Ultra‐Tight Host‐Guest Binding with Exceptionally Strong Positive Cooperativity

Sobiech, Thomas A.; Zhong, Yulong; Miller, Daniel P.; McGrath, Jillian K.; Scalzo, Christina T.; Redington, Morgan C.; Zurek, Eva; Gong, Bing

doi:10.1002/anie.202213467

Cited by 11 publications

(10 citation statements)

References 35 publications

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“…Upon addition of 5 % D 2 O in DMSO-d 6 :CDCl 3 (9.5:0.5), the aromatic signals get broadened and are shifted upfield due to the enhanced π-π intermolecular stacking of aromatic moieties (Figure S10). [32][33] The powder X-ray diffraction (XRD) studies also support the existence of intermolecular π-π stacking in DPZ-PHZ molecules (Figure S11). [34][35] To have an idea about morphology, we carried out scanning electron microscopy (SEM) studies.…”

Section: Resultsmentioning

confidence: 92%

“…To understand the driving force for the aggregation of DPZ‐PHZ molecules, we carried out the 1 H NMR studies in DMSO‐ d 6 :CDCl 3 :D 2 O. Upon addition of 5 % D 2 O in DMSO‐ d 6 :CDCl 3 (9.5:0.5), the aromatic signals get broadened and are shifted upfield due to the enhanced π–π intermolecular stacking of aromatic moieties (Figure S10) [32–33] . The powder X‐ray diffraction (XRD) studies also support the existence of intermolecular π–π stacking in DPZ‐PHZ molecules (Figure S11) [34–35] …”

Section: Resultsmentioning

confidence: 99%

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Strategic Insertion of Heavy Atom to Tailor TADF OLED Material for the Development of Type I Photosensitizing Catalytic Red Emissive Assemblies

Singh,

Kumar,

Bhalla

2024

Chemistry An Asian Journal

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The work presented in the manuscript describes a simple strategy for transforming thermally activated delayed fluorescent organic light‐emitting diodes (TADF OLEDs) compound 10‐(dibenzo[a,c]phenazin‐11‐yl)‐10H‐phenoxazine (DPZ‐PXZ) into type I photosensitizer 10‐(dibenzo[a,c]phenazin‐11‐yl)‐10H‐phenothiazine (DPZ‐PHZ) by strategically introducing sulfur atom in the photosensitizing core. The synthesized compound DPZ‐PHZ exhibits aggregation‐induced enhancement (AIE) and through‐space charge transfer (TSCT) characteristics and generates red emissive assemblies in mixed aqueous media. The original compound DPZ‐PXZ exhibits well‐separated HOMO and LUMO levels and is reported to have highly efficient reverse intersystem crossing (RISC). In comparison, the incorporation of sulfur atom in the phenothiazine donor regulates the electronic communication between donor and acceptor units and promotes the intersystem crossing (ISC) in DPZ‐PHZ molecules. Interestingly, compound DPZ‐PHZ exhibits rapid activation of aerial oxygen for instant generation of superoxide radical anion. Backed by excellent type I photosensitizing activity, DPZ‐PHZ assemblies have high catalytic potential for the synthesis of benzimidazoles, benzothiazoles and quinazolines derivatives under mild reaction conditions. The work presented in the manuscript provides an insight into the combination of heavy atom approach and TSCT for achieving adequate electronic communication between donor and acceptor units, balanced RISC/ISC, and stabilized‐charge separated state for the development of efficient type I photosensitizing assemblies.

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Section: Resultsmentioning

confidence: 92%

Section: Resultsmentioning

confidence: 99%

Strategic Insertion of Heavy Atom to Tailor TADF OLED Material for the Development of Type I Photosensitizing Catalytic Red Emissive Assemblies

Singh,

Kumar,

Bhalla

2024

Chemistry An Asian Journal

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“…Gong and colleagues reported a novel exteriorly H‐bonded macrocycle 5 a with a C 3 symmetry, which can bind bipyridinium guest G7 and DABCO‐based cationic guests G8 – G10 to form a highly stable pseudo[3]rotaxane in 2 : 1 stoichiometry (Figure 9). [53] The isothermal titration calorimetry (ITC) experiments demonstrated high binding affinities ( K total =3.2×10 13 M −2 for 4a 2 ⊃ G9 ; K total =2.0×10 13 M −2 for 4a 2 ⊃ G10 in DMF) for DABCO‐based cationic guests and strong positive cooperativity (α=2700 for 4a 2 ⊃ G9 , α=5500 for 4a 2 ⊃ G10 ) of host‐guest binding systems. This result contrasts with the negative to weakly positive cooperativity observed for macrocycle 1 a with bipyridinium guests (cooperativity factor α ranging from 0.12 to 2.51).…”

Section: Host‐guest Complexation and Production Of Higher Order Rotax...mentioning

confidence: 99%

Construction of Oligorotaxanes with Hydrogen‐Bonded Aramide Macrocycles through Threaded Host‐Guest Complexation

