TTF Units Research Articles

Integrating Tetrathiafulvalene and Nickel-Bis(dithiolene) Units into Donor-Acceptor Covalent Organic Frameworks for Stable and Efficient Photothermal Conversion.

Tetrathiafulvalene (TTF) and Ni-bis(dithiolene) are typical conductive units widely studied in electronics, optics, and photochemistry. However, their applications in near-infrared (NIR) photothermal conversion are often limited by insufficient NIR absorption and low chemical/thermal stability. Herein, we integrate TTF and Ni-bis(dithiolene) into a covalent organic framework (COF) with stable and efficient NIR and solar photothermal conversion performance. Two isostructural COFs, namely Ni-TTF and TTF-TTF, are successfully isolated which are composed of TTF and Ni-bis(dithiolene) units as donor-acceptor (D-A) pairs or TTF units only. Both COFs show high BET surface areas and good chemical/thermal stability. Notably, compared with TTF-TTF, the periodic D-A arrangement in Ni-TTF significantly lowers the bandgap, leading to unprecedented NIR and solar photothermal conversion performance.

Access to and reactions of P-functional 1,4-dihydro-1,4-diphosphinines fused to two TTF units.

P-Functional phosphanylated tetrathiafulvalenes 3a-f were synthesised via stepwise lithiation and phosphanylation of TTF derivatives, and then reacted with PCl3 to form the related P-chloro compounds 4a-f. Reactions of 4c-f with LDA resulted in the formation of the corresponding 1,4-dihydro-1,4-diphosphinines 5c-f. As a case in point, P-oxidation reactions of 5d,f with elemental chalcogens were performed, and the former were also converted into 1,4-dichloro-1,4-dihydro-1,4-diphosphinine 9f. The latter was reduced to form the related 1,4-diphosphinine 10f which could not be isolated but formed the corresponding 1,4-diphosphabarrelene 11f in a [4 + 2]-cycloaddition with 1-hexene. All compounds were characterised by multinuclear NMR spectroscopy and mass spectrometry and also by single crystal X-ray diffraction studies in some cases. Intensive cyclic voltammetry studies were performed for all isolated compounds with the special focus on using TTF units as sensors to study the substituent effects on oxidation potentials and, hence, the degree of electronic communication between redox active moieties in the bis-TTF species. E.g., 5d possesses four quasi-reversible one-electron oxidation steps thus forming a tetracation species at highest potential (+0.54 V vs. Fc+/0). Additionally, high level DFT calculations were undertaken to get a deeper understanding of various aspects of this novel combination of phosphorus and TTF chemistry.

Progressive framework designing and photocurrent responsive tuning based on tetra(4-pyridyl)-tetrathiafulvalene ligand

Although metal−organic frameworks (MOFs) based on redox-active tetrathiafulvalene (TTF) unit show good photocurrent performance, related reports about systematically elucidating the relationship between framework and photocurrent propriety are still scarce. Herein, three topologically and dimensionally tunable MOFs based on the redox active tetra(4-pyridyl)-tetrathiafulvalene (TTF(py)4), terephthalic acid (TPA), 4,4′-biphenyldicarboxylic acid (BDA) and 4,4′-oxybisbenzoic acid (OBA) ligand, namely as [Cd(TTF(py)4)2(TPA)2]n (1), [Zn(TTF(py)4)2(BDA)2]n (2) and {[Zn(TTF(py)4)2(OBA)2] H2O}n (3), were prepared via utilizing solvothermal method. Single crystal diffraction analysis showed that the structural adjustment of auxiliary ligands can realize the supramolecular networks with different dimensions well. The rod-shaped auxiliary ligands can endow MOFs (complex 1 and 2) with better three-dimensional (3D) extension skeleton. As a comparison, the fold-like auxiliary ligand (OBA) enabled complex 3 to extend along the two-dimensional (2D) backbone. In addition, all complexes exhibit redox activity and photocurrent responsive properties. Interestingly, complex 3 linking by fold-like auxiliary ligand shows nearly 10 times higher photocurrent intensity than traditional TTF unit. This work sheds some light on the construction of complexes with high photocurrent response properties through rational tuning of MOFs dimensions.

