Bay Positions Research Articles

A-A′-A structured methoxy-modified perylenediimide dimeric acceptors at the outside-bay position: Synthesis, spectroscopic property and photovoltaic application

Acceptor-acceptor′-acceptor (A-A′-A) structured methoxy-modified perylene diimide (PDI-OMe) electron acceptors weren′t fully investigated so far. Herein, two A-A′-A type dimeric acceptors, denoted as DTBT-(PDI-OMe)2 and difluorinated DTFFBT-(PDI-OMe)2, where two methoxy-modified PDI-OMe subunits as biswings and electron-deficient units 4,7-di(thien-2- yl)benzothiadiazole (DTBT) and difluorinated 4,7-di(thien-2-yl)-5,6-difluorobenzothiadiazole (DTFFBT) as central linkers, were developed. And the methoxy-free DTBT-(PDI-HD)2 was utilized as reference material. Owing to the electron-donating characteristic of incorporating methoxy group at the outside bay position of PDI, DTBT-(PDI-OMe)2 possessed an enlarged optical bandgap but improved light-capturing ability, weakened aggregation and up-shifted ELUMO. Moreover, the decreased the thermal- and photo-stability, slightly red-shifted maximum absorption, the reduced the bandgap, weakened aggregation and the deepened ELUMO were seen after further difluorinating the central benzothiadiazole linker. Thereupon, compared with DTBT-(PDI-HD)2, PTB7-Th:DTBT-(PDI-OMe)2-based device achieved a 0.07V increased VOC of 0.86V, an 5.91% enhanced JSC of 3.94mAcm2 and a 20.69% elevated FF of 42.23% and thus a 38.83% raised PCE of 1.43%. Moreover, the further difluorinating the central benzothiadiazole linker led to a 20.98% decreased PCE of 1.13%, which was mainly limited by the 0.07V decreased VOC and 15.65% dropped FF regardless of slightly increased JSC in the DTFFBT-(PDI-OMe)2-based device. The dropped PCE was mainly due to the enlarged charge recombination, reduced electron mobility resulted from the weakened aggregation and insufficient microstructural phase separation. The work suggested that introducing the methoxy substituent at the outside bay position was an effective strategy for enhancing the voltage and efficiency, but it should be cautious to further incorporate fluorine atoms into the central electron-deficient linking cores during the A-A′-A structured methoxy-modified PDI dimers for high performance photovoltaic device.

Modified perylene diimide for femto molar level detection of glucose: smartphone-assisted colorimetric glucose detection kits.

In this report, a functionalized hydroxyphenyl benzothiazole (HBT) derivative has been synthesized and anchored onto the perylene diimide (PDI) core at the -bay position (PHI). PHI has been explored for the generation of radical anions (PH1˙-) and dianions (PH12-) in 20% HEPES buffer-DMSO solution using H2S as a sacrificial electron donor. The PH1˙- has a half-life (t1/2) of 1.5 h and 3 h in oxygenated and hypoxic conditions, respectively. The formation of radical anions has been confirmed by optical (absorbance and fluorescence) methods, cyclic voltammetry (CV), differential pulse voltammetry (DPV), and femtosecond transient absorbance spectroscopy along with current-voltage (I-V) and NOBF4 studies. The PH1˙- showed peroxidase-like activity for the reduction of H2O2 as low as 170 fmol L-1 (fM) giving a colour change from sea green to pink. The biochemical assay which consists of PH1˙-+ GOx has been further utilized as a glucose sensor. Upon addition of glucose (0-8 nM) in the biochemical assay, the in-situ produced H2O2 (after oxidation of glucose with GOx) oxidized PH1˙- to PH1 giving a sea green to pink colorimetric read out along with a decrease in the absorption intensities at 720, 815, 880 and 950 nm and the emergence of absorption intensity at 541 nm. The lowest limit of detection is 85 fM. We also explored this biochemical assay for the detection of 860 fM of glucose in a 10% blood serum. Similarly, fluorometric, CV and DPV studies were carried out for the detection of glucose using this biochemical assay. The smartphone-assisted RGB colour analyser showed large variations in the red colour and this RGB based colour differentiation can be used for the detection of 1 nM of glucose.

