can undergo reversible structural phase transitions during electrochemical oxidation and ion injection. We study poly[2,5-bis(thiophenyl)-1,4-bis(2-(2-(2-methoxyethoxy)ethoxy)ethoxy)benzene] (PB2T-TEG), a conjugated polymer with glycolated side chains. Using grazing incidence wide-angle X-ray scattering (GIWAXS), we show that, in contrast to previously known polymers, this polymer switches between two structurally distinct crystalline phases associated with electrochemical oxidation/reduction in an aqueous electrolyte. Importantly, we show that this unique phase change behavior has important physical consequences for ion-polaron pair transport. Notably, using moving front experiments visualized by both optical microscopy and super-resolution photoinduced force microscopy (PiFM), we show that a laterally propagating ion-polaron pair front in PB2T-TEG exhibits non-Fickian transport, retaining a sharp step-edge profile, in stark contrast to the Fickian diffusion more commonly observed in polymers like P3MEEMT. This structural phase transition is reminiscent of those accompanying ion uptake in inorganic materials like LiFePO

Published

2020

46. P-Type Electrochemical Doping Can Occur by Cation Expulsion in a High-Performing Polymer for Organic Electrochemical Transistors

Author

Lucas Q. Flagg, Jonathan W. Onorato, Connor G. Bischak, David S. Ginger, Ramsess J. Quezada, and Christine K. Luscombe

Subjects

chemistry.chemical_classification, Materials science, General Chemical Engineering, Transistor, Doping, Biomedical Engineering, Ionic bonding, Polymer, Electrochemistry, law.invention, Electrochemical doping, Polythiophene derivative, chemistry, Chemical engineering, law, General Materials Science, Charge compensation

Abstract

We investigate the mechanism of ion-dependent charge compensation during electrochemical oxidation (doping) of the model mixed ionic/electronic transporting polythiophene derivative poly(3-{[2-(2-m...