Self‐Assembly Construction of Carbon Nanotube Network‐Threaded Tetrathiafulvalene‐Bridging Covalent Organic Framework Composite Anodes for High‐Performance Hybrid Lithium‐Ion Capacitors

Hybrid lithium‐ion capacitors (HLICs), a special class of electrochemical energy storage devices composed of battery‐type anodes and capacitor‐type cathodes, have the potential to bridge the gap between high‐energy‐density batteries and high‐power‐density capacitors. Nevertheless, the key challenge for developing high‐performance HLICs is the imbalances of the electrochemical kinetics and lifespans between the battery‐type anodes and capacitor‐type cathodes. Herein, the self‐assembly preparation of the 3D‐crosslinked carbon nanotube (CNT) network‐threaded tetrathiafulvalene‐bridging covalent organic framework (TTF‐COF) composite via in situ growth of the 2D‐stacked TTF‐COF capping layer alongside the outer walls of 3D‐interlaced CNTs is reported. Originated for the electron‐donating and redox‐switchable TTF units, the TTF‐COF component has abundant active sites and high charge conductivity for reversible Li+ storage. Moreover, due to the 3D‐assembled architecture, the TTF‐COF/CNT composite possesses abundant open nanochannels for ion transfer and 3D‐interconnected conductive CNT network for electron transfer. When used in HLICs, the TTF‐COF/CNT composite anodes exhibit ultrahigh specific capacity (609 mAh g−1 at 100 mA g−1) and outstanding power density (12 000 W kg−1 at 4000 mA g−1). Herein, the design of advanced COF composite materials with high activity, porosity, and conductivity can be a promising route for boosting the overall performances of high‐power‐type energy storage devices.

Tetrathiafulvalenes as anchors for building highly conductive and mechanically tunable molecular junctions

The interface between molecules and electrodes has great impact on charge transport of molecular devices. Precisely manipulating the structure and electronic coupling of electrode-molecule interface at a molecular level is very challenging. Here, we develop new molecular junctions based on tetrathiafulvalene (TTF)-fused naphthalene diimide (NDI) molecules which are anchored to gold electrodes through direct TTF-Au contacts formed via Au-S bonding. These contacts enable highly efficient orbital hybridization of gold electrodes and the conducting π-channels, yielding strong electrode-molecule coupling and remarkably high conductivity in the junctions. By further introducing additional thiohexyl (SHe) anchors to the TTF units, we develop molecular wires with multiple binding sites and demonstrate reversibly switchable electrode-molecule contacts and junction conductance through mechanical control. These findings show a superb electrode-molecule interface and provide a new strategy for precisely tunning the conductance of molecular devices towards new functions.

A Tetrathiafulvalene/Naphthalene Diimide-Containing Metal-Organic Framework with fsc Topology for Highly Efficient Near-Infrared Photothermal Conversion.

Metal-organic frameworks (MOFs) provide broad prospects for the development of new photothermal conversion materials, while their design and synthesis remain challenging. A new Zn-MOF (1) containing both tetrathiafulvalene (TTF) as an electron donor and naphthalene diimide (NDI) as an electron acceptor was constructed by using a space limiting effect. The material exhibited wide absorption peaks in the near-infrared region, indicating that there was strong charge transfer interaction between the TTF and NDI units and providing the possibility of photothermal conversion. 1 shows efficient near-infrared photothermal conversion performance. Under 808 nm laser (0.4 W cm-2) illumination, the temperature of 1 increased rapidly from room temperature to 250 °C, with good thermal stability and cycle durability. This work provides an efficient strategy for promising materials in photothermal therapy.

Iron(II) Spin Crossover Coordination Polymers Derived From a Redox Active Equatorial Tetrathiafulvalene Schiff-Base Ligand.

