Your search keyword '"R. Pfattner"' showing total 34 results

1. Inkjet-printed stretchable and low voltage synaptic transistor array

Author

F. Molina-Lopez, T. Z. Gao, U. Kraft, C. Zhu, T. Öhlund, R. Pfattner, V. R. Feig, Y. Kim, S. Wang, Y. Yun, and Z. Bao

Subjects

Science

Abstract

The development of novel low-cost fabrication schemes for realizing stretchable transistor arrays with applicability in wearable electronics remains a challenge. Here, the authors report skin-like electronics with stretchable active materials and devices processed exclusively from ink-jet printing.

Published

2019

2. Organic metal-organic semiconductor blended contacts in single crystal field-effect transistors for a significant improvement of the device performance

Author

R. Pfattner, M. Mas Torrent, C. Moreno, J. Puigdollers, R. Alcubilla, V. Laukhin, J. Veciana, C. Rovira, BILOTTI, IVANO, VENUTI, ELISABETTA, BRILLANTE, ALDO, R. Pfattner, M. Mas-Torrent, C. Moreno, J. Puigdoller, R. Alcubilla, I. Bilotti, E. Venuti, A. Brillante, V. Laukhin, J. Veciana, and C. Rovira

Subjects

SELF-ASSEMBLED MONOLAYERS, ORGANIC ELECTRODES, DITHIOPHENE-TETRATHIAFULVALENE, HIGH-PERFORMANCE FET

Abstract

A novel approach to blend organic source and drain electrodes with semiconducting organic single crystals in field is described. The devices fabricated show a very high performance which is ascribed to a notable reduction of the contact resistance as measured by Kelvin probe microscopy. The average mobility is found to be four-fold that obtained from devices whereno interprenetration of the two materials takes place. This work highlights therefore the importance of the contacts in organic field effects transistors not only in terms of the alignments of the energy levels but also with respect to the interface morphology.

Published

2012

3. High performance single crystal OFETs based on two dithiophene-tetrathiafulvalene (DT-TTF) polymorphs

Author

R. Pfattner, M. Mas Torrent, S. Milita, F. Liscio, T. Marszalek, J. Ulański, A. Nosal, M. Gazicki Lipman, M. Leufgen, G. Schmidt, L. W. Molenkamp, V. Laukhin, J. Veciana, C. Rovira, BILOTTI, IVANO, BRILLANTE, ALDO, BISCARINI, FABIO, R. Pfattner, M. Mas-Torrent, I. Bilotti, A. Brillante, S. Milita, F. Liscio, F. Biscarini, T. Marszalek, J. Ulański, A. Nosal, M. Gazicki-Lipman, M. Leufgen, G.Schmidt, L. W. Molenkamp, V. Laukhin, J. Veciana, and C. Rovira

Published

2010

4. Experimental and theoretical studies of the electronic transport of an extended curcuminoid in graphene nano-junctions.

Author

Cardona-Lamarca T, Baum TY, Zaffino R, Herrera D, Pfattner R, Gómez-Coca S, Ruiz E, González-Campo A, van der Zant HSJ, and Aliaga-Alcalde N

Abstract

Exploiting the potential of curcuminoids (CCMoids) as molecular platforms, a new 3.53 nm extended system (pyACCMoid, 2) has been designed in two steps by reacting a CCMoid with amino-terminal groups (NH 2 -CCMoid, 1, of 1.79 nm length) with polycyclic aromatic hydrocarbon (PAH) aldehydes. CCMoid 2 contains pyrene units at both ends as anchoring groups to optimize its trapping in graphene nano-junctions created by feedback-controlled electro-burning. The measured I - V characteristics show gate-dependent behaviour at room temperature and 10 K, with increased conductance values compared to shorter CCMoids previously reported, and in agreement with DFT calculations. Our results show that the adjusted molecular design improves the conductance, as system 2 separates the conductive backbone from the anchor groups, which tend to adopt a planar configuration upon contact with the graphene electrodes. DFT calculations using Green functions of a set of different molecular conformations of 2 on graphene electrodes show a direct relationship between the units ( e.g. pyrene, amide, etc. ), in the molecule, through which electrons are injected and the conductance values; where the size of the spacing between the graphene electrodes contributes but is not the dominant factor, and thus, counter-intuitively the smallest spacing gives one of the lowest conductance values., Competing Interests: The authors declare no competing financial interest., (This journal is © The Royal Society of Chemistry.)

Published

2024

5. Synergistic Effect of Solvent Vapor Annealing and Chemical Doping for Achieving High-Performance Organic Field-Effect Transistors with Ideal Electrical Characteristics.

Author

Li J, Babuji A, Fijahi L, James AM, Resel R, Salzillo T, Pfattner R, Ocal C, Barrena E, and Mas-Torrent M

Abstract

Contact resistance and charge trapping are two key obstacles, often intertwined, that negatively impact on the performance of organic field-effect transistors (OFETs) by reducing the overall device mobility and provoking a nonideal behavior. Here, we expose organic semiconductor (OSC) thin films based on blends of 2,7-dioctyl[1]benzothieno[3,2- b ][1]benzothiophene (C8-BTBT-C8) with polystyrene (PS) to (i) a CH 3 CN vapor annealing process, (ii) a doping I 2 /water procedure, and (iii) vapors of I 2 /CH 3 CN to simultaneously dope and anneal the films. After careful analysis of the OFET electrical characteristics and by performing local Kelvin probe force microscopy studies, we found that the vapor annealing process predominantly reduces interfacial shallow traps, while the chemical doping of the OSC film is responsible for the diminishment of deeper traps and promoting a significant reduction of the contact resistance. Remarkably, the devices treated with I 2 /CH 3 CN reveal ideal electrical characteristics with a low level of shallow/deep traps and a very high and almost gate-independent mobility. Hence, this work demonstrates the promising synergistic effects of performing simultaneously a solvent vapor annealing and doping procedure, which can lead to trap-free OSC films with negligible contact resistance problems.