Bay-substituted Perylene diimides (PDIs) as redox mediators in dye-sensitized solar cells and active electrode material in supercapacitors

In recent years, innovations in materials design have improved the optoelectronic properties of advanced materials and facilitated their efficient utilization. A significant amount of research has been conducted on developing perylene diimide (PDI) dyes for their use in various energy-related applications. In the present work, we have synthesized bay-substituted PDI derivatives and explored their dual applications in energy harvesting and storage devices. The nucleophilic substitution reaction of 1,7/1,6-brominated Val-PDI was performed by using 2-naphthol (N) and its Nitrogen analogue 8-hydroxy quinoline (Q) for analysing the effect of N-heterocycle at the bay position. The prepared 1,7 (N1/Q1) and 1,6 (N2/Q2) PDIs underwent thorough photophysical and electrochemical analyses and their structures were optimized through density functional theory (DFT) using B3LYP approach with a 6-31+G (d,p) basis set. Although all the prepared bay-substituted PDIs showed reasonable redox activity, N1 was chosen as an electrolyte dopant in dye-sensitized solar cells (DSSC) owing to its band alignment. This aided in enhanced electron lifetime and charge transfer properties, which led to an enhanced efficiency of 2.04 % while the conventional DSSC delivered only 1.84 % at 200 W m−2 illumination. Additionally, the symmetrical supercapacitor fabricated by using Q1 as electrode material generated a high specific capacitance of 146.54 F g−1. Thus, the proposed work opens avenues for the utility of bay-substituted PDI derivatives for organic electronic applications.

Dual-Modality Imaging with a Zwitterionic Fluorescent Probe for Reversible Monitoring of Mitochondrial Membrane Potential Dynamics.

Traditional fluorescence intensity-based probes face challenges in accurately measuring mitochondrial membrane potential (MMP) due to intramolecular fluorescence quenching. In this work, we introduce a novel approach by incorporating quenching moieties within the zwitterionic probe to eliminate self-quenching interference, thus, enabling real-time and precise visualization of reversible MMP changes. We synthesized a zwitterionic fluorescent probe consisting of silicon-rhodamine (SiR) that was hydroxyl-substituted on the bay position of perylene diimides (PDIs) connected via a polyethylene glycol (PEG) linker. The lipophilic cationic SiR facilitates the entry of the PDI into the mitochondria, where the alkaline pH environment (pH = 8.0) ionizes the hydroxyl to a negatively charged species, affecting the quenching efficiency of SiR depending on the distance between the PDI and SiR moieties regulated by the MMP. The rigid aromatic ring of the PDI and strong hydrophobic interactions with the lipid bilayer, along with the inhibitory effect of the negatively charged hydroxyl on internalization, ensure the retention of PDI within the mitochondria. As the MMP decreases, SiR shifts outward, reducing quenching by phenolic anions and restoring fluorescence. Conversely, as the MMP increases, SiR moves inward, intensifying quenching by phenolic ions and reducing fluorescence, enabling reversible visualization monitoring of the MMP. This strategy overcomes the limitations of traditional intensity-based probes, providing a new avenue for reversible monitoring of the MMP.

Structural Basis of Cucurbituril-Containing Self-Assembled Supramolecular Chiral Materials.

Macrocycle-based host-guest complexation offers an intriguing protocol in producing chiroptical materials, while the bulky size and dynamic exchange between hosts and guests hinders the ordered aggregation to afford the long-range chiral arrangement. It remains great challenges in assembling cucurbit[n]urils (CB[n]s) included complexes to induce supramolecular chirality ascribed to the excellent water solubility and flexible packing. Herein, we unveiled the structural basis on the formation of chiroptical coassemblies from CB[n] (n=6, 7) complexes. Perylene diimides (PDIs) with cationic chiral pendants formed complexes in the aqueous media, which selectively showed chiroptical properties. Chlorination at the bay position, increasing alkyl length of cationic chiral pendants or reducing the number of polyaromatic rings would hinder the chiral aggregation. In a comprehensive manner, CB[6] favors ordered aggregation into one-dimensional fibrous nanoarchitectures that greatly facilitates the supramolecular chirality. In contrast, CB[7] with larger cavity and water solubility shrinks the ordered arrangement of complexes, reducing the formation possibility of supramolecular chiral nanoarchitectures. This work suggests the great potential of CB[6] in the preparation and manipulation of supramolecular chiral assemblies, shedding light on the macrocycle-based functional chiroptical materials.