Two polymorphic FeII coordination polymers [FeIIL (TPPE)0.5] 1) and [(FeII 3L3 (TPPE)1.5)] 2), were obtained from a redox-active tetrathiafulvalene (TTF) functionalized ligand [H2L = 2,2’-(((2-(4,5-bis-(methylthio)-1,3-dithiol-2-ylidene)benzo(d) (1,3) dithiole-5,6-diyl)bis-(azanediyl))bis-(meth anylylidene)) (2E,2E')-bis(3-oxobutanoate)] and a highly luminescent connector {TPPE = 1,1,2,2-tetrakis[4-(pyridine-4-yl)phenyl]-ethene}. Complex 1 has a layered structure where the TPPE uses its four diverging pyridines from the TPPE ligand are coordinated by the trans positions to the flat TTF Schiff-base ligand, and complex 2 has an unprecedented catenation of layers within two interpenetrated frameworks. These coordination polymers reserved the redox activity of the TTF unit. Complex 1 shows gradual spin transition behavior without hysteresis. And the fluorescence intensity of TPPE in 1 changes in tandem with the spin crossover (SCO) transition indicating a possible interplay between fluorescence and SCO behavior.

π-Conjugated Molecules Containing Tetrathiafulvalene and Benzo[b]phosphole Oxide: Synthesis, Structure, and Electrochemical and Optical Properties

Three new π-conjugated molecules containing a tetrathiafulvalene (TTF) unit and a benzo[b]phosphole oxide unit were successfully synthesized. X-ray structural analysis revealed that the benzo[b]phosphole oxide unit exhibits high planarity, whereas the TTF unit adopts a bending structure. Electrochemical analysis by cyclic voltammetry revealed two pairs of redox waves derived from the TTF site. The absorption bands were almost identical to those of the TTF and benzo[b]phosphole oxide moieties, although their fluorescence was significantly quenched by intramolecular electron transfer.

Synthesis and Properties of Fused Extended Tetrathiafulvalene Donors with Dithienylmethylene Spacer and Application to Organic Rechargeable Batteries

Abstract Several derivatives of 1,3-dithiole[3]dendralene derivatives with two thiophene spacers (2) were synthesized. The results of an X-ray structure analysis of an analog without fused TTF units and a DFT calculation of the unsubstituted-2 (2Aa) suggested that 2Aa had a structure significantly distorted between the central 1,3-dithiole (DT) ring and one of the thiophene rings. Cyclic voltammograms of tetrakis(n-hexylsulfanyl) derivatives (2Be and 2Ce) consisted of one pair of two-electron redox waves and five pairs of one-electron redox waves in correspondence with the presence of seven redox-active DT rings. The tetrakis(methylsulfanyl) or bis(ethylenedithio) derivative (2Bc or 2Bd) worked as a positive electrode material for lithium-ion batteries, and the 2Bc/Li and 2Bd/Li cells exhibited the first discharge capacities of 133–138 mAh g−1.

A Tris-fused Tetrathiafulvalene Analog Composed of an Anthraquinoid- and Two Vinyl-extended Tetrathiafulvalenes

Derivatives of a new tris-fused donor composed of two vinyl-extended TTF (EBDT) units and one extended TTF with an anthraquinoid spacer (TTFAQ) (3a–c and 4a) were successfully synthesized. X-ray structure analysis of the tetrakis(methylsulfanyl) derivative 3b revealed that the TTFAQ unit adopts the so-called saddle conformation similar to most the neutral TTFAQs, and that half of the 3b molecules are stacked with each other. Cyclic voltammetry suggested that two positive charges in 3b2+ and 4a2+ were mainly distributed on the EBDT units, while two positive charges of 3c2+ were mainly located on the TTFAQ unit.

Benzo-Tetrathiafulvalene- (BTTF-) Annulated Expanded Porphyrins: Potential Next-Generation Multielectron Reservoirs.