Published

2020

47. The sustainable materials roadmap

Author

Magda Titirici, Sterling G Baird, Taylor D Sparks, Shirley Min Yang, Agnieszka Brandt-Talbot, Omid Hosseinaei, David P Harper, Richard M Parker, Silvia Vignolini, Lars A Berglund, Yuanyuan Li, Huai-Ling Gao, Li-Bo Mao, Shu-Hong Yu, Noel Díez, Guillermo A Ferrero, Marta Sevilla, Petra Ágota Szilágyi, Connor J Stubbs, Joshua C Worch, Yunping Huang, Christine K Luscombe, Koon-Yang Lee, Hui Luo, M J Platts, Devendra Tiwari, Dmitry Kovalevskiy, David J Fermin, Heather Au, Hande Alptekin, Maria Crespo-Ribadeneyra, Valeska P Ting, Tim-Patrick Fellinger, Jesús Barrio, Olivia Westhead, Claudie Roy, Ifan E L Stephens, Sabina Alexandra Nicolae, Saurav Ch Sarma, Rose P Oates, Chen-Gang Wang, Zibiao Li, Xian Jun Loh, Rupert J Myers, Niko Heeren, Alice Grégoire, Clément Périssé, Xiaoying Zhao, Yael Vodovotz, Becky Earley, Göran Finnveden, Anna Björklund, Gavin D J Harper, Allan Walton, Paul A Anderson, Díez Nogués, Noel, Álvarez Ferrero, Guillermo, Sevilla Solís, Marta, Titirici, M [0000-0003-0773-2100], Baird, SG [0000-0002-4491-6876], Sparks, TD [0000-0001-8020-7711], Yang, SM [0000-0003-4989-7210], Brandt-Talbot, A [0000-0002-5805-0233], Parker, RM [0000-0002-4096-9161], Vignolini, S [0000-0003-0664-1418], Berglund, LA [0000-0001-5818-2378], Li, Y [0000-0002-1591-5815], Díez, N [0000-0002-6072-8947], Ferrero, GA [0000-0001-8606-781X], Sevilla, M [0000-0002-2471-2403], Worch, JC [0000-0002-4354-8303], Lee, KY [0000-0003-0777-2292], Luo, H [0000-0002-5876-0294], Tiwari, D [0000-0001-8225-0000], Fermin, DJ [0000-0002-0376-5506], Au, H [0000-0002-1652-2204], Alptekin, H [0000-0001-6065-0513], Crespo-Ribadeneyra, M [0000-0001-6455-4430], Ting, VP [0000-0003-3049-0939], Fellinger, TP [0000-0001-6332-2347], Barrio, J [0000-0002-4147-2667], Stephens, IEL [0000-0003-2157-492X], Sarma, SC [0000-0002-6941-9702], Oates, RP [0000-0002-2513-7666], Wang, CG [0000-0001-6986-3961], Li, Z [0000-0002-0591-5328], Loh, XJ [0000-0001-8118-6502], Zhao, X [0000-0003-3709-3143], Harper, GDJ [0000-0002-4691-6642], Walton, A [0000-0001-8608-7941], Anderson, PA [0000-0002-0613-7281], Apollo - University of Cambridge Repository, Titirici, Maria-Magdalena [0000-0003-0773-2100], Parker, Richard [0000-0002-4096-9161], Vignolini, Silvia [0000-0003-0664-1418], Fermin, David [0000-0002-0376-5506], Ting, Valeska [0000-0003-3049-0939], Loh, Xian Jun [0000-0001-8118-6502], Engineering and Physical Sciences Research Council, Engineering & Physical Science Research Council (EPSRC), Titirici, Magda [0000-0003-0773-2100], Baird, Sterling G [0000-0002-4491-6876], Sparks, Taylor D [0000-0001-8020-7711], Yang, Shirley Min [0000-0003-4989-7210], Brandt-Talbot, Agnieszka [0000-0002-5805-0233], Parker, Richard M [0000-0002-4096-9161], Berglund, Lars A [0000-0001-5818-2378], Li, Yuanyuan [0000-0002-1591-5815], Díez, Noel [0000-0002-6072-8947], Ferrero, Guillermo A [0000-0001-8606-781X], Sevilla, Marta [0000-0002-2471-2403], Worch, Joshua C [0000-0002-4354-8303], Lee, Koon-Yang [0000-0003-0777-2292], Luo, Hui [0000-0002-5876-0294], Tiwari, Devendra [0000-0001-8225-0000], Fermin, David J [0000-0002-0376-5506], Au, Heather [0000-0002-1652-2204], Alptekin, Hande [0000-0001-6065-0513], Crespo-Ribadeneyra, Maria [0000-0001-6455-4430], Ting, Valeska P [0000-0003-3049-0939], Fellinger, Tim-Patrick [0000-0001-6332-2347], Barrio, Jesús [0000-0002-4147-2667], Stephens, Ifan E L [0000-0003-2157-492X], Sarma, Saurav Ch [0000-0002-6941-9702], Oates, Rose P [0000-0002-2513-7666], Wang, Chen-Gang [0000-0001-6986-3961], Li, Zibiao [0000-0002-0591-5328], Zhao, Xiaoying [0000-0003-3709-3143], Harper, Gavin D J [0000-0002-4691-6642], Walton, Allan [0000-0001-8608-7941], and Anderson, Paul A [0000-0002-0613-7281]

Subjects

Technology, CELLULOSE NANOCRYSTALS, Science & Technology, research, Materials Science, INDUSTRIAL ECOLOGY, H900, Materials Science, Multidisciplinary, MECHANICAL-PROPERTIES, Condensed Matter Physics, Atomic and Molecular Physics, and Optics, ENVIRONMENTAL-IMPACT, materials, project, DIRECT (HETERO)ARYLATION POLYMERIZATION, POROUS CARBON, sustainable materials, ACTIVE-SITES, BIO-BASED PLASTICS, General Materials Science, ION BATTERIES, sustainable, Topical Review, CONJUGATED POLYMERS