Published

2023

6. Stable Organic Radical for Enhancing Metal-Monolayer-Semiconductor Junction Performance.

Author

De Sousa JA, Pfattner R, Gutiérrez D, Jutglar K, Bromley ST, Veciana J, Rovira C, Mas-Torrent M, Fabre B, and Crivillers N

Abstract

The preparation of monolayers based on an organic radical and its diamagnetic counterpart has been pursued on hydrogen-terminated silicon surfaces. The functional monolayers have been investigated as solid-state metal/monolayer/semiconductor (MmS) junctions showing a characteristic diode behavior which is tuned by the electronic characteristics of the organic molecule. The eutectic gallium-indium liquid metal is used as a top electrode to perform the transport measurements and the results clearly indicate that the SOMO-SUMO molecular orbitals impact the device performance. The junction incorporating the radical shows an almost two orders of magnitude higher rectification ratio ( R (| J 1V / J -1V |) = 10 4.04 ) in comparison with the nonradical one ( R (| J 1V / J -1V |) = 10 2.30 ). The high stability of the fabricated MmS allows the system to be interrogated under irradiation, evidencing that at the wavelength where the photon energy is close to the band gap of the radical there is a clear enhancement of the photoresponse. This is translated into an increase of the photosensitivity ( S ph ) value from 68.7 to 269.0 mA/W for the nonradical and radical based systems, respectively.

Published

2023

7. Dielectric behavior of curcuminoid polymorphs on different substrates by direct soft vacuum deposition.

Author

Riba-López D, Zaffino R, Herrera D, Matheu R, Silvestri F, Ferreira da Silva J, Sañudo EC, Mas-Torrent M, Barrena E, Pfattner R, Ruiz E, González-Campo A, and Aliaga-Alcalde N

Abstract

Our work examines the structural-electronic correlation of a new curcuminoid, AlkCCMoid, as a dielectric material on different substrates. For this purpose, we show a homemade sublimation method that allows the direct deposition of molecules on any type of matrix. The electronic properties of AlkCCMoid have been evaluated by measurements on single crystals, microcrystalline powder, and sublimated samples, respectively. GIWAXS studies on surfaces and XRD studies on powder have revealed the existence of polymorphs and the effect that substrates have on curcuminoid organization. We describe the dielectric nature of our system and identify how different polymorphs can affect electronic parameters such as permittivity, all corroborated by DFT calculations., Competing Interests: Regarding the sublimation system, a patent application has been filed (22/02/2022), with application number: P202230143 (Ref. Number: ES1641.1728). D.H., A.G.C., and N.A.A. are listed as co-inventors of the patents. The rest of the authors declare no competing interests., (© 2022 The Author(s).)

Published

2022

8. Emergent Insulator-Metal Transition with Tunable Optical and Electrical Gap in Thin Films of a Molecular Conducting Composite.

Author

Pfattner R, Laukhina E, Li J, Zaffino RL, Aliaga-Alcalde N, Mas-Torrent M, Laukhin V, and Veciana J

Abstract

Composites exhibit unique synergistic properties emerging when components with different properties are combined. The tuning of the energy bandgap in the electronic structure of the material allows designing tailor-made systems with desirable mechanical, electrical, optical, and/or thermal properties. Here, we study an emergent insulator-metal transition at room temperature in bilayered (BL) thin-films comprised of polycarbonate/molecular-metal composites. Temperature-dependent resistance measurements allow monitoring of the electrical bandgap, which is in agreement with the optical bandgap extracted by optical absorption spectroscopy. The semiconductor-like properties of BL films, made with bis(ethylenedithio)-tetrathiafulvalene (BEDT-TTF or ET) α-ET 2 I 3 (nano)microcrystals as two-dimensional molecular conductor on one side and insulator polycarbonate as a second ingredient, are attributed to an emergent phenomenon equivalent to the transition from an insulator to a metal. This made it possible to obtain semiconducting BL films with tunable electrical/optical bandgaps ranging from 0 to 2.9 eV. A remarkable aspect is the similarity close to room temperature of the thermal and mechanical properties of both composite components, making these materials ideal candidates to fabricate flexible and soft sensors for stress, pressure, and temperature aiming at applications in wearable human health care and bioelectronics., Competing Interests: The authors declare no competing financial interest., (© 2022 The Authors. Published by American Chemical Society.)

Published

2022

9. Synthesis of 2D Porous Crystalline Materials in Simulated Microgravity.

Author

Contreras-Pereda N, Rodríguez-San-Miguel D, Franco C, Sevim S, Vale JP, Solano E, Fong WK, Del Giudice A, Galantini L, Pfattner R, Pané S, Mayor TS, Ruiz-Molina D, and Puigmartí-Luis J

Abstract

To date, crystallization studies conducted in space laboratories, which are prohibitively costly and unsuitable to most research laboratories, have shown the valuable effects of microgravity during crystal growth and morphogenesis. Herein, an easy and highly efficient method is shown to achieve space-like experimentation conditions on Earth employing custom-made microfluidic devices to fabricate 2D porous crystalline molecular frameworks. It is confirmed that experimentation under these simulated microgravity conditions has unprecedented effects on the orientation, compactness and crack-free generation of 2D porous crystalline molecular frameworks as well as in their integration and crystal morphogenesis. It is believed that this work will provide a new "playground" to chemists, physicists, and materials scientists that desire to process unprecedented 2D functional materials and devices., (© 2021 The Authors. Advanced Materials published by Wiley-VCH GmbH.)