Structural Basis of Cucurbituril‐Containing Self‐Assembled Supramolecular Chiral Materials

Macrocycle‐based host‐guest complexation offers an intriguing protocol in producing chiroptical materials, while the bulky size and dynamic exchange between hosts and guests hinders the ordered aggregation to afford the long‐range chiral arrangement. It remains great challenges in assembling cucurbit[n]urils (CB[n]s) included complexes to induce supramolecular chirality ascribed to the excellent water solubility and flexible packing. Herein, we unveiled the structural basis on the formation of chiroptical coassemblies from CB[n] (n = 6, 7) complexes. Perylene diimides (PDIs) with cationic chiral pendants formed complexes in the aqueous media, which selectively showed chiroptical properties. Chlorination at the bay position, increasing alkyl length of cationic chiral pendants or reducing the number of polyaromatic rings would hinder the chiral aggregation. In a comprehensive manner, CB[6] favors ordered aggregation into one‐dimensional fibrous nanoarchitectures that greatly facilitates the supramolecular chirality. In contrast, CB[7] with larger cavity and water solubility shrinks the ordered arrangement of complexes, reducing the formation possibility of supramolecular chiral nanoarchitectures. This work suggests the great potential of CB[6] in the preparation and manipulation of supramolecular chiral assemblies, shedding light on the macrocycle‐based functional chiroptical materials.

Excited Charge Transfer Promoted Electron Transfer in all Perylenediimide Derived, Wide-Band Capturing Conjugates: A Mimicry of the Early Events of Natural Photosynthesis.

Fundamental discoveries in electron transfer advance scientific and technological advancements. It is suggested that in plant and bacterial photosynthesis, the primary donor, a chlorophyll or bacteriochlorophyll dimer, forms an initial excited symmetry-breaking charge transfer state (1CT*) upon photoexcitation that subsequently promotes sequential electron transfer (ET) events. This is unlike monomeric photosensitizer-bearing donor-acceptor dyads where ET occurs from the excited donor or acceptor (1D* or 1A*). In the present study, we successfully demonstrated the former photochemical event using an excited charge transfer molecule as a donor. Electron-deficient perylenediimide (PDI) is functionalized with three electron-rich piperidine entities at the bay positions, resulting in a far-red emitting CT molecule (DCT). Further, this molecule is covalently linked to another PDI (APDI) carrying no substituents at the bay positions, resulting in wide-band capturing DCT-APDI conjugates. Selective excitation of the CT band of DCT in these conjugates leads to an initial 1DCT* that undergoes subsequent ET involving APDI, resulting in DCT +-APDI - charge separation product (kCS~109 s-1). Conversely, when APDI was directly excited, ultrafast energy transfer (ENT) from 1APDI* to DCT (kENT~1011 s-1) followed by ET from 1DCT* to PDI is witnessed. While increasing solvent polarity improved kCS rates, for a given solvent, the magnitude of the kCS values was almost the same, irrespective of the excitation wavelengths. The present findings demonstrate ET from an initial CT state to an acceptor is key to understanding the intricate ET events in complex natural and bacterial photosynthetic systems possessing multiple redox- and photoactive entities.

Low-aggregated multi-color perylene diimide derivatives and their photo-thermal stability in color films

Perylene diimide derivatives (PDIs) have potential applications in organic semiconductor devices owing to their high absorption coefficients and chemical persistency. However, molecular aggregation and inferior thermal stability limit their preparation and application as color-film devices. In addressing this issue, we designed a series of PDIs by introducing different steric hindrance group (propyl isobutyl polyhedral oligomeric silsesquioxane (propyl isobutyl POSS), isoctyl, and 2-octyldodecyl) at the terminal position and electron-donating group (alkoxy, alkyl-substituted phenoxy or alkylamino) at the bay position. Density Functional Theory (DFT) calculations demonstrated that the substitution of propyl isobutyl POSS at the terminal position and electron-donating groups (2,4-di-tert-butylphenoxy, tert-butyloxy, and diethylamino) at bay position of the perylene chromophore had synergistic effect on reducing the aggregation of PDIs, and the bay substitution could achieve PDIs with different colors due to the connection of the substituent group with the conjugated system of the PDIs. Based on the results of calculation, four low-aggregated multi-color PDIs were synthesized for the first time. Their color films displayed excellent photo-thermal stability because of the introduction of propyl isobutyl POSS moieties (Td > 230 °C, color difference ΔE < 3). This work provides important insights into the design of multi-color PDIs with low aggregation and high photo-thermal stabilities, which holds great promise for the organic electronics research field.