Huang,

Li,

Cai

et al. 2024

Chemistry A European J

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The development of efficient and selective organic synthetic approaches for complex molecules has garnered significant attention due to the need for precise control over molecular structures and functions. Rotaxanes, a type of mechanically interlocked molecules (MIMs), have shown promising applications in various fields including sensing, catalysis, and material science. However, the highly selective synthesis of oligo[n]rotaxanes (mostly n≥3) through controlling host‐guest complexation and supramolecular threading assembly process still remains an ongoing challenge. In particular, the utilization of two‐dimensional (2D) macrocycles with structural shape‐persistency for the synthesis of oligo[n]rotaxanes is rare. In this concept, research on cooperatively threaded host‐guest complexation with hydrogen‐bonded (H‐bonded) aramide macrocycles and selective synthetic protocols of oligo[n]rotaxanes has been summarized. The high efficiency and selectivity in synthesis are ascribed to the synergistic interplay of multiple non‐covalent bonding interactions such as hydrogen bonding and intermolecular π–π stacking of macrocycles within the unique supramolecular structure of threaded host‐guest complexes. This review focuses on the latest progress in the concepts, synthesis, and properties of H‐bonded aramide macrocycle‐based oligorotaxanes, and presents an in‐depth outlook on challenges in this emerging field.

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“…The addition of an equivalent mole ratio of carbon dioxide adduct (2-hydroxyethyl) carbamic acid (donated as 1-CO 2 ), which was formed by directly bubbling CO 2 gas into a DMSO solution containing monoethanolamine 1, demonstrated a new peak at m/z = 1667.8485 that was assigned to the species of [1-CO 2 •H1] 2+ via a comparison with the simulation results based on the natural isotopic abundances (Figure 1c), referring to the stability of the host and the host−guest complex in the solution. 21 H1 exhibited a single set of ligand signals in 1 H NMR, the addition of 1-CO 2 adduct shifted the −OH proton and the −CH 2 protons downfield 22 (Figure S7). Diffusion-ordered 1 H NMR spectra of H1 and of H1 with that of 1-CO 2 (Figure 2a) demonstrated the almost identical diffusion coefficient, 7.90 × 10 −11 m 2 •S −1 .…”

Section: ■ Introductionmentioning

confidence: 99%

Enzymatic Activation and Continuous Electrochemical Production of Methane from Dilute CO₂ Sources with a Self-Healing Capsule

Wang,

Jing,

Yang

et al. 2024

J. Am. Chem. Soc.

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Converting dilute CO 2 source into value-added chemicals and fuels is a promising route to reduce fossil fuel consumption and greenhouse gas emission, but integrating electrocatalysis with CO 2 capture still faced marked challenges. Herein, we show that a self-healing metal−organic macrocycle functionalized as an electrochemical catalyst to selectively produce methane from flue gas and air with the lowest applied potential so far (0.06 V vs reversible hydrogen electrode, RHE) through an enzymatic activation fashion. The capsule emulates the enzyme' pocket to abstract one in situ-formed CO 2 -adduct molecule with the commercial amino alcohols, forming an easy-to-reduce substrate-involving clathrate to combine the CO 2 capture with electroreduction for a thorough CO 2 reduction. We find that the self-healing system exhibited enzymatic kinetics for the first time with the Michaelis−Menten mechanism in the electrochemical reduction of CO 2 and maintained a methane Faraday efficiency (FE) of 74.24% with a selectivity of over 99% for continuous operation over 200 h. A consecutive working lab at 50 mA•cm −2 , in an eleven-for-one (10 h working and 1 h healing) electrolysis manner, gives a methane turnover number (TON) of more than 10,000 within 100 h. The integrated electrolysis with CO 2 capture facilitates the thorough reduction of flue gas (ca. 13.0% of CO 2 ) and first time of air (ca. 400 ppm of CO 2 to 42.7 mL CH 4 from 1.0 m 3 air). The new self-healing strategy of molecular electrocatalyst with an enzymatic activation manner and anodic shifting of the applied potentials provided a departure from the existing electrochemical catalytic techniques.

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Ultra‐Tight Host‐Guest Binding with Exceptionally Strong Positive Cooperativity

Cited by 11 publications

References 35 publications

Strategic Insertion of Heavy Atom to Tailor TADF OLED Material for the Development of Type I Photosensitizing Catalytic Red Emissive Assemblies

Strategic Insertion of Heavy Atom to Tailor TADF OLED Material for the Development of Type I Photosensitizing Catalytic Red Emissive Assemblies

Construction of Oligorotaxanes with Hydrogen‐Bonded Aramide Macrocycles through Threaded Host‐Guest Complexation

Enzymatic Activation and Continuous Electrochemical Production of Methane from Dilute CO₂ Sources with a Self-Healing Capsule

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Ultra‐Tight Host‐Guest Binding with Exceptionally Strong Positive Cooperativity

Cited by 11 publications

References 35 publications

Strategic Insertion of Heavy Atom to Tailor TADF OLED Material for the Development of Type I Photosensitizing Catalytic Red Emissive Assemblies

Strategic Insertion of Heavy Atom to Tailor TADF OLED Material for the Development of Type I Photosensitizing Catalytic Red Emissive Assemblies

Construction of Oligorotaxanes with Hydrogen‐Bonded Aramide Macrocycles through Threaded Host‐Guest Complexation

Enzymatic Activation and Continuous Electrochemical Production of Methane from Dilute CO2 Sources with a Self-Healing Capsule

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Product

Resources

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Enzymatic Activation and Continuous Electrochemical Production of Methane from Dilute CO₂ Sources with a Self-Healing Capsule