Published

2021

10. Low-Voltage, Dual-Gate Organic Transistors with High Sensitivity and Stability toward Electrostatic Biosensing.

Author

Nikolka M, Simatos D, Foudeh A, Pfattner R, McCulloch I, and Bao Z

Subjects

Animals, Cattle, Particle Size, Static Electricity, Surface Properties, Transistors, Electronic, Biosensing Techniques, Serum Albumin, Bovine analysis

Abstract

High levels of performance and stability have been demonstrated for conjugated polymer thin-film transistors in recent years, making them promising materials for flexible electronic circuits and displays. For sensing applications, however, most research efforts have been focusing on electrochemical sensing devices. Here we demonstrate a highly stable biosensing platform using polymer transistors based on the dual-gate mechanism. In this architecture a sensing signal is transduced and amplified by the capacitive coupling between a low- k bottom dielectric and a high- k ionic elastomer top dielectric that is in contact with an analyte solution. The new design exhibits a high signal amplification, high stability under bias stress in various aqueous environments, and low signal drift. Our platform, furthermore, while responding expectedly to charged analytes such as the protein bovine serum albumin, is insensitive to changes of salt concentration of the analyte solution. These features make this platform a potentially suitable tool for a variety of biosensing applications.

Published

2020

11. Effects of Water and Different Solutes on Carbon-Nanotube Low-Voltage Field-Effect Transistors.

Author

Foudeh AM, Pfattner R, Lu S, Kubzdela NS, Gao TZ, Lei T, and Bao Z

Abstract

Semiconducting single-walled carbon nanotubes (swCNTs) are a promising class of materials for emerging applications. In particular, they are demonstrated to possess excellent biosensing capabilities, and are poised to address existing challenges in sensor reliability, sensitivity, and selectivity. This work focuses on swCNT field-effect transistors (FETs) employing rubbery double-layer capacitive dielectric poly(vinylidene fluoride-co-hexafluoropropylene). These devices exhibit small device-to-device variation as well as high current output at low voltages (<0.5 V), making them compatible with most physiological liquids. Using this platform, the swCNT devices are directly exposed to aqueous solutions containing different solutes to characterize their effects on FET current-voltage (FET I-V) characteristics. Clear deviation from ideal characteristics is observed when swCNTs are directly contacted by water. Such changes are attributed to strong interactions between water molecules and sp 2 -hybridized carbon structures. Selective response to Hg 2+ is discussed along with reversible pH effect using two distinct device geometries. Additionally, the influence of aqueous ammonium/ammonia in direct contact with the swCNTs is investigated. Understanding the FET I-V characteristics of low-voltage swCNT FETs may provide insights for future development of stable, reliable, and selective biosensor systems., (© 2020 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2020

12. Inkjet-printed stretchable and low voltage synaptic transistor array.

Author

Molina-Lopez F, Gao TZ, Kraft U, Zhu C, Öhlund T, Pfattner R, Feig VR, Kim Y, Wang S, Yun Y, and Bao Z

Subjects

Brain-Computer Interfaces, Equipment Design, Humans, Nanotubes, Carbon chemistry, Neurons physiology, Polymers chemistry, Synaptic Transmission physiology, Transistors, Electronic, Electronics, Medical methods, Nanotechnology methods, Printing methods, Wearable Electronic Devices

Abstract

Wearable and skin electronics benefit from mechanically soft and stretchable materials to conform to curved and dynamic surfaces, thereby enabling seamless integration with the human body. However, such materials are challenging to process using traditional microelectronics techniques. Here, stretchable transistor arrays are patterned exclusively from solution by inkjet printing of polymers and carbon nanotubes. The additive, non-contact and maskless nature of inkjet printing provides a simple, inexpensive and scalable route for stacking and patterning these chemically-sensitive materials over large areas. The transistors, which are stable at ambient conditions, display mobilities as high as 30 cm 2  V -1 s -1 and currents per channel width of 0.2 mA cm -1 at operation voltages as low as 1 V, owing to the ionic character of their printed gate dielectric. Furthermore, these transistors with double-layer capacitive dielectric can mimic the synaptic behavior of neurons, making them interesting for conformal brain-machine interfaces and other wearable bioelectronics.

Published

2019

13. Biodegradable and flexible arterial-pulse sensor for the wireless monitoring of blood flow.

Author

Boutry CM, Beker L, Kaizawa Y, Vassos C, Tran H, Hinckley AC, Pfattner R, Niu S, Li J, Claverie J, Wang Z, Chang J, Fox PM, and Bao Z

Subjects

Anastomosis, Surgical, Animals, Arteries surgery, Equipment Design, Pliability, Rats, Sprague-Dawley, Arteries physiology, Blood Circulation physiology, Monitoring, Physiologic instrumentation, Pulse instrumentation, Wireless Technology instrumentation

Abstract

The ability to monitor blood flow is critical to patient recovery and patient outcomes after complex reconstructive surgeries. Clinically available wired implantable monitoring technology requires careful fixation for accurate detection and needs to be removed after use. Here, we report the design of a pressure sensor, made entirely of biodegradable materials and based on fringe-field capacitor technology, for measuring arterial blood flow in both contact and non-contact modes. The sensor is operated wirelessly through inductive coupling, has minimal hysteresis, fast response times, excellent cycling stability, is highly robust, allows for easy mounting and eliminates the need for removal, thus reducing the risk of vessel trauma. We demonstrate the operation of the sensor with a custom-made artificial artery model and in vivo in rats. This technology may be advantageous in real-time post-operative monitoring of blood flow after reconstructive surgery.