Perylene diimide tethered with multi-POSS nanocages for polymer composite material with nonlinear optical property

A novel perylene diimide derivative tethered with three polyhedral oligosilsesquioxane nanocages (PDI-3POSS) was designed and synthesized as an organic-inorganic hybrid with donor-acceptor (D-A) conjugated structure. The experimental results reveal that the introduction of multi-POSS nanocages endows PDI-3POSS with inhibition of continuous PDI-stacking and subsequent good dispersivity in polymer matrix. Moreover, the molecular simulation indicates that PDI-3POSS can exhibit intense intramolecular charge transfer due to the electron-donating modification at the bay position. As a result, PMMA film doped with PDI-3POSS possesses unique reverse saturable absorption property and potential optical limiting application. It is hoped that the synergistic modification of multi-nanocages and D-A structure may be a new strategy to prepare composite materials with both good dispersivity and novel nonlinear optical property.

All-organic heterojunctions used for the excellent photocatalytic H2O2 synthesis: The key role of bay-position Cl in PDI

Melem is the basic structural unit of g-C3N4. When directly utilized as a photocatalyst, the separation efficiency of photogenerated electron-hole pairs is low. In this study, we constructed a Melem-based all-organic heterojunction (PICN) by reacting the -NH2 at the terminal of the Melem unit with the anhydride of PDA. The photocatalytic efficiency for H2O2 production of the heterojunction is 4.2 times that of CN. Introducing -Cl at the bay position of PDI further enhances the photocatalytic H2O2 production efficiency by 1.6 times. This enhancement is attributed to the introduction of -Cl, which not only broadens the UV–visible light absorption range of the sample but also improves the interface electron transfer efficiency between Melem and PDICl. Moreover, the introduction of -Cl can also reduce the overpotential of the O2 reduction reaction on the surface of the sample. These novel findings may provide insights for the design of organic heterojunction photocatalysts.

Impact of Packing Geometry on Excimer Characteristics and Mobility in Perylene Bisimide Polycrystalline Films.

Efficient exciton transport is essential for high-performance optoelectronics. Considerable efforts have been focused on improving the exciton mobility in organic materials. While it is feasible to improve mobility in organic systems by forming well-ordered stacks, the formation of trap states, particularly the lower-lying states referred to as excimers, remains a significant challenge to enhancing mobility. The mobility of excimer excitons intricately depends on the strength of excitonic coupling in terms of Förster-type diffusive exciton transfer processes. Given that the formation and mobility of excimer excitons are highly sensitive to molecular arrangements (packing geometries), conducting comprehensive investigations into the structure-property relationship in organic systems is crucial. In this study, we prepared three types of polycrystalline films of perylene bisimide (PBI) by varying substituents at the imide and bay positions, which allowed us to tailor the properties of excimer excitons and their mobility based on packing geometries and excitonic coupling strengths. By utilizing femtosecond transient absorption spectroscopy, we observed ultrafast excimer formation in the higher coupling regime, while in the lower coupling regime, the transition from Frenkel to excimer excitons occurs with a time constant of 500 fs. Under high pump-fluence, exciton-exciton annihilation processes occur, indicating the diffusion of excimer excitons. Intriguingly, employing a three-dimensional diffusion model, we derived a diffusion constant that is 3000 times greater in the high coupling regime than in the low coupling regime. To investigate the optoelectronic properties in the form of a bulk system, we fabricated n-type organic field effect transistors and obtained 8000 times higher mobility in the high coupling regime. Furthermore, photocurrent measurements enable us to investigate the charge carrier transport by mobile excimer excitons, suggesting a 230-fold improvement in external quantum efficiency with tightly packing PBI molecules compared to the low coupling regime. These findings not only offer valuable insights into optimizing organic materials for optoelectronic devices but also unveil the intriguing potential of exciton migration within excimers.

