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1. Dipole Effects on Electron Transfer are Enormous

   https://doi.org/10.1002/anie.201802637  

   Krzeszewski, Maciej ; Espinoza, Eli M. ; Červinka, Ctirad ; Derr, James B. ; Clark, John A. ; Borchardt, Dan ; Beran, Gregory J. O. ; Gryko, Daniel T. ; Vullev, Valentine I. ( June 2018 , Angewandte Chemie International Edition)

   Molecular dipoles present important, but underutilized, methods for guiding electron transfer (ET) processes. While dipoles generate fields of Gigavolts per meter in their vicinity, reported differences between rates of ET along versus against dipoles are often small or undetectable. Herein we show unprecedentedly large dipole effects on ET. Depending on their orientation, dipoles either ensure picosecond ET, or turn ET completely off. Furthermore, favorable dipole orientation makes ET possible even in lipophilic medium, which appears counterintuitive for non‐charged donor–acceptor systems. Our analysis reveals that dipoles can substantially alter the ET driving force for low solvent polarity, which accounts for these unique trends. This discovery opens doors for guiding forward ET processes while suppressing undesired backward electron transduction, which is one of the holy grails of photophysics and energy science.

    

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2. Breaking Radial Dipole Symmetry in Planar Macrocycles Modulates Edge‐to‐Edge Packing and Disrupts Cofacial Stacking

   https://doi.org/10.1002/chem.202302946  

   Li, Yan ; Castillo, Henry D. ; Dobscha, James R. ; Morgan, Amanda R. ; Tait, Steven L. ; Flood, Amar H. ( December 2023 , Chemistry – A European Journal)

   Dipolar interactions are ever‐present in supramolecular architectures, though their impact is typically revealed by making dipoles stronger. While it is also possible to assess the role of dipoles by altering their orientations by using synthetic design, doing so without altering the molecular shape is not straightforward. We have now done this by flipping one triazole unit in a rigid macrocycle, tricarb. The macrocycle is composed of three carbazoles (2 Debye) and three triazoles (5 Debye) defining an array of dipoles aligned radially but organized alternately in and out. These dipoles are believed to dictate edge‐to‐edge tiling and face‐to‐face stacking. We modified our synthesis to prepare isosteric macrocycles with the orientation of one triazole dipole rotated 40°. The new dipole orientation guides edge‐to‐edge contacts to reorder the stability of two surface‐bound 2D polymorphs. The impact on dipole‐enhanced π stacking, however, was unexpected. Our stacking model identified an unchanged set of short‐range (3.4 Å)anti‐parallel dipole contacts. Despite this situation, the reduction in self‐association was attributed to long‐range (~6.4 Å) dipolar repulsions between π‐stacked macrocycles. This work highlights our ability to control the build‐up and symmetry of macrocyclic skeletons by synthetic design, and the work needed to further our understanding of how dipoles control self‐assembly.

    

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3. Achieving high circularly polarized luminescence with push–pull helicenic systems: from rationalized design to top-emission CP-OLED applications

   https://doi.org/10.1039/D0SC06895K  

   Dhbaibi, Kais ; Abella, Laura ; Meunier-Della-Gatta, Sylvia ; Roisnel, Thierry ; Vanthuyne, Nicolas ; Jamoussi, Bassem ; Pieters, Grégory ; Racine, Benoît ; Quesnel, Etienne ; Autschbach, Jochen ; et al ( April 2021 , Chemical Science)

   null (Ed.)

   While the development of chiral molecules displaying circularly polarized luminescence (CPL) has received considerable attention, the corresponding CPL intensity, g lum, hardly exceeds 10 −2 at the molecular level owing to the difficulty in optimizing the key parameters governing such a luminescence process. To address this challenge, we report here the synthesis and chiroptical properties of a new family of π-helical push–pull systems based on carbo[6]helicene, where the latter acts as either a chiral electron acceptor or a donor unit. This comprehensive experimental and theoretical investigation shows that the magnitude and relative orientation of the electric ( μe ) and magnetic (μ m ) dipole transition moments can be tuned efficiently with regard to the molecular chiroptical properties, which results in high g lum values, i.e. up to 3–4 × 10 −2 . Our investigations revealed that the optimized mutual orientation of the electric and magnetic dipoles in the excited state is a crucial parameter to achieve intense helicene-mediated exciton coupling, which is a major contributor to the obtained strong CPL. Finally, top-emission CP-OLEDs were fabricated through vapor deposition, which afforded a promising g El of around 8 × 10 −3 . These results bring about further molecular design guidelines to reach high CPL intensity and offer new insights into the development of innovative CP-OLED architectures. 

