Your search keyword '"McCulloch I"' showing total 653 results

251. Small molecule organic acceptors: relating chemical structure with thin film device performance

Author

Bristow, H and McCulloch, I

Abstract

The development of the class of small molecule organic semiconductors typically referred to as non-fullerene acceptors (NFA), has led to a resurgence of research interest on the topic of organic photovoltaic (OPV) devices, in which they have replaced fullerene derivatives as the electron acceptors of choice. This thesis contributes to understanding the relationship between the chemical structure of these small molecule organic semiconductors, their physical properties, optoelectronic properties, and performance in organic electronic thin film devices. A better understanding of this relationship is required to direct the development of novel small molecule organic semiconductors. In the first part of this thesis the impact of aliphatic side chains on NFA intermolecular packing and mobility is investigated. The NFA O-IDTBR, which has been widely used in OPV applications, is also found to be a good candidate for organic thin film transistor (OTFT) applications. The high mobility of over 0.4 cm2 V-1 s-1 achieved in OTFTs operating in the saturation regime is attributed to O-IDTBR’s packing motif in the solid state. In the second part of the thesis further chemical structure modifications to O-IDTBR’s conjugated push-pull donor-acceptor structure as well as its aliphatic side chains are investigated. Through these structural modifications, the unique properties that the combination of the specific conjugated chromophore and octyl side chains present in O IDTBR have given the material, allowing it to deliver high mobilities in OTFTs, are highlighted. The third part of this thesis focuses on organic photodetectors (OPD), a relatively recently explored application for NFAs. Very little is currently known about the impact of OSC chemical structure on OPD performance metrics. In particular, achieving a low dark current at reverse bias has been a major limitation to the development of OPD technology. Two new blends based on NFAs for OPDs, PTQ10:O-FBR and PTQ10:O-IDTBR, are identified as delivering low dark current densities at reverse bias, resulting in high specific detectivities of over 1012 Jones. The final part of the thesis focuses on NFAs with chemical structures tuned to allow absorption in the NIR region. Whilst OPVs were originally touted as a low-cost alternative to other solar cell technologies, the reduction in the cost of manufacturing silicon based solar panels has meant that, for OPV to realise its market potential, other advantages over competing solar technologies need to be exploited. One such application is transparent and semi-transparent photovoltaics for which near-infra red (NIR), or specifically visible blind, NFAs are being developed. Similarly, a key OPD application is for detectors targeting NIR absorption, which have uses in biomedical imaging, substance identification and optical communications. The final results chapter explores the properties of several NIR absorbing NFAs and their application in both OPV and OPD applications.

Published

2022

252. Design of mixed ionic-electronic polymeric conductors for organic electrochemical transistors

Author

Moser, M and McCulloch, I

Subjects

Chemistry, Polymers, Organic semiconductors, Chemistry, Organic, Conjugated polymers, Materials science

Abstract

Organic electrochemical transistors (OECTs) are electronic devices that have gained significant attention for many biomedical applications, including as electrophysiological recording elements, cell activity monitors, and biomolecule sensors. Compared to conventional transistors, one distinguishing feature of OECTs is the requirement of the employed channel material to conduct both ionic and electronic charge carriers. Currently, poly(3,4-ethylenedioxythiophene):poly(styrenesulfonate) (PEDOT:PSS), has established itself as OECT benchmark channel material, predominantly due to its widespread commercial availability. PEDOT:PSS-based OECTs, however, display several disadvantages, such as moderate steady-state performances and PEDOT:PSS’ limited chemical tunability preventing the formulation of structure-property relationships to guide future material design. Based on these limitations, this thesis focuses on the development of ethylene glycol (EG) functionalised conjugated polymers capable of conducting both ionic and electronic charge carriers to advance OECT performance, while concomitantly also establishing molecular design guidelines for the development of future channel materials. In Chapter 2 a series of four polythiophenes with pendant EG side-chain lengths ranging between two and six EG repeat units is synthesised and characterised. Specifically, p(g3T2- T), the polymer employing triethylene glycol side-chains is shown to incur the highest OECT performance, with both EG side-chain length shortening and lengthening proving to be detrimental towards OECT performance. Chapter 3 builds on the results of Chapter 2 and explores how variation in the relative distribution of the EG side-chains in polythiophenes impacts their swelling and therefore their OECT performance and stability. While intermediate degrees of polymer swelling boost device performance, minimising the polymers’ swelling improves device stability. The importance of maximising OECT device performance and stability are highlighted by employing one of the newly developed polymers as the channel material in a SARS-CoV-2 OECT biosensor, incurring better sensing performances compared to the PEDOT:PSS benchmark. Chapter 4 investigates the use of the diketopyrrolopyrrole (DPP) unit to improve the p-type performance of donor-acceptor copolymers in OECTs, whose performance has lagged far behind their all-donor counterparts. In particular, control over both the overall and relative energy levels in these polymers is demonstrated to be of utmost importance to tune their performance and stability in devices.