On-Surface Synthesis of Silole and Disila-Cyclooctene Derivatives.

The incorporation of Si atoms into organic compounds significantly increases a variety of functionality, facilitating further applications. Recently, on-surface synthesis was introduced into organosilicon chemistry as 1,4-disilabenzene bridged nanostructures were obtained via coupling between silicon atoms and brominated phenyl groups at the ortho position on Au(111). Here, we demonstrate a high generality of this strategy via syntheses of silole derivatives and nanoribbon structures with eight-membered sila-cyclic rings from dibrominated molecules at the bay and peri positions on Au(111), respectively. Their structures and electronic properties were investigated by a combination of scanning tunneling microscopy/spectroscopy and density functional theory calculations. This work demonstrates a great potential to deal with heavy group 14 elements in on-surface silicon chemistry.

On‐Surface Synthesis of Silole and Disila‐Cyclooctene Derivatives

AbstractThe incorporation of Si atoms into organic compounds significantly increases a variety of functionality, facilitating further applications. Recently, on‐surface synthesis was introduced into organosilicon chemistry as 1,4‐disilabenzene bridged nanostructures were obtained via coupling between silicon atoms and brominated phenyl groups at the ortho position on Au(111). Here, we demonstrate a high generality of this strategy via syntheses of silole derivatives and nanoribbon structures with eight‐membered sila‐cyclic rings from dibrominated molecules at the bay and peri positions on Au(111), respectively. Their structures and electronic properties were investigated by a combination of scanning tunneling microscopy/spectroscopy and density functional theory calculations. This work demonstrates a great potential to deal with heavy group 14 elements in on‐surface silicon chemistry.

Dynamic fluorescence imaging and controllable capture/release of guests based on thermo-responsive perylene-cyclodextrin conjugates

In view of the fact that multivalent intermolecular noncovalent interactions are the main elements for the formation of phase separation, supramolecular entities are a type of multivalent system. However, the phase separation system based on single supramolecular molecules was limited. In this paper, two permethyl-β-cyclodextrin modified perylene monoamide derivatives (PMI-B-CD and PMI-N-CD) with modification of benzene and naphthalene groups at the bay position of perylene backbone were synthesized. Of interest, PMI-B-CD and PMI-N-CD showed a LCST effect due to a self-inclusion interaction between PMCD and the benzene or naphthalene groups in the bay position of perylene monoamide backbone. Dynamic confocal fluorescence imaging of PMI-B-CD and PMI-N-CD showed thermo-responsive phase separation process. It is surprised that PMI-B-CD and PMI-N-CD achieved thermo-responsive capture and release of aromatic guests. Dynamic phase separation and controllable capture and release of guests with thermo-responsive phase transition process are found, which opens a novel supramolecular principle of liquid-liquid transition.

Core charge of imidazolium annulated triphenylene derivatives induces discotic columnar mesomorphism.

Thermotropic ionic liquid crystals have remained a relatively little studied group of materials despite their many potential applications as anisotropic ionic liquids and charge (ion and electron/hole) transporting materials. Particularly rare are core charged discotic liquid crystals because their synthesis is usually more involved, and their molecular design is less established. Presented here is a straightforward and versatile synthetic approach to imidazolium annulated triphenylene derivatives. Their neutral imidazole precursors are not liquid crystalline while the imidazolium salts display hexagonal discotic columnar mesophases over a wide range of temperatures and as low as 47 °C. Computational studies at the DFT and PM6 levels of theory confirmed much higher stacking energies for the imidazolium salts compared to the neutral imidazole precursors. They also predicted the anions of columnar stacks of imidazolium salts to be positioned in the bay-positions next to the imidazolium unit and in-plane with the polyaromatic system. The anions were stabilized in the bay position by multiple interactions with partially positively charged H atoms and do not interfere with π-π stacking.

Boosting solar cell performance during highly thermo- and photo-stable asymmetric perylene diimide dimeric acceptors by selenium-annulation at the outside bay position

Se-annulated PDI-SePDI device achieved a 56.64% elevated PCE of 5.31%, which was mainly due to enhanced exciton dissociation, suppressed charge recombination, and increased charge mobility benefiting from beneficial microstructural morphology.

