Anthony L. Appleton

Integrated materials design of organic semiconductors for field-effect transistors.

The past couple of years have witnessed a remarkable burst in the development of organic field-effect transistors (OFETs), with a number of organic semiconductors surpassing the benchmark mobility of 10 cm(2)/(V s). In this perspective, we highlight some of the major milestones along the way to provide a historical view of OFET development, introduce the integrated molecular design concepts and process engineering approaches that lead to the current success, and identify the challenges ahead to make OFETs applicable in real applications.

Flexible polymer transistors with high pressure sensitivity for application in electronic skin and health monitoring

Flexible pressure sensors are essential parts of an electronic skin to allow future biomedical prostheses and robots to naturally interact with humans and the environment. Mobile biomonitoring in long-term medical diagnostics is another attractive application for these sensors. Here we report the fabrication of flexible pressure-sensitive organic thin film transistors with a maximum sensitivity of 8.4 kPa(-1), a fast response time of <10 ms, high stability over >15,000 cycles and a low power consumption of <1 mW. The combination of a microstructured polydimethylsiloxane dielectric and the high-mobility semiconducting polyisoindigobithiophene-siloxane in a monolithic transistor design enabled us to operate the devices in the subthreshold regime, where the capacitance change upon compression of the dielectric is strongly amplified. We demonstrate that our sensors can be used for non-invasive, high fidelity, continuous radial artery pulse wave monitoring, which may lead to the use of flexible pressure sensors in mobile health monitoring and remote diagnostics in cardiovascular medicine.

High Performance All-Polymer Solar Cell via Polymer Side-Chain Engineering

Acknowledge support from the Office of Naval Research (N00014-14-1-0142), KAUST Center for Advanced Molecular Photovoltaics at Stanford and the Stanford Global Climate and Energy Program, NSF DMR-1303742 and the National Natural Science Foundation of China (Projects 21174004 and 21222403). Soft X-ray characterization and analysis by NCSU supported by the U.S. Department of Energy, Office of Science, Basic Energy Science, Division of Materials Science and Engineering under Contract DE-FG02-98ER45737. Soft X-ray data was acquired at beamlines 11.0.1.2 at the Advanced Light Source, which is supported by the Director, Office of Science, Office of Basic Energy Sciences, of the U. S. Department of Energy under Contract No. DE-AC02-05CH11231. We thank Professor Michael D. McGehee, Dr. George F. Burkhard and Dr. Eric T. Hoke for their help in discussion of the recombination mechanism.

Highly stable organic polymer field-effect transistor sensor for selective detection in the marine environment.

In recent decades, the susceptibility to degradation in both ambient and aqueous environments has prevented organic electronics from gaining rapid traction for sensing applications. Here we report an organic field-effect transistor sensor that overcomes this barrier using a solution-processable isoindigo-based polymer semiconductor. More importantly, these organic field-effect transistor sensors are stable in both freshwater and seawater environments over extended periods of time. The organic field-effect transistor sensors are further capable of selectively sensing heavy-metal ions in seawater. This discovery has potential for inexpensive, ink-jet printed, and large-scale environmental monitoring devices that can be deployed in areas once thought of as beyond the scope of organic materials.

Effects of electronegative substitution on the optical and electronic properties of acenes and diazaacenes

Large acenes, particularly pentacenes, are important in organic electronics applications such as thin-film transistors. Derivatives where CH units are substituted by sp(2) nitrogen atoms are rare but of potential interest as charge-transport materials. In this article, we show that pyrazine units embedded in tetracenes and pentacenes allow for additional electronegative substituents to induce unexpected redshifts in the optical transitions of diazaacenes. The presence of the pyrazine group is critical for this effect. The decrease in transition energy in the halogenated diazaacenes is due to a disproportionate lack of stabilization of the HOMO on halogen substitution. The effect results from the unsymmetrical distribution of the HOMO, which shows decreased orbital coefficients on the ring bearing chlorine substituents. The more strongly electron-accepting cyano group is predicted to shift the transitions of diazaacenes even further to the red. Electronegative substitution impacts the electronic properties of diazaacenes to a much greater degree than expected.