Published

2019

14. Highly Tunable and Facile Synthesis of Uniform Carbon Flower Particles.

Author

Chen S, Koshy DM, Tsao Y, Pfattner R, Yan X, Feng D, and Bao Z

Abstract

Three-dimensional hierarchical porous carbon materials with flower-like superstructures are of great interest for energy applications since their unique shape not only provides high accessible surface area and consequently more exposed active sites but also facilitates ion transport for high-rate capability. However, finding a controllable way to make porous carbons with such specific shapes has been challenging. Herein, we report a tunable and simple method for one-pot synthesis of polyacrylonitrile and its copolymer nanostructured particles with various superstructures (flower, pompom, hairy leave, and petal shapes) controlled by employing various solvents or by the incorporation of different co-monomers. The correlation between polymer particle shapes and solvent properties has been identified through Hansen solubility parameters analysis. The obtained uniform polyacrylonitrile particles could be readily converted into porous carbons by high-temperature gas treatment while maintaining the original shape of the polymer precursor structures. The resulting carbon materials have high nitrogen-doping concentration (7-15 at%) and tunable porous structures. This novel synthetic method provides a simple way to make porous carbons with controllable morphology and potentially advantageous properties for a variety of potential energy and environmental applications, such as electrochemical energy conversion and wastewater treatment.

Published

2018

15. A bioinspired flexible organic artificial afferent nerve.

Author

Kim Y, Chortos A, Xu W, Liu Y, Oh JY, Son D, Kang J, Foudeh AM, Zhu C, Lee Y, Niu S, Liu J, Pfattner R, Bao Z, and Lee TW

Subjects

Mechanoreceptors, Motor Neurons, Muscle Contraction, Muscles innervation, Muscles physiology, Pressure, Robotics, Afferent Pathways, Biomimetic Materials, Neural Prostheses

Abstract

The distributed network of receptors, neurons, and synapses in the somatosensory system efficiently processes complex tactile information. We used flexible organic electronics to mimic the functions of a sensory nerve. Our artificial afferent nerve collects pressure information (1 to 80 kilopascals) from clusters of pressure sensors, converts the pressure information into action potentials (0 to 100 hertz) by using ring oscillators, and integrates the action potentials from multiple ring oscillators with a synaptic transistor. Biomimetic hierarchical structures can detect movement of an object, combine simultaneous pressure inputs, and distinguish braille characters. Furthermore, we connected our artificial afferent nerve to motor nerves to construct a hybrid bioelectronic reflex arc to actuate muscles. Our system has potential applications in neurorobotics and neuroprosthetics., (Copyright © 2018 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works.)

Published

2018

16. Deformable Organic Nanowire Field-Effect Transistors.

Author

Lee Y, Oh JY, Kim TR, Gu X, Kim Y, Wang GN, Wu HC, Pfattner R, To JWF, Katsumata T, Son D, Kang J, Matthews JR, Niu W, He M, Sinclair R, Cui Y, Tok JB, Lee TW, and Bao Z

Abstract

Deformable electronic devices that are impervious to mechanical influence when mounted on surfaces of dynamically changing soft matters have great potential for next-generation implantable bioelectronic devices. Here, deformable field-effect transistors (FETs) composed of single organic nanowires (NWs) as the semiconductor are presented. The NWs are composed of fused thiophene diketopyrrolopyrrole based polymer semiconductor and high-molecular-weight polyethylene oxide as both the molecular binder and deformability enhancer. The obtained transistors show high field-effect mobility >8 cm 2 V -1 s -1 with poly(vinylidenefluoride-co-trifluoroethylene) polymer dielectric and can easily be deformed by applied strains (both 100% tensile and compressive strains). The electrical reliability and mechanical durability of the NWs can be significantly enhanced by forming serpentine-like structures of the NWs. Remarkably, the fully deformable NW FETs withstand 3D volume changes (>1700% and reverting back to original state) of a rubber balloon with constant current output, on the surface of which it is attached. The deformable transistors can robustly operate without noticeable degradation on a mechanically dynamic soft matter surface, e.g., a pulsating balloon (pulse rate: 40 min -1 (0.67 Hz) and 40% volume expansion) that mimics a beating heart, which underscores its potential for future biomedical applications., (© 2018 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2018

17. Ultratransparent and stretchable graphene electrodes.

Author

Liu N, Chortos A, Lei T, Jin L, Kim TR, Bae WG, Zhu C, Wang S, Pfattner R, Chen X, Sinclair R, and Bao Z

Abstract

Two-dimensional materials, such as graphene, are attractive for both conventional semiconductor applications and nascent applications in flexible electronics. However, the high tensile strength of graphene results in fracturing at low strain, making it challenging to take advantage of its extraordinary electronic properties in stretchable electronics. To enable excellent strain-dependent performance of transparent graphene conductors, we created graphene nanoscrolls in between stacked graphene layers, referred to as multilayer graphene/graphene scrolls (MGGs). Under strain, some scrolls bridged the fragmented domains of graphene to maintain a percolating network that enabled excellent conductivity at high strains. Trilayer MGGs supported on elastomers retained 65% of their original conductance at 100% strain, which is perpendicular to the direction of current flow, whereas trilayer films of graphene without nanoscrolls retained only 25% of their starting conductance. A stretchable all-carbon transistor fabricated using MGGs as electrodes exhibited a transmittance of >90% and retained 60% of its original current output at 120% strain (parallel to the direction of charge transport). These highly stretchable and transparent all-carbon transistors could enable sophisticated stretchable optoelectronics.