Two sterically crowded benzo-tetrathiafulvalene (BTTF)-annulated expanded porphyrins (BTTF7-F and BTTF8) are synthesized. Detailed photophysical investigations reveal their intrinsic intramolecular charge transfer (CT) character, originated from partial electron transfer from electron-rich TTF units to the relatively electron-deficient macrocyclic core. This finding stands in contrast to what was observed in the previously reported Figure-of-eight conformer of BTTF-annulated [28]hexaphyrin (BTTF6), in which a typical π-π* electronic transition from HOMO to LUMO was observed. However, core expansion in BTTF7-F and BTTF8 makes the oligopyrrole macrocyclic cores relatively more electron-deficient, facilitating the effective intramolecular CT process. Comparative electrochemical investigations reveal that the current generated at the oxidative region is directly proportional to the number of TTF units attached to the macrocyclic core. This work demonstrates the control of the intramolecular CT process through incremental addition of TTF units to the macrocyclic core. Facile multielectron electrochemical oxidations of these expanded porphyrins suggest that they behave like potential multielectron reservoirs.

Synthesis and properties of supramolecular gels based on tetrathiafulvalene and cyanobiphenyl units

ABSTRACT For the development of self-assembly donor-σ-acceptor (D-σ-A) molecules, a series of D-σ-A low-molecular mass organogelators, consisting of tetrathiafulvalene (D) and cyanobiphenyl (A) connected by a thioalkanoyloxy spacer of varying lengths modified with hydrophobic chains incorporating amide groups on the side, was designed and readily synthesized. Their gelation properties were studied. The results showed that the gelation capability of these compounds was highly dependent on the alkyl chain length in the spacer group and the TTF and cyanobiphenyl units. Derivative 1a with short alkyl chain (n = 4) efficiently gelated in some aromatic solvents, forming opaque organogels. These gelators reacted with F4TCNQ to form stable charge-transfer complex gels in ethanol. Clear evidence of self-assembled micro/nanoflower, fibrous, or tubular morphologies in gelation state was obtained by scanning electron microscopy. It was found that the molecules adopted lamellar and rectangular columnar molecular packing models in the gel phase by X-ray diffraction. The native gels underwent a reversible gel-sol phase transition upon exposure to external stimuli. The gel-sol transition of the organogel was stimulated by the addition of fluoride anions. Interestingly, all gels showed an irreversible gel-sol transition triggered by TFA and TEA. The formation of flower-like morphologies of TTF-based derivatives in the gel state was observed.

Synthesis, electropolymerization, and electrochromic performances of two novel tetrathiafulvalene–thiophene assemblies

Abstract 6,7-Bis(hexylthio)-2-[(2-hydroxyethyl)thio]-3-methylthio-tetrathiafulvalene (TTF-2) is coupled with thiophene-3-carboxylic acid and thiophene-3,4-dicarboxylic acid by Steglich esterification, respectively, to afford 2-((4′,5′-bis(hexylthio)-5-(methylthio)-[2,2′-bi(1,3-dithiolylidene)]-4-yl)thio)ethyl thiophene-3-carboxylate (TTF-Th) and bis(2-((4′,5′-bis(hexylthio)-5-(methylthio)-[2,2′-bi(1,3-dithiolylidene)]-4-yl)thio)ethyl)thiophene-3,4-di-carboxylate (DTTF-Th). Their structures were characterized by ESI-MS, 1H NMR, and elemental analysis. Electropolymerization of TTF-Th and DTTF-Th was conducted with 0.1 M n-Bu4NPF6. The results indicated that both assemblies could rapidly form polymers via electrochemical deposition. In addition, their electrochromic performances illustrated that the color of P(TTF-Th) could switch from orange-yellow to dark blue, while P(DTTF-Th) changed its color from orange in the neutral state to dark blue in the oxidation state. Moreover, the electrochromic performances of P(DTTF-Th) were better than P(TTF-Th) due to the introduction of one extra TTF unit.