Abstract

Over the past 150 years, our ability to produce and transform engineered materials has been responsible for our current high standards of living, especially in developed economies. However, we must carefully think of the effects our addiction to creating and using materials at this fast rate will have on the future generations. The way we currently make and use materials detrimentally affects the planet Earth, creating many severe environmental problems. It affects the next generations by putting in danger the future of the economy, energy, and climate. We are at the point where something must drastically change, and it must change now. We must create more sustainable materials alternatives using natural raw materials and inspiration from nature while making sure not to deplete important resources, i.e. in competition with the food chain supply. We must use less materials, eliminate the use of toxic materials and create a circular materials economy where reuse and recycle are priorities. We must develop sustainable methods for materials recycling and encourage design for disassembly. We must look across the whole materials life cycle from raw resources till end of life and apply thorough life cycle assessments (LCAs) based on reliable and relevant data to quantify sustainability. We need to seriously start thinking of where our future materials will come from and how could we track them, given that we are confronted with resource scarcity and geographical constrains. This is particularly important for the development of new and sustainable energy technologies, key to our transition to net zero. Currently ‘critical materials’ are central components of sustainable energy systems because they are the best performing. A few examples include the permanent magnets based on rare earth metals (Dy, Nd, Pr) used in wind turbines, Li and Co in Li-ion batteries, Pt and Ir in fuel cells and electrolysers, Si in solar cells just to mention a few. These materials are classified as ‘critical’ by the European Union and Department of Energy. Except in sustainable energy, materials are also key components in packaging, construction, and textile industry along with many other industrial sectors. This roadmap authored by prominent researchers working across disciplines in the very important field of sustainable materials is intended to highlight the outstanding issues that must be addressed and provide an insight into the pathways towards solving them adopted by the sustainable materials community. In compiling this roadmap, we hope to aid the development of the wider sustainable materials research community, providing a guide for academia, industry, government, and funding agencies in this critically important and rapidly developing research space which is key to future sustainability., The authors would like to thank The Faraday Institution ReLiB Project Grant Numbers FIRG005 and FIRG006, the UKRI Interdisciplinary Circular Economy Centre for Technology Metals (Met4Tech) Grant No. EP/V011855/1 and the EPSRC Critical Elements and Materials Network (CREAM) EP/R020140/1 for providing financial assistance for this research.

Published

2022

48. Consensus statement: Standardized reporting of power-producing luminescent solar concentrator performance

Author

Chenchen Yang, Harry A. Atwater, Marc A. Baldo, Derya Baran, Christopher J. Barile, Miles C. Barr, Matthew Bates, Moungi G. Bawendi, Matthew R. Bergren, Babak Borhan, Christoph J. Brabec, Sergio Brovelli, Vladimir Bulović, Paola Ceroni, Michael G. Debije, Jose-Maria Delgado-Sanchez, Wen-Ji Dong, Phillip M. Duxbury, Rachel C. Evans, Stephen R. Forrest, Daniel R. Gamelin, Noel C. Giebink, Xiao Gong, Gianmarco Griffini, Fei Guo, Christopher K. Herrera, Anita W.Y. Ho-Baillie, Russell J. Holmes, Sung-Kyu Hong, Thomas Kirchartz, Benjamin G. Levine, Hongbo Li, Yilin Li, Dianyi Liu, Maria A. Loi, Christine K. Luscombe, Nikolay S. Makarov, Fahad Mateen, Raffaello Mazzaro, Hunter McDaniel, Michael D. McGehee, Francesco Meinardi, Amador Menéndez-Velázquez, Jie Min, David B. Mitzi, Mehdi Moemeni, Jun Hyuk Moon, Andrew Nattestad, Mohammad K. Nazeeruddin, Ana F. Nogueira, Ulrich W. Paetzold, David L. Patrick, Andrea Pucci, Barry P. Rand, Elsa Reichmanis, Bryce S. Richards, Jean Roncali, Federico Rosei, Timothy W. Schmidt, Franky So, Chang-Ching Tu, Aria Vahdani, Wilfried G.J.H.M. van Sark, Rafael Verduzco, Alberto Vomiero, Wallace W.H. Wong, Kaifeng Wu, Hin-Lap Yip, Xiaowei Zhang, Haiguang Zhao, Richard R. Lunt, Evans, Rachel [0000-0003-2956-4857], Apollo - University of Cambridge Repository, Integration of Photovoltaic Solar Energy, Energy and Resources, Stimuli-responsive Funct. Materials & Dev., ICMS Core, EIRES Chem. for Sustainable Energy Systems, EIRES System Integration, Yang, CC, Atwater, HA, Baldo, MA, Baran, D, Barile, CJ, Barr, MC, Bates, M, Bawendi, MG, Bergren, MR, Borhan, B, Brabec, CJ, Brovelli, S, Bulovic, V, Ceroni, P, Debije, MG, Delgado-Sanchez, JM, Dong, WJ, Duxbury, PM, Evans, RC, Forrest, SR, Gamelin, DR, Giebink, NC, Gong, X, Griffini, G, Guo, F, Herrera, CK, Ho-Baillie, AWY, Holmes, RJ, Hong, SK, Kirchartz, T, Levine, BG, Li, HB, Li, YL, Liu, DY, Loi, MA, Luscombe, CK, Makarov, NS, Mateen, F, Mazzaro, R, McDaniel, H, McGehee, MD, Meinardi, F, Menendez-Velazquez, A, Min, J, Mitzi, DB, Moemeni, M, Moon, JH, Nattestad, A, Nazeeruddin, MK, Nogueira, AF, Paetzold, UW, Patrick, DL, Pucci, A, Rand, BP, Reichmanis, E, Richards, BS, Roncali, J, Rosei, F, Schmidt, TW, So, F, Tu, CC, Vahdani, A, van Sark, WGJHM, Verduzco, R, Vomiero, A, Wong, WWH, Wu, KF, Yip, HL, Zhang, XW, Zhao, HG, Lunt, RR, Yang, C, Atwater, H, Baldo, M, Barile, C, Barr, M, Bawendi, M, Bergren, M, Brabec, C, Bulović, V, Debije, M, Delgado-Sanchez, J, Dong, W, Duxbury, P, Evans, R, Forrest, S, Gamelin, D, Giebink, N, Herrera, C, Ho-Baillie, A, Holmes, R, Hong, S, Levine, B, Li, H, Li, Y, Liu, D, Loi, M, Luscombe, C, Makarov, N, Mcdaniel, H, Mcgehee, M, Menéndez-Velázquez, A, Mitzi, D, Moon, J, Nazeeruddin, M, Nogueira, A, Paetzold, U, Patrick, D, Rand, B, Richards, B, Schmidt, T, Tu, C, van Sark, W, Wong, W, Wu, K, Yip, H, Zhang, X, Zhao, H, and Lunt, R