Published

2017

18. Mechanochemical unzipping of insulating polyladderene to semiconducting polyacetylene.

Author

Chen Z, Mercer JAM, Zhu X, Romaniuk JAH, Pfattner R, Cegelski L, Martinez TJ, Burns NZ, and Xia Y

Abstract

Biological systems sense and respond to mechanical stimuli in a complex manner. In an effort to develop synthetic materials that transduce mechanical force into multifold changes in their intrinsic properties, we report on a mechanochemically responsive nonconjugated polymer that converts to a conjugated polymer via an extensive rearrangement of the macromolecular structure in response to force. Our design is based on the facile mechanochemical unzipping of polyladderene, a polymer inspired by a lipid natural product structure and prepared via direct metathesis polymerization. The resultant polyacetylene block copolymers exhibit long conjugation length and uniform trans-configuration and self-assemble into semiconducting nanowires. Calculations support a tandem unzipping mechanism of the ladderene units., (Copyright © 2017 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works.)

Published

2017

19. Biocompatible and totally disintegrable semiconducting polymer for ultrathin and ultralightweight transient electronics.

Author

Lei T, Guan M, Liu J, Lin HC, Pfattner R, Shaw L, McGuire AF, Huang TC, Shao L, Cheng KT, Tok JB, and Bao Z

Subjects

Electrodes, Biocompatible Materials chemistry, Biodegradable Plastics chemistry, Cellulose chemistry, Semiconductors

Abstract

Increasing performance demands and shorter use lifetimes of consumer electronics have resulted in the rapid growth of electronic waste. Currently, consumer electronics are typically made with nondecomposable, nonbiocompatible, and sometimes even toxic materials, leading to serious ecological challenges worldwide. Here, we report an example of totally disintegrable and biocompatible semiconducting polymers for thin-film transistors. The polymer consists of reversible imine bonds and building blocks that can be easily decomposed under mild acidic conditions. In addition, an ultrathin (800-nm) biodegradable cellulose substrate with high chemical and thermal stability is developed. Coupled with iron electrodes, we have successfully fabricated fully disintegrable and biocompatible polymer transistors. Furthermore, disintegrable and biocompatible pseudo-complementary metal-oxide-semiconductor (CMOS) flexible circuits are demonstrated. These flexible circuits are ultrathin (<1 μm) and ultralightweight (∼2 g/m 2 ) with low operating voltage (4 V), yielding potential applications of these disintegrable semiconducting polymers in low-cost, biocompatible, and ultralightweight transient electronics., Competing Interests: The authors declare no conflict of interest.

Published

2017

20. A highly stretchable, transparent, and conductive polymer.

Author

Wang Y, Zhu C, Pfattner R, Yan H, Jin L, Chen S, Molina-Lopez F, Lissel F, Liu J, Rabiah NI, Chen Z, Chung JW, Linder C, Toney MF, Murmann B, and Bao Z

Abstract

Previous breakthroughs in stretchable electronics stem from strain engineering and nanocomposite approaches. Routes toward intrinsically stretchable molecular materials remain scarce but, if successful, will enable simpler fabrication processes, such as direct printing and coating, mechanically robust devices, and more intimate contact with objects. We report a highly stretchable conducting polymer, realized with a range of enhancers that serve a dual function: (i) they change morphology and (ii) they act as conductivity-enhancing dopants in poly(3,4-ethylenedioxythiophene):poly(styrenesulfonate) (PEDOT:PSS). The polymer films exhibit conductivities comparable to the best reported values for PEDOT:PSS, with over 3100 S/cm under 0% strain and over 4100 S/cm under 100% strain-among the highest for reported stretchable conductors. It is highly durable under cyclic loading, with the conductivity maintained at 3600 S/cm even after 1000 cycles to 100% strain. The conductivity remained above 100 S/cm under 600% strain, with a fracture strain of 800%, which is superior to even the best silver nanowire- or carbon nanotube-based stretchable conductor films. The combination of excellent electrical and mechanical properties allowed it to serve as interconnects for field-effect transistor arrays with a device density that is five times higher than typical lithographically patterned wavy interconnects.

Published

2017

21. Structural and electronic characterisation of π-extended tetrathiafulvalene derivatives as active components in field-effect transistors.

Author

Campos A, Oxtoby N, Galindo S, Pfattner R, Veciana J, Bromley ST, Rovira C, and Mas-Torrent M

Abstract

The electronic and structural properties of two tetrathiafulvalene derivatives bearing aromatic benzene rings are reported. Thin film transistors of these materials show p-type characteristics with comparable mobility values. It is found that the rigidification of the molecule is beneficial for reducing the reorganisation energy but also has an unfavorable impact on the electronic structure dimensionality.