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4. Revealing the Cooperative Relationship between Spin, Energy, and Polarization Parameters toward Developing High‐Efficiency Exciplex Light‐Emitting Diodes

   https://doi.org/10.1002/adma.201904114  

   Wang, Miaosheng ; Huang, Yi‐Hsuan ; Lin, Kai‐Siang ; Yeh, Tzu‐Hung ; Duan, Jiashun ; Ko, Tzu‐Yu ; Liu, Shun‐Wei ; Wong, Ken‐Tsung ; Hu, Bin ( September 2019 , Advanced Materials)

   Experimental studies to reveal the cooperative relationship between spin, energy, and polarization through intermolecular charge‐transfer dipoles to harvest nonradiative triplets into radiative singlets in exciplex light‐emitting diodes are reported. Magneto‐photoluminescence studies reveal that the triplet‐to‐singlet conversion in exciplexes involves an artificially generated spin‐orbital coupling (SOC). The photoinduced electron parametric resonance measurements indicate that the intermolecular charge‐transfer occurs with forming electric dipoles (D^+•→A^−•), providing the ionic polarization to generate SOC in exciplexes. By having different singlet‐triplet energy differences (ΔE_ST) in 9,9′‐diphenyl‐9H,9′H‐3,3′‐bicarbazole (BCzPh):3′,3′″,3′″″‐(1,3,5‐triazine‐2,4,6‐triyl)tris(([1,1′‐biphenyl]‐3‐carbonitrile)) (CN‐T2T) (ΔE_ST= 30 meV) and BCzPh:bis‐4,6‐(3,5‐di‐3‐pyridylphenyl)‐2‐methyl‐pyrimidine (B3PYMPM) (ΔE_ST= 130 meV) exciplexes, the SOC generated by the intermolecular charge‐transfer states shows large and small values (reflected by different internal magnetic parameters: 274 vs 17 mT) with high and low external quantum efficiency maximum, EQE_max(21.05% vs 4.89%), respectively. To further explore the cooperative relationship of spin, energy, and polarization parameters, different photoluminescence wavelengths are selected to concurrently change SOC, ΔE_ST, and polarization while monitoring delayed fluorescence. When the electron clouds become more deformed at a longer emitting wavelength due to reduced dipole (D^+•→A^−•) size, enhanced SOC, increased orbital polarization, and decreased ΔE_STcan simultaneously occur to cooperatively operate the triplet‐to‐singlet conversion.

    

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5. Self‐Assembled Robust 2D Networks from Magneto‐Elastic Bars

   https://doi.org/10.1002/admt.202202189  

   Yang, Xinyan ; Leng, Junqing ; Sun, Cheng ; Keten, Sinan ( June 2023 , Advanced Materials Technologies)

   Magneto‐elastic materials facilitate features such as shape programmability, adaptive stiffness, and tunable strength, which are critical for advances in structural and robotic materials. Magneto‐elastic networks are commonly fabricated by employing hard magnets embedded in soft matrices to constitute a monolithic body. These architected network materials have excellent mechanical properties but damage incurred in extreme loading scenarios are permanent. To overcome this limitation, we present a novel design for elastic bars with permanent fixed dipole magnets at their ends and demonstrate their ability to self‐assemble into magneto‐elastic networks under random vibrations. The magneto‐elastic unit configuration, most notably the orientation of end dipoles, is shown to dictate the self‐assembled network topology, which can range from quasi‐ordered triangular lattices to stacks or strings of particles. Network mechanics are probed with uniaxial tensile tests and design criteria for forming stable lightweight 2D networks are established. It is shown that these magneto‐elastic networks rearrange and break gracefully at their magnetic nodes under large excitations and yet recover their original structure at moderate random excitations. This work paves the way for structural materials that can be self‐assembled and repaired on‐the‐fly with random vibrations, and broadens the applications of magneto‐elastic soft materials.

    

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