Subjects

Luminescent solar concentrator, photovoltaics, performance reporting, 34 Chemical Sciences, Settore ING-IND/22 - Scienza e Tecnologia dei Materiali, photovoltaics, General Energy, Rare Diseases, Clinical Research, Taverne, ddc:333.7, SDG 7 - Affordable and Clean Energy, luminescent solar concentrator, luminescent solar concentrators, SDG 7 – Betaalbare en schone energie, 40 Engineering

Abstract

Fair and meaningful device per- formance comparison among luminescent solar concentrator- photovoltaic (LSC-PV) reports cannot be realized without a gen- eral consensus on reporting stan- dards in LSC-PV research. There- fore, it is imperative to adopt standardized characterization protocols for these emerging types of PV devices that are consistent with other PV devices. This commentary highlights several common limitations in LSC literature and summarizes the best practices moving for- ward to harmonize with standard PV reporting, considering the greater nuances present with LSC-PV. Based on these prac- tices, a checklist of actionable items is provided to help stan- dardize the characterization/re- porting protocols and offer a set of baseline expectations for au- thors, reviewers, and editors. The general consensus combined with the checklist will ultimately guide LSC-PV research towards reliable and meaningful ad- vances.

Published

2022

49. Cross‐Dehydrogenative Coupling Polymerization via C−H Activation for the Synthesis of Conjugated Polymers

Author

Baitan Chakraborty and Christine K. Luscombe

Subjects

Conjugated Polymers, Cross Dehydrogenative Coupling, General Medicine, General Chemistry, Organic Semiconductors, C−H Activation, Catalysis, Polymerization

Abstract

Owing to their versatile (opto)electronic properties, conjugated polymers have found application in several organic electronic devices. Cross-coupling reactions such as Stille, Suzuki, Kumada couplings, and direct arylation reactions have proved to be effective for their synthesis. More atom-efficient oxidative direct arylation polymerization has also been reported for making homopolymers. However, growing interest toward donor-acceptor polymers has led to the recent emergence of cross-dehydrogenative coupling (CDC) polymerization to synthesize alternating copolymers without any prefunctionalization of monomers. Metal-catalyzed cross-coupling of two simple arenes via double C−H activation, or of an arene with an alkene via oxidative Heck-type reaction have been used so far for CDC polymerization. In this article, we discuss the development of CDC polymerization protocols along with the relevant small molecule CDC reactions for an improved understanding of these reactions.

Published

2023

50. Enhanced miscibility and strain resistance of blended elastomer/π‐conjugated polymer composites through side chain functionalization towards stretchable electronics

Author

Jonathan W. Onorato, Emily J Steiner, Christine K. Luscombe, Theodore A. Cohen, and Viktoria Pakhnyuk

Subjects

Strain resistance, Materials science, Polymers and Plastics, Organic Chemistry, Stretchable electronics, Materials Chemistry, Polymer composites, Side chain, Surface modification, Composite material, Conjugated system, Elastomer, Miscibility

Published

2019