Published

2021

253. Critical Role of Side-Chain Attachment Density on the Order and Device Performance of Polythiophenes

Author

McCulloch, I

Published

2007

254. Modulation spectroscopy with ultracold fermions in an optical lattice

Author

McCulloch, I [Institute for Theoretical Physics, RWTH Aachen, D-52056 Aachen (Germany)]

Published

2006

255. Predicting the optimal process window for the coating of single-crystalline organic films with mobilities exceeding 7 cm2/Vs

Author

Cedric Rolin, Robby Janneck, Paul Heremans, Jan Genoe, Federico Vercesi, McCulloch, I, and Jurchescu, OD

Subjects

Fabrication, Materials science, business.industry, Nanotechnology, 02 engineering and technology, engineering.material, 021001 nanoscience & nanotechnology, 01 natural sciences, 010309 optics, Organic semiconductor, Semiconductor, Coating, Thin-film transistor, 0103 physical sciences, engineering, Optoelectronics, Process window, Process optimization, Thin film, 0210 nano-technology, business

Abstract

Organic thin film transistors (OTFTs) based on single crystalline thin films of organic semiconductors have seen considerable development in the recent years. The most successful method for the fabrication of single crystalline films are solution-based meniscus guided coating techniques such as dip-coating, solution shearing or zone casting. These upscalable methods enable rapid and efficient film formation without additional processing steps. The single-crystalline film quality is strongly dependent on solvent choice, substrate temperature and coating speed. So far, however, process optimization has been conducted by trial and error methods, involving, for example, the variation of coating speeds over several orders of magnitude. Through a systematic study of solvent phase change dynamics in the meniscus region, we develop a theoretical framework that links the optimal coating speed to the solvent choice and the substrate temperature. In this way, we can accurately predict an optimal processing window, enabling fast process optimization. Our approach is verified through systematic OTFT fabrication based on films grown with different semiconductors, solvents and substrate temperatures. The use of best predicted coating speeds delivers state of the art devices. In the case of C8BTBT, OTFTs show well-behaved characteristics with mobilities up to 7 cm2/Vs and onset voltages close to 0 V. Our approach also explains well optimal recipes published in the literature. This route considerably accelerates parameter screening for all meniscus guided coating techniques and unveils the physics of single crystalline film formation. ispartof: pages:99430- ispartof: Organic Field-Effect Transistors XV vol:9943 pages:99430- ispartof: Organic Field-Effect Transistors XV location:San Diego, CA USA date:8 Jan 2016 status: published

Published

2016

256. Highly red-shifted NIR emission from a novel anthracene conjugated polymer backbone containing Pt(II) porphyrins

Author

David M.E. Freeman, Alessandro Minotto, Warren Duffy, Hugo Bronstein, Franco Cacialli, Kealan J. Fallon, Iain McCulloch, Fallon, Kealan [0000-0001-6241-6034], Bronstein, Hugo [0000-0003-0293-8775], Apollo - University of Cambridge Repository, Freeman, D, Minotto, A, Duffy, W, Fallon, K, Mcculloch, I, Cacialli, F, and Bronstein, H

Subjects

Photoluminescence, Polymers and Plastics, EFFICIENT, Bioengineering, 02 engineering and technology, Electroluminescence, Conjugated system, 010402 general chemistry, 01 natural sciences, Biochemistry, 4016 Materials Engineering, chemistry.chemical_compound, ELECTROLUMINESCE, Polymer chemistry, 40 Engineering, chemistry.chemical_classification, Anthracene, 3403 Macromolecular and Materials Chemistry, Dopant, 34 Chemical Sciences, Organic Chemistry, PHOSPHORESCENCE, Polymer, 021001 nanoscience & nanotechnology, Porphyrin, 0104 chemical sciences, GAP POLYMER, Monomer, chemistry, PHOTOPHYSICAL PROPERTIES, HIGH-PERFORMANCE, NEAR-INFRARED POLYMER, LUMINESCENCE, COMPLEXES, ENERGY-TRANSFER, 0210 nano-technology

Abstract

We present the synthesis of a novel diphenylanthracene (DPA) based semiconducting polymer. The polymer is solubilised by alkoxy groups attached directly to a DPA monomer, meaning the choice of co-monomer is not limited to exclusively highly solubilising moieties. Interestingly, the polymer shows a red-shifted elecroluminescence maximum (510 nm) when compared to its photoluminescence maximum (450 nm) which we attribute to excimer formation. The novel polymer was utilised as a host for a covalently-linked platinum(ii) complexed porphyrin dopant. Emission from these polymers was observed in the NIR and again showed almost a 100 nm red shift from photoluminescence to electroluminescence. This work demonstrates that utilising highly aggregating host materials is an effective tool for inducing red-shifted emission in OLEDs.

Published

2016

257. Correlation between the Molecular Properties of Semiconducting Polymers of Intrinsic Microporosity and Their Photocatalytic Hydrogen Production.

Author

Willner BJ, Aitchison CM, Podjaski F, Lu W, Tian J, Durrant JR, and McCulloch I

Abstract

Increasing the interface area between organic semiconductor photocatalysts and electrolyte by fabricating nanoparticles has proven to be an effective strategy to increase photocatalytic hydrogen production activity. However, it remains unclear if increasing the internal interface by the introduction of porosity has as clear benefits for activity. To better inform future photocatalyst design, a series of polymers of intrinsic microporosity (PIMs) with the same conjugated backbone were synthesized as a platform to independently modulate the variables of porosity and relative hydrophilicity through the use of hydrophilic alcohol moieties protected by silyl ether protecting groups. When tested in the presence of ascorbic acid and photodeposited Pt, a strong correlation between the wettable porosity and photocatalytic activity was found, with the more wettable analogue of two polymers of almost the same surface area delivering 7.3 times greater activity, while controlling for other variables. Transient absorption spectroscopic (TAS) investigation showed efficient intrinsic charge generation within 10 ps in two of the porous polymers, even without the presence of ascorbic acid or Pt. Detectable hole polarons were found to be immediately extracted by added ascorbic acid, suggesting the generation of reactive charges at regions readily accessible to electrolyte in the porous structures. This study directs organic semiconductor photocatalysts design toward more hydrophilic functionality for addressing exciton and charge recombination bottlenecks and clearly demonstrates the advantages of wettable porosity as a design principle.

Published

2024

258. Impact of water solvation on the charge carrier dynamics of organic heterojunction photocatalyst nanoparticle dispersions.

Author

Gonzalez-Carrero S, Kosco J, Fei T, McCulloch I, and Durrant JR

Abstract

Organic heterojunction nanoparticles (NP) have recently gained significant interest as photocatalysts for visible light-driven hydrogen production. Whilst promising photocatalytic efficiencies have been reported for aqueous NP dispersions, the underlying dynamics of photogenerated charges in such organic heterojunction photocatalysts and how these might differ from more widely studied dry heterojunction films remain relatively unexplored. In this study, we combine transient optical spectroscopies over twelve orders of magnitude in time, using pulsed and continuous light illumination, to elucidate the differences in the charge carrier dynamics of heterojunction NP dispersions, dried NP films, and bulk heterojunction films prepared by spin coating. The ultrafast fast (ps to ns) transient absorption results show efficient charge generation and indistinguishable nanosecond charge recombination decay kinetics of separated charges in all three samples. In contrast, on the slower μs to ms time range, the decay kinetics of heterojunction NP dispersion exhibited up to 15-fold larger amplitude and more than one order of magnitude slower decay of the photogenerated charges than those in films. The analysis of the nanomorphology, NP surfactant, polymer residual metal content and local polar environment suggest that the longer lifetime differences (in ms) in the charge recombination in NP dispersion are mostly associated with a charge carrier stabilisation on a shallow density of states on the NP surface of ∼350 meV by interaction with local water environment, resulting in suppressed charge recombination. The lengthening of NP dispersion charge carrier lifetime is discussed regarding the energetic loss for function and their implications in photocatalysis., Competing Interests: There are no conflicts to declare., (This journal is © The Royal Society of Chemistry.)

Published

2024

259. Single ambipolar OECT-based inverter with volatility and nonvolatility on demand.

Author

Cong S, Chen J, Xie M, Deng Z, Chen C, Liu R, Duan J, Zhu X, Li Z, Cheng Y, Huang W, McCulloch I, and Yue W

Abstract

Organic electrochemical transistor (OECT)-based inverter introduces new prospects for energy-efficient brain-inspired artificial intelligence devices. Here, we report single-component OECT-based inverters by incorporating ambipolar p(gDPP-V). Notably, p(gDPP-V) shows state-of-the-art ambipolar OECT performances in both conventional (p/n-type mode transconductance of 29/25 S cm -1 ) and vertical (transconductance of 297.2/292.4 μS μm -2 under p/n operation) device architectures. Especially, the resulting highly stable vertical OECT-based inverter shows a high voltage gain of 105 V V -1 under a low driving voltage of 0.8 V. The inverter exhibits undiscovered voltage-regulated dual mode: volatile receptor and nonvolatile synapse. Moreover, applications of physiology signal recording and demonstrations of NAND/NOR logic circuits are investigated within the volatile feature, while neuromorphic simulations with a convolutional neural network and image memorizing capabilities are explored under the nonvolatile behavior. The ambipolar OECT-based inverter, capable of both volatile and nonvolatile operations, provides possibilities for the applications of reconfigurable complementary logic circuits in novel neuromorphic computing paradigms.

Published

2024

260. High Efficiency n-Type Doping of Organic Semiconductors by Cation Exchange.

Author

Zhao X, Alsufyani M, Tian J, Lin Y, Jeong SY, Han YW, Yin Y, and McCulloch I

Abstract

Achieving efficient doping in n-type conjugated polymers is crucial for their application in electronic devices. In this study, an n-type doping method is developed based on cation exchange that maintains a high doping level while ensuring a high degree of structural order, leading to significantly improved electrical conductivity. By investigating various dopants and ionic liquids, it is discovered that the choice of dopant influences doping efficiency, while the selection of ionic liquid affects cation exchange efficiency. Through careful selection of suitable dopants and ionic liquids, High doping levels are achieved remarkably in a short period, resulting in the highest conductivity (nearly 1 × 10 - 2  S cm - ¹) compared to other doping methods for poly{[N,N'-bis(2-octyldodecyl)-naphthalene-1,4,5,8-bis(dicarboximide)-2,6-diyl]-alt-5,5'-(2,2'-bithiophene)} (N2200). The findings highlight the robustness and efficiency of cation exchange doping as an effective approach for achieving high-quality n-type