Hund’s multiplicity rule states that a higher spin state has a lower energy for a given electronic configuration1. Rephrasing this rule for molecular excited states predicts a positive energy gap between spin-singlet and spin-triplet excited states, as has been consistent with numerous experimental observations over almost a century. Here we report a fluorescent molecule that disobeys Hund’s rule and has a negative singlet–triplet energy gap of −11 ± 2 meV. The energy inversion of the singlet and triplet excited states results in delayed fluorescence with short time constants of 0.2 μs, which anomalously decrease with decreasing temperature owing to the emissive singlet character of the lowest-energy excited state. Organic light-emitting diodes (OLEDs) using this molecule exhibited a fast transient electroluminescence decay with a peak external quantum efficiency of 17%, demonstrating its potential implications for optoelectronic devices, including displays, lighting and lasers.
One of the enticing characteristics of supramolecular polymers is their thermodynamic reversibility, which is attractive, in particular, for stimuli-responsive applications. These polymers usually disassemble upon heating, but here we report a supramolecular polymerization that occurs upon heating as well as cooling. This behaviour arises from the use of a metalloporphyrin-based tailored monomer bearing eight amide-containing side chains, which assembles into a highly thermostable one-dimensional polymer through π-stacking and multivalent hydrogen-bonding interactions, and a scavenger, 1-hexanol, in a dodecane-based solvent. At around 50 °C, the scavenger locks the monomer into a non-polymerizable form through competing hydrogen bonding. On cooling, the scavenger preferentially self-aggregates, unlocking the monomer for polymerization. Heating also results in unlocking the monomer for polymerization, by disrupting the dipole and hydrogen-bonding interactions with the scavenger. Analogous to 'upper and lower critical solution temperature phenomena' for covalently bonded polymers, such a thermally bisignate feature may lead to supramolecular polymers with tailored complex thermoresponsive properties.
In general, supramolecular polymers are thermally labile in solution and easily depolymerized upon heating. This dynamic nature is beneficial in many aspects but limits certain applications. Recently, we developed “thermally bisignate supramolecular polymerization”, through which a polymer is formed upon heating as well as cooling in a hydrocarbon solvent containing a small amount of alcohol. Here, we present a detailed mechanistic picture for this polymerization based on both spectroscopic and computational studies. For this particular type of polymerization, we mainly employed a copper porphyrin derivative ( ( S ) POR Cu ) as a monomer with eight hydrogen-bonding (H-bonding) amide units in its chiral side chains. Because of a strong multivalent interaction, the resulting supramolecular polymer displayed an extraordinarily high thermal stability in a hydrocarbon medium such as methylcyclohexane (MCH)/chloroform (CHCl3) (98/2 v/v; denoted as MCH*). However, when a small volume (<2.0 vol %) of ethanol (EtOH) was added to this solution at ambient temperatures as a H-bond scavenger, the supramolecular polymer dissociated into its monomers. Here, it should be noted that, both upon cooling (clustering of EtOH) and heating (lower-critical-solution-temperature behavior, LCST), the monomer was liberated from the H-bond scavenger and underwent supramolecular polymerization. In this Article, we conducted detailed spectroscopic studies, analyzed the results using theoretical models, and eventually succeeded in supporting the pathways explaining why the monomer deactivated by the H-bond scavenger turns active upon both heating and cooling. We also investigated the thermally bisignate nature of the supramolecular polymerization of other monomers such as triphenylamine ( ( S ) TPA) and pyrene ( ( S ) Py) derivatives together with free-base ( ( R ) POR 2H ) and zinc porphyrin ( ( S ) POR Zn ) derivatives and rationalized the large potential for this multicomponent supramolecular polymerization.
In recent years, ferroelectric nematic liquid crystals have attracted considerable attention owing to their unique properties such as a colossal polarization, high electro-optic activity, and high fluidity. However, despite large efforts in designing and developing new ferrofluid molecules based on molecular parameters, the control and stabilization of ferroelectric nematic phase transitions remain challenging. Here, we discuss the impact of mixing 1,3-dioxane-tethered fluorinated (DIO) diastereomer molecules, namely transDIO and cisDIO, in controlling the ferroelectric nematic phase transition, using X-ray diffraction to investigate the effect of smectic cybotactic cluster formation. Our results show that the ferroelectric nematic phase transition can be tuned by a smooth exchange of the ferroelectric nematic transDIO and non-liquid crystal cisDIO components, where the similar dipole and molecular backbone of the two components ensures a consistent macroscopic polarization of the diastereomeric-controlled ferroelectric nematic phase.
Chirality-induced current-perpendicular-to-plane magnetoresistance (CPP-MR) originates from current-induced spin polarization in molecules. The current-induced spin polarization is widely recognized as a fundamental principle of chiral-induced spin selectivity (CISS). In this study, we investigate chirality-induced current-in-plane magnetoresistance (CIP-MR) in a chiral molecule/ferromagnetic metal bilayer at room temperature. In contrast to CPP-MR, CIP-MR observed in the present study requires no bias charge current through the molecule. The temperature dependence of CIP-MR suggests that thermally driven spontaneous spin polarization in chiral molecules is the key to the observed MR. The novel MR is consistent with recent CISS-related studies, that is, chiral molecules in contact with a metallic surface possess a finite spin polarization.
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