Twisted chromophore assist to tetrathiafulvalene-spiropyran hybrid driving four-state molecular switch

A series of novel molecular hybrids, in which tetrathiafulvalene (TTF) unit and spiropyran (SP) core are covalently linked to various typical π-conjugated bridges, has been designed based on auxiliary donors and acceptors model and twisted intramolecular charge transfer (TICT) strategy. And the second-order nonlinear optical (NLO) responses of these molecular hybrids have been investigated by using density functional theory (DFT) calculations. The results show that grafting of the TTF unit and SP core to the twisted chromophore (TC) can effectively enhances second-order NLO responses. The promoting effect of enhancing NLO response can be attributed to a strongly favorable charge transfer in TTF-TC-SP hybrid. More importantly, we have found that this TTF-TC-SP hybrid with donor-π-conjugated bridge-acceptor structure can efficiently switch the first hyperpolarizability across four states via redox and photochemical stimuli. Meanwhile, time-dependent (TD) DFT calculations were carried out to probe the origin of the second-order NLO response of TTF-TC-SP molecular hybrid. All these findings provide a clear and well understanding of the relationship between the tunable first hyperpolarizability and electronic structure. We hope these findings would be very useful to guide the search for potential polymorphic molecular switch.

Iron(II) Spin Crossover Complexes Based on a Redox Active Equatorial Schiff-Base-Like Ligand.

In this work, two iron(II) coordination compounds with a N2O2 coordinating Schiff base-like ligand bearing a redox active tetrathiafulvalene (TTF) unit and pyridine or trans-1,2-bis(4-pyridylethylene) as an axial ligand are synthesized. Crystals suitable for single X-ray structure analysis were obtained for the new ligand. The complexes were characterized by magnetic susceptibility measurements, T-dependent UV-vis spectroscopy, and cyclic voltammetry. Both complexes display spin transition behavior below room temperature with T1/2 values of 146 and 156 K. The mononuclear iron(II) complex [FeTTFL(py)2] is relatively stable up to 400 K compared to similar complexes, showing no loss of axial ligands upon heating. Temperature dependent Mössbauer spectroscopy was conducted for the coordination polymer {[FeTTFL(bpee)]}n to get more information regarding the origin of the stepwise spin crossover (SCO) behavior observed in the magnetic measurements. The change of the spin state is accompanied by a change of the optical properties, which can be monitored by VT-UV-vis spectroscopy for the mononuclear complex and has been analyzed in theoretical studies. The redox behavior of the iron(II) complexes reveals three reversible redox steps which are located at the iron center and at the TTF unit of the ligand. Oxidation of the TTF unit induces characteristic changes in the UV-vis spectrum that can be followed by spectroelectrochemical UV-vis spectroscopy. Addressing the potential of the iron-centered redox process results in similar changes in the UV-vis spectrum, which indicates an electronic coupling of the redox active unit with the metal center under certain circumstances.

Redox, transmetalation, and stacking properties of tetrathiafulvalene-2,3,6,7-tetrathiolate bridged tin, nickel, and palladium compounds.

Here we report that capping the molecule TTFtt (TTFtt = tetrathiafulvalene-2,3,6,7-tetrathiolate) with dialkyl tin groups enables the isolation of a stable series of redox congeners and facile transmetalation to Ni and Pd. TTFtt has been proposed as an attractive building block for molecular materials for two decades as it combines the redox chemistry of TTF and dithiolene units. TTFttH4, however, is inherently unstable and the incorporation of TTFtt units into complexes or materials typically proceeds through the in situ generation of the tetraanion TTFtt4−. Capping of TTFtt4− with Bu2Sn2+ units dramatically improves the stability of the TTFtt moiety and furthermore enables the isolation of a redox series where the TTF core carries the formal charges of 0, +1, and +2. All of these redox congeners show efficient and clean transmetalation to Ni and Pd resulting in an analogous series of bimetallic complexes capped by 1,2-bis(diphenylphosphino)ethane (dppe) ligands. Furthermore, by using the same transmetalation method, we synthesized analogous palladium complexes capped by 1,1′-bis(diphenylphosphino)ferrocene (dppf) which had been previously reported. All of these species have been thoroughly characterized through a systematic survey of chemical and electronic properties by techniques including cyclic voltammetry (CV), ultraviolet-visible-near infrared spectroscopy (UV-vis-NIR), electron paramagnetic resonance spectroscopy (EPR), nuclear magnetic resonance spectroscopy (NMR) and X-ray diffraction (XRD). These detailed synthetic and spectroscopic studies highlight important differences between the transmetalation strategy presented here and previously reported synthetic methods for the installation of TTFtt. In addition, the utility of this stabilization strategy can be illustrated by the observation of unusual TTF radical–radical packing in the solid state and dimerization in the solution state. Theoretical calculations based on variational 2-electron reduced density matrix methods have been used to investigate these unusual interactions and illustrate fundamentally different levels of covalency and overlap depending on the orientations of the TTF cores. Taken together, this work demonstrates that tin-capped TTFtt units are ideal reagents for the installation of redox-tunable TTFtt ligands enabling the generation of entirely new geometric and electronic structures.