Toward Type I/II ROS Generation Photoimmunotherapy by Molecular Engineering of Semiconducting Perylene Diimide.

As prospective phototheranostic agents for cancer imaging and therapy, semiconducting organic molecule-based nanomedicines are developed. However, near-infrared (NIR) emission, and tunable type I (O2 • -) and type II (1O2) photoinduced reactive oxygen species (ROS) generation to boost cancer photoimmunotherapy remains a big challenge. Herein, a series of D-π-A structures, NIR absorbing perylene diimides (PDIs) with heavy atom bromide modification at the bay position of PDIs are prepared for investigating the optimal photoinduced type I/II ROS generation. The heavy atom effect has demonstrated a reduction of molecular ∆EST and promotion of the intersystem crossing processes of PDIs, enhancing the photodynamic therapy (PDT) efficacy. The modification of three bromides and one pyrrolidine at the bay position of PDI (TBDT) has demonstrated the best type I/II PDT performance by batch experiments and theoretical calculations. TBDT based nanoplatforms (TBDT NPs) enable type I/II PDT in the hypoxic tumor microenvironment as a strong immunogenic cell death (ICD) inducer. Moreover, TBDT NPs showing NIR emission allow in vivo bioimaging guided phototherapy of tumor. This work uses novel PDIs with adjustable type I/II ROS production to promote antitumor immune response and accomplish effective tumor eradication, consequently offering molecular guidelines for building high-efficiency ICD inducers.

High‐Performance Near‐Infrared Chlorinated Rylenecarboximide Fluorophores via Consecutive C−N and C−C Bond Formation

AbstractA new class of near‐infrared (NIR) fluorophores, PAI, is obtained by consecutive C−N/C−C bond formation between diphenylamines and 9,10‐dibromoperylenecarboximide. Owing to the rigid structure, extended π‐conjugation and pronounced push‐pull substitution, these fluorophores show emission maxima up to 804 nm and large Stokes shifts. The extraordinarily high fluorescence quantum yields from 47 % to 70 % are attributed to chloro substitution in the bay positions of the perylene core. These characteristics, together with high photostability, qualify them as useful NIR emitters for applications as biomarkers and security inks.

High-Performance Near-Infrared Chlorinated Rylenecarboximide Fluorophores via Consecutive C-N and C-C Bond Formation.

A new class of near-infrared (NIR) fluorophores, PAI, is obtained by consecutive C-N/C-C bond formation between diphenylamines and 9,10-dibromoperylenecarboximide. Owing to the rigid structure, extended π-conjugation and pronounced push-pull substitution, these fluorophores show emission maxima up to 804 nm and large Stokes shifts. The extraordinarily high fluorescence quantum yields from 47 % to 70 % are attributed to chloro substitution in the bay positions of the perylene core. These characteristics, together with high photostability, qualify them as useful NIR emitters for applications as biomarkers and security inks.

Silicon- and Germanium-Functionalized Perylene Diimides: Synthesis, Optoelectronic Properties, and Their Application as Non-fullerene Acceptors in Organic Solar Cells.

Organic solar cells have been continuously studied and developed through the last decades. A major step in their development was the introduction of fused-ring non-fullerene electron acceptors. Yet, beside their high efficiency, they suffer from complex synthesis and stability issues. Perylene-based non-fullerene acceptors, in contrast, can be prepared in only a few steps and display good photochemical and thermal stability. Herein, we introduce four monomeric perylene diimide acceptors obtained in a three-step synthesis. In these molecules, the semimetals silicon and germanium were added in the bay position, on one or both sides of the molecules, resulting in asymmetric and symmetric compounds with a red-shifted absorption compared to unsubstituted perylene diimide. Introducing two germanium atoms improved the crystallinity and charge carrier mobility in the blend with the conjugated polymer PM6. In addition, charge carrier separation is significantly influenced by the high crystallinity of this blend, as shown by transient absorption spectroscopy. As a result, the solar cells reached a power conversion efficiency of 5.38 %, which is one of the highest efficiencies of monomeric perylene diimide-based solar cells recorded to date.