Stable Hexacenes through Nitrogen Substitution

The stabilization of larger acenes is a demanding task both synthetically as well as conceptually to be solved in different ways. Neither unsubstituted hexacene nor its higher homologues are stable, but their existence can be demonstrated in suitable matrixes. In the case of pentacene, two strategically attached TIPS-ethynyl groups suffice to fully stabilize and solubilize this material (TIPS = triisopropylsilyl). In larger acenes, however, two TIPS-ethynyl groups do not provide enough stabilization to furnish long-term persistent representatives. Anthony et al. demonstrated that even sterically encumbered hexacenes (with two tris(trimethylsilyl)silylethynyl substituents) react in solution under butterfly dimerization with a half-life of around 20 minutes. Only the introduction of four more aryl groups in lateral positions increases the stability of higher acenes so far that the Wudl and Chi groups could obtain persistent heptacene derivatives with a half-life of up to one week in solution. But even here, formation of endoperoxides is observed after some time. The laterally attached phenyl groups lead to isolation of the p systems with respect to their next neighbors, as evidenced by single-crystal structure analysis. We demonstrate herein that nitrogen atoms introduced into the acene skeleton give persistent disubstituted heterohexacenes, which are stable even when stored for longer periods of time. The palladium-catalyzed coupling of 1 with 2 in the presence of the ligand L gave the tetrazaacene 3 after oxidation with MnO2 in good yields (Scheme 1). [8, 9] The dichlorobenzoquinoxaline 4 also couples in good yields to give 5 (Scheme 2) However, attempts to oxidize 5 by MnO2, IBX = 2-iodoxybenzoic acid, N-bromosuccinimide (NBS), potassium chromate, pyridinium chlorochromate (PCC), or Cu(OAc)2 were fruitless. Difficult-to-separate product mixtures formed, but not the desired acene. This behavior was not entirely unexpected, as Kummer and Zimmermann had already unsuccessfully attempted to oxidize 6, readily obtained by co-melting of diaminonaphthalene and dihydroxyanthracene at 220 8C, using chloroanil or PbO2. Azahexacenes remained unknown. To maximize the shielding effect of the TIPS groups, it might be better to attach them in the center of the molecule. Consequently, 7a,b were coupled to 2 (Scheme 3). The Pdcatalyzed coupling works very well in the presence of L and furnishes 8a,b in good to excellent yields (92 %, 56%). Both are dehydrogenated by MnO2 into the azaacens 9 a,b in 56% and 74% yield, but it is not clear why this reaction does not work for 5. The heteroacenes 9a and 9b are greenish black crystalline powders, stable under laboratory conditions both as solids and in solutions, which display a green-yellow color. By NMR spectroscopy we could not detect endoperoxide formation or dimerization of 9 to butterfly cycloadducts. In our case, triisopropylsilyl and even the triethylsilyl groups are sufficient to stabilize and solubilize the hexacene skeleton, but 9b is considerably less soluble than 9a. To extend this chemistry, we prepared 7c in a multistep synthesis starting from diaminoScheme 1. Palladium-catalyzed synthesis of 3. dba = dibenzylideneacetone.

6,13-Diethynyl-5,7,12,14-tetraazapentacene

A new relative of pentacene: The dialkynylated tetraazapentacene (see figure) was prepared by a two-step synthesis from the corresponding quinone derivative. The heteroacene is an air-stable, dark-blue, crystalline material and is of great interest as a potential organic n-electron-transport material.

Lead candidates for high-performance organic photovoltaics from high-throughput quantum chemistry - the Harvard Clean Energy Project

The virtual high-throughput screening framework of the Harvard Clean Energy Project allows for the computational assessment of candidate structures for organic electronic materials – in particular photovoltaics – at an unprecedented scale. We report the most promising compounds that have emerged after studying 2.3 million molecular motifs by means of 150 million density functional theory calculations. Our top candidates are analyzed with respect to their structural makeup in order to identify important building blocks and extract design rules for efficient materials. An online database of the results is made available to the community.

Alkynylated aceno[2,1,3]thiadiazoles.

Enlarged acenothiadiazoles, which are easily prepared, display attractive optical and electrochemical properties. The annulation of thiadiazole to anthracene gives a stable material with optical properties similar to those of substituted pentacenes.

Synthesis and Optical Properties of Diaza‐ and Tetraazatetracenes

A series of functionalized diaza- and tetraazatetracenes was synthesized, either by condensation of an aromatic diamine with an ortho-quinone/diethyloxalate followed by chlorination with POCl(3) to give diazatetracenes or by palladium-catalyzed coupling of a phenylenediamine with various 2,3-dichloroquinoxalines to give tetraazatetracenes (after oxidation with MnO(2)). Representative examples included halogenated and nitrated derivatives. The optical properties of these azatetracenes were discussed with respect to their molecular structures and substitution patterns. The diazatetracenes and tetraazatetracenes formed two different groups that had significantly different electronic structures and properties. Furthermore, 1,2,3,4-tetrafluoro-6,11-bis((triisopropylsilyl)ethynyl)benzo[b]phenazine was synthesized, which is the first reported fluorinated diazatetracene. Single-crystal X-ray analysis of this compound is reported.