Published

2016

22. Investigation of a Solution-Processable, Nonspecific Surface Modifier for Low Cost, High Work Function Electrodes.

Author

Hinckley AC, Wang C, Pfattner R, Kong D, Zhou Y, Ecker B, Gao Y, and Bao Z

Abstract

We demonstrate the ability of the highly fluorinated, chemically inert copolymer poly(vinylidene fluoride-co-hexafluoropropylene) (PVDF-HFP) to significantly increase the work function of a variety of common electrode materials. The work function change is hypothesized to occur via physisorption of the polymer layer and formation of a surface dipole at the polymer/conductor interface. When incorporated into organic solar cells, an interlayer of PVDF-HFP at an Ag anode increases the open circuit voltage by 0.4 eV and improves device power conversion efficiency by approximately an order of magnitude relative to Ag alone. Solution-processable in air, PVDF-HFP thin films provide one possible route toward achieving low cost, nonreactive, high work function electrodes.

Published

2016

23. Microfluidic Pneumatic Cages: A Novel Approach for In-chip Crystal Trapping, Manipulation and Controlled Chemical Treatment.

Author

Abrishamkar A, Paradinas M, Bailo E, Rodriguez-Trujillo R, Pfattner R, Rossi RM, Ocal C, deMello AJ, Amabilino DB, and Puigmartí-Luis J

Subjects

Microfluidic Analytical Techniques, Microfluidics instrumentation

Abstract

The precise localization and controlled chemical treatment of structures on a surface are significant challenges for common laboratory technologies. Herein, we introduce a microfluidic-based technology, employing a double-layer microfluidic device, which can trap and localize in situ and ex situ synthesized structures on microfluidic channel surfaces. Crucially, we show how such a device can be used to conduct controlled chemical reactions onto on-chip trapped structures and we demonstrate how the synthetic pathway of a crystalline molecular material and its positioning inside a microfluidic channel can be precisely modified with this technology. This approach provides new opportunities for the controlled assembly of structures on surface and for their subsequent treatment.

Published

2016

24. Mechanically Durable and Highly Stretchable Transistors Employing Carbon Nanotube Semiconductor and Electrodes.

Author

Chortos A, Koleilat GI, Pfattner R, Kong D, Lin P, Nur R, Lei T, Wang H, Liu N, Lai YC, Kim MG, Chung JW, Lee S, and Bao Z

Abstract

Mechanically durable stretchable trans-istors are fabricated using carbon nanotube electrical components and tough thermoplastic elastomers. After an initial conditioning step, the electrical characteristics remain constant with strain. The strain-dependent characteristics are similar in orthogonal stretching directions. Devices can be impacted with a hammer and punctured with a needle while remaining functional and stretchable., (© 2015 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2016

25. Stretchable Self-Healing Polymeric Dielectrics Cross-Linked Through Metal-Ligand Coordination.

Author

Rao YL, Chortos A, Pfattner R, Lissel F, Chiu YC, Feig V, Xu J, Kurosawa T, Gu X, Wang C, He M, Chung JW, and Bao Z

Subjects

2,2'-Dipyridyl, Chlorides chemistry, Cross-Linking Reagents, Dimethylpolysiloxanes chemistry, Elasticity, Electronics, Ferrous Compounds chemistry, Ligands, Zinc Compounds chemistry, Metals chemistry, Polymers chemistry

Abstract

A self-healing dielectric elastomer is achieved by the incorporation of metal-ligand coordination as cross-linking sites in nonpolar polydimethylsiloxane (PDMS) polymers. The ligand is 2,2'-bipyridine-5,5'-dicarboxylic amide, while the metal salts investigated here are Fe(2+) and Zn(2+) with various counteranions. The kinetically labile coordination between Zn(2+) and bipyridine endows the polymer fast self-healing ability at ambient condition. When integrated into organic field-effect transistors (OFETs) as gate dielectrics, transistors with FeCl2 and ZnCl2 salts cross-linked PDMS exhibited increased dielectric constants compared to PDMS and demonstrated hysteresis-free transfer characteristics, owing to the low ion conductivity in PDMS and the strong columbic interaction between metal cations and the small Cl(-) anions which can prevent mobile anions drifting under gate bias. Fully stretchable transistors with FeCl2-PDMS dielectrics were fabricated and exhibited ideal transfer characteristics. The gate leakage current remained low even after 1000 cycles at 100% strain. The mechanical robustness and stable electrical performance proved its suitability for applications in stretchable electronics. On the other hand, transistors with gate dielectrics containing large-sized anions (BF4(-), ClO4(-), CF3SO3(-)) displayed prominent hysteresis due to mobile anions drifting under gate bias voltage. This work provides insights on future design of self-healing stretchable dielectric materials based on metal-ligand cross-linked polymers.

Published

2016

26. Significance of the double-layer capacitor effect in polar rubbery dielectrics and exceptionally stable low-voltage high transconductance organic transistors.

Author

Wang C, Lee WY, Kong D, Pfattner R, Schweicher G, Nakajima R, Lu C, Mei J, Lee TH, Wu HC, Lopez J, Diao Y, Gu X, Himmelberger S, Niu W, Matthews JR, He M, Salleo A, Nishi Y, and Bao Z

Abstract

Both high gain and transconductance at low operating voltages are essential for practical applications of organic field-effect transistors (OFETs). Here, we describe the significance of the double-layer capacitance effect in polar rubbery dielectrics, even when present in a very low ion concentration and conductivity. We observed that this effect can greatly enhance the OFET transconductance when driven at low voltages. Specifically, when the polar elastomer poly(vinylidene fluoride-co-hexafluoropropylene) (e-PVDF-HFP) was used as the dielectric layer, despite a thickness of several micrometers, we obtained a transconductance per channel width 30 times higher than that measured for the same organic semiconductors fabricated on a semicrystalline PVDF-HFP with a similar thickness. After a series of detailed experimental investigations, we attribute the above observation to the double-layer capacitance effect, even though the ionic conductivity is as low as 10(-10) S/cm. Different from previously reported OFETs with double-layer capacitance effects, our devices showed unprecedented high bias-stress stability in air and even in water.

Published

2015

27. Partially-Screened Field Effect and Selective Carrier Injection at Organic Semiconductor/Graphene Heterointerface.

Author

Shih CJ, Pfattner R, Chiu YC, Liu N, Lei T, Kong D, Kim Y, Chou HH, Bae WG, and Bao Z

Abstract

Due to the lack of a bandgap, applications of graphene require special device structures and engineering strategies to enable semiconducting characteristics at room temperature. To this end, graphene-based vertical field-effect transistors (VFETs) are emerging as one of the most promising candidates. Previous work attributed the current modulation primarily to gate-modulated graphene-semiconductor Schottky barrier. Here, we report the first experimental evidence that the partially screened field effect and selective carrier injection through graphene dominate the electronic transport at the organic semiconductor/graphene heterointerface. The new mechanistic insight allows us to rationally design graphene VFETs. Flexible organic/graphene VFETs with bending radius <1 mm and the output current per unit layout area equivalent to that of the best oxide planar FETs can be achieved. We suggest driving organic light emitting diodes with such VFETs as a promising application.

Published

2015

28. Organic metal engineering for enhanced field-effect transistor performance.

Author

Pfattner R, Rovira C, and Mas-Torrent M

Subjects

Molecular Structure, Semiconductors, Organometallic Compounds chemistry, Transistors, Electronic

Abstract

A key device component in organic field-effect transistors (OFETs) is the organic semiconductor/metal interface since it has to ensure efficient charge injection. Traditionally, inorganic metals have been employed in these devices using conventional lithographic fabrication techniques. Metals with low or high work-functions have been selected depending on the type of semiconductor measured and, in some cases, the metal has been covered with molecular self-assembled monolayers to tune the work function, improve the molecular order at the interface and reduce the contact resistance. However, in the last few years, some approaches have been focused on utilizing organic metals in these devices, which have been fabricated by means of both evaporation and solution-processed techniques. Higher device performances have often been observed, which have been attributed to a range of factors, such as a more favourable organic/organic interface, a better matching of energy levels or/and to a reduction of the contact resistance. Further, in contrast to their inorganic counterparts, organic metals allow their chemical modification and thus the tuning of the Fermi level. In this perspective paper, an overview of the recent work devoted to the fabrication of OFETs with organic metals as electrodes will be carried out. It will be shown that in these devices not only is the matching of the HOMO or LUMO of the semiconductor with the metal work-function important, but other aspects such as the interface morphology can also play a critical role. Also, recent approaches in which the use of organic charge transfer salts as buffer layers at the metal contacts or on the dielectric or as doping agents of the organic semiconductors that have been used to improve the device performance will be briefly described.

Published

2015

29. Bottom-up on-crystal in-chip formation of a conducting salt and a view of its restructuring: from organic insulator to conducting "switch" through microfluidic manipulation.

Author

Puigmartí-Luis J, Paradinas M, Bailo E, Rodriguez-Trujillo R, Pfattner R, Ocal C, and Amabilino DB

Abstract

The chemical modification of an immobilized single crystal in a fluid cell is reported, whereby a material with switching functions is generated in situ by generating a chemical reagent in the flow. Crystals of the insulating organic crystal of TCNQ (tetracyanoquinodimethane) were grown in a microfluidic channel and were trapped using a pneumatic valve, a nascent technique for materials manipulation. They were subsequently reduced using solution-deposited silver to provide a conducting material in situ by a heterogeneous reaction. Removal of the new material from the chip proved it to be the silver salt of reduced TCNQ. Uniquely, conducting atomic force microscope (CAFM) studies show three regions in the solid. The localized original neutral organic material crystal is shown to be an insulator but to produce areas with Ohmic conducting characteristics after reduction. This inhomogeneous doping provides an opportunity for probing electrical materials properties side by side. Measurements with the CAFM witness this conducting material where the TCNQ is fully transformed to the silver salt. Additionally, an intermediate phase is observed that exhibits bipolar resistive switching typical of programmable resistive memories. Raman microscopy proves the conversion of the material in specific regions and clearly defines the intermediate phase region that could be responsible for the switching effect in related materials. This kind of "on crystal chemistry" exploiting immobilization and masking by a pneumatic clamp in a microfluidic channel shows how material can be selectively converted to give different functionalities in the same material piece, even though it is not a single crystal to single crystal conversion, and beckons exploitation for the preparation of systems relevant for molecular electronics as well as other areas where chemical manipulation of single crystals could be beneficial.

Published

2015

30. HOMO stabilisation in π-extended dibenzotetrathiafulvalene derivatives for their application in organic field-effect transistors.

Author

Geng Y, Pfattner R, Campos A, Wang W, Jeannin O, Hauser J, Puigdollers J, Bromley ST, Decurtins S, Veciana J, Rovira C, Mas-Torrent M, and Liu SX

Subjects

Electrons, Fluorescence, Transistors, Electronic, Benzene Derivatives chemistry, Heterocyclic Compounds chemistry, Semiconductors

Abstract

Three new organic semiconductors, in which either two methoxy units are directly linked to a dibenzotetrathiafulvalene (DB-TTF) central core and a 2,1,3-chalcogendiazole is fused on the one side, or four methoxy groups are linked to the DB-TTF, have been synthesised as active materials for organic field-effect transistors (OFETs). Their electrochemical behaviour, electronic absorption and fluorescence emission as well as photoinduced intramolecular charge transfer were studied. The electron-withdrawing 2,1,3-chalcogendiazole unit significantly affects the electronic properties of these semiconductors, lowering both the HOMO and LUMO energy levels and hence increasing the stability of the semiconducting material. The solution-processed single-crystal transistors exhibit high performance with a hole mobility up to 0.04 cm(2)  V(-1)  s(-1) as well as good ambient stability., (© 2014 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2014

31. A compact tetrathiafulvalene-benzothiadiazole dyad and its highly symmetrical charge-transfer salt: ordered donor π-stacks closely bound to their acceptors.

Author

Geng Y, Pfattner R, Campos A, Hauser J, Laukhin V, Puigdollers J, Veciana J, Mas-Torrent M, Rovira C, Decurtins S, and Liu SX

Subjects

Crystallography, X-Ray, Electric Conductivity, Electrochemical Techniques, Molecular Conformation, Oxidation-Reduction, Quantum Theory, Salts chemistry, Transistors, Electronic, Heterocyclic Compounds chemistry, Thiadiazoles chemistry

Abstract

A compact and planar donor-acceptor molecule 1 comprising tetrathiafulvalene (TTF) and benzothiadiazole (BTD) units has been synthesised and experimentally characterised by structural, optical, and electrochemical methods. Solution-processed and thermally evaporated thin films of 1 have also been explored as active materials in organic field-effect transistors (OFETs). For these devices, hole field-effect mobilities of μFE = (1.3±0.5)×10(-3) and (2.7±0.4)×10(-3)  cm(2)  V s(-1) were determined for the solution-processed and thermally evaporated thin films, respectively. An intense intramolecular charge-transfer (ICT) transition at around 495 nm dominates the optical absorption spectrum of the neutral dyad, which also shows a weak emission from its ICT state. The iodine-induced oxidation of 1 leads to a partially oxidised crystalline charge-transfer (CT) salt {(1)2I3}, and eventually also to a fully oxidised compound {1I3}⋅1/2I2. Single crystals of the former CT compound, exhibiting a highly symmetrical crystal structure, reveal a fairly good room temperature electrical conductivity of the order of 2 S cm(-1). The one-dimensional spin system bears compactly bonded BTD acceptors (spatial localisation of the LUMO) along its ridge., (© 2014 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2014

32. Benzodicarbomethoxytetrathiafulvalene derivatives as soluble organic semiconductors.

Author

Otón F, Pfattner R, Oxtoby NS, Mas-Torrent M, Wurst K, Fontrodona X, Olivier Y, Cornil J, Veciana J, and Rovira C

Subjects

Crystallography, X-Ray, Electrons, Models, Molecular, Semiconductors, Solubility, Spectrophotometry, Ultraviolet, Thiophenes chemistry, X-Ray Diffraction, Heterocyclic Compounds, 1-Ring chemistry

Abstract

A series of new tetrathiafulvalene (TTF) derivatives bearing dimethoxycarbonyl and phenyl or phthalimidyl groups fused to the TTF core (6 and 15-18) has been synthesized as potential soluble semiconductor materials for organic field-effect transistors (OFETs). The electron-withdrawing substituents lower the energy of the HOMO and LUMO levels and increase the solubility and stability of the semiconducting material. Crystal structures of all new TTF derivatives are also described, and theoretical DFT calculations were carried out to study the potential of the crystals to be used in OFET. In the experimental study, the best performing device exhibited a hole mobility up to 7.5 × 10(-3) cm(2) V(-1) s(-1)).

Published

2011

33. High-performance single crystal organic field-effect transistors based on two dithiophene-tetrathiafulvalene (DT-TTF) polymorphs.

Author

Pfattner R, Mas-Torrent M, Bilotti I, Brillante A, Milita S, Liscio F, Biscarini F, Marszalek T, Ulanski J, Nosal A, Gazicki-Lipman M, Leufgen M, Schmidt G, Molenkamp LW, Laukhin V, Veciana J, and Rovira C

Subjects

Crystallization, Spectrum Analysis, Raman, X-Ray Diffraction, Heterocyclic Compounds chemistry, Thiophenes chemistry, Transistors, Electronic

Abstract

Solution prepared single crystal organic field-effect transistors (OFETs) combine low-cost with high performance due to structural ordering of molecules. However, in organic crystals polymorphism is a known phenomenon, which can have a crucial influence on charge transport. Here, the performance of solution-prepared single crystal OFETs based on two different polymorphs of dithiophene-tetrathiafulvalene, which were investigated by confocal Raman spectroscopy and X-ray diffraction, are reported. OFET devices prepared using different configurations show that both polymorphs exhibited excellent device performance, although the -phase revealed charge carrier mobility between two and ten times higher in accordance to the closer stacking of the molecules.

Published

2010

34. Ultrasensitive piezoresistive all-organic flexible thin films.

Author

Laukhina E, Pfattner R, Ferreras LR, Galli S, Mas-Torrent M, Masciocchi N, Laukhin V, Rovira C, and Veciana J

Subjects

Electric Impedance, Equipment Design, Equipment Failure Analysis, Materials Testing, Membranes, Artificial, Micro-Electrical-Mechanical Systems instrumentation, Microelectrodes, Organic Chemicals chemistry

Published

2010