Fabrication of Nanostructures Composed of Tetrathiafuluvalene Derivatives with Various Side Chains

Design of molecules for specific functions and their structural control in a nanoscale have attracted much interest for device downsizing as well as development of complex and multi-functional devices. In order to obtain nanostructures in various dimensions, supramolecular approaches are quite useful because of the structural flexibility. Furthermore, appropriate design of the constituent molecules may amplify and/or combine their specific functions in the supramolecular systems by proper molecular orientation and intermolecular interaction. Tetrathiafulvalene (TTF) is a strong electron donor, and its complexes with various kinds of electron acceptors are known to become semiconductors, metals and superconductors. In our previous studies, we found that introduction of appropriate substituents with a hydrogen-bonding group to the TTF moiety resulted in formation of its one-dimensional (1D) stacks to form nanofibers. Charge-transfer (CT) complexes of the TTF derivatives were also found to form 1D structures, which was considered as conducting nanowires useful for molecular electronics. In addition, if we can control reversible conformational changes of the molecules in nanowires by external stimuli such as light, electric or magnetic field and heat, the induced motions can be applied for molecular machines as well as switching devices. In this study, we synthesized the TTF derivatives having various side chains as shown in Figure 1A and their self-organization was investigated. Also, the CT complexes were prepared by mixing the TTF derivatives with various acceptor molecules and their electrical properties were evaluated. Characteristics of the mono-TTF compounds 1a–1d are as follows. For all compounds, π-π interaction between TTF moieties is expected. In addition, 1b–1d have phenyl rings which also induce π-π interactions between them. For 1c, cinnamoyl groups in adjacent molecules can react to form a cyclobutane ring by UV irradiation, and this reaction may be useful to fix the supramolecular structures. Amide groups for intermolecular hydrogen-bonding in 1b and 1d are also important to form molecular stacking arrays. Chiral centers in these compounds were introduced for the helical structure formation. The terminal ferrocene moiety in 1d is electrochemically active species, which can be utilized as a stimulus-responsive part. The CT complexes were prepared by mixing the TTF derivatives and F2TCNQ or F4TCNQ. In any combinations, new absorption bands were observed between 600 and 900 nm, suggesting formation of the CT complexes. The nanostructures of the TTF derivatives and their CT complexes were prepared by casting the corresponding toluene solution on HOPG substrates. Although 1b formed nanofibers, 1a, 1c and 1d became amorphous films or nanodots. Among these three compounds, 1a and 1c do not have relatively strong interactions like hydrogen bonding in their substituents. This indicates that the π-π interaction between TTF moieties is not enough to form the 1D nanostructure in general. In the case of 1d with amide groups, the bulky ferrocene groups at the end of the substituents seems to weaken the intermolecular hydrogen bonding, and the 1D nanostructure was not fabricated. Therefore, in order to intensify the π-π interaction of the core part, we synthesized compounds 2a–2d in which TTF units are dimerized with a disulfide bond. The crystallinity of 2a–2d was improved in comparison with the corresponding mono-TTF compounds. By SEM observation, it was confirmed that 2a and 2d formed nanoribbons having the width of about 800 nm and nanofibers having the width of about 200 nm, respectively (Figure 1B). This result suggested that intermolecular interaction was enhanced by the dimerized TTF structure with stronger π-π stacking. Thus, nanofiber formation became possible even in the compound with bulky substituents. In addition, the CT complexes of 2a–2d with F2TCNQ or F4TCNQ were prepared and their nanostructures were observed. Except for the CT complex using 2c, we confirmed the nanofiber formation. All of the CT complexes were found to show conductivity at the semiconductor level of 10-2–10-3 S m-1. Figure 1

Synthesis, Characterization, and Self-Assembly of a Tetrathiafulvalene (TTF)–Triglycyl Derivative

In this work, we describe the synthesis, characterization, and self-assembly properties of a new tetrathiafulvalene (TTF)–triglycyl low-molecular-weight (LMW) gelator. Supramolecular organogels were obtained in various solvents via a heating–cooling cycle. Critical gelation concentrations (CGC) (range ≈ 5–50 g/L) and thermal gel-to-sol transition temperatures (Tgel) (range ≈ 36–51 °C) were determined for each gel. Fourier transform infrared (FT-IR) spectroscopy suggested that the gelator is also aggregated in its solid state via a similar hydrogen-bonding pattern. The fibrillar microstructure and viscoelastic properties of selected gels were demonstrated by means of field-emission electron microscopy (FE-SEM) and rheological measurements. As expected, exposure of a model xerogel to I2 vapor caused the oxidation of the TTF unit as confirmed by UV-vis-NIR analysis. However, FT-IR spectroscopy showed that the oxidation was accompanied with concurrent alteration of the hydrogen-bonded network.

Intermolecular Electronic Communication in Tetrathiafulvalene Derivatives with Hydrogen‐Bonding Amide Units

AbstractAs a basis for the design of electroactive materials, mono‐ and bis‐tetrathiafulvalene (TTF) derivatives with one and two amide units were prepared to investigate how hydrogen bonding induces electronic communication. The bis‐TTF compound exhibited a mixed‐valence state as a result of electronic interactions among the TTF units. Comparison with non‐hydrogen‐bonding N‐methylated analogues indicated that the electronic interaction observed occurs between intermolecular TTF units owing to the formation of supramolecular assemblies induced by hydrogen bonds.

Anderson-Type Polyoxometalates Functionalized by Tetrathiafulvalene Groups: Synthesis, Electrochemical Studies, and NLO Properties.

Three polyoxometalates (POMs) functionalized by tetrathiafulvalene (TTF) molecules have been synthesized by a coupling reaction between the Anderson-type POMs [MnMo6O18{(OCH2)3CNH2}2]3- or [AlMo6O18(OH)3{(OCH2)3CNH2}]3- and the TTF carboxylic acid derivative (MeS)3TTF(S-CH2-CO2H). The monofunctionalized TTF-AlMo6 POM contains one TTF group covalently grafted on an Al Anderson platform. The symmetrical TTF-MnMo6-TTF POM possesses two TTF groups grafted on each side of a Mn Anderson derivative while the asymmetrical TTF-MnMo6-SP POM contains a TTF and a spiropyran groups. These three trianionic species have been characterized by elemental analysis, 1H and 13C NMR, FT-IR spectroscopy, ESI-MS spectrometry, and single-crystal X-ray diffraction (for TTF-MnMo6-TTF). In the solid state, the grafted TTF molecules of TTF-MnMo6-TTF POMs interact via S···S and π···π interactions and form chains. The electrochemical properties of the complexes reflect the contributions of both the inorganic POM and the TTF moieties. Despite adsorption of the oxidized hybrid species on the Pt grid working electrode, UV-vis-NIR spectroelectrochemical investigations evidence peaks characteristic of the oxidation of the TTF units. Finally, hyper-Rayleigh scattering (HRS) measurements show that the three novel TTF derivatives exhibit β values between 20 and 37 × 10-30 esu. Moreover it is observed that the oxidation of the TTF moieties by Fe3+ ions increases the NLO response. These values are in the order of magnitude of that found for the well-known 4-dimethylamino- N-methyl-4-stilbazolium (DAS+) cation (β = 60 × 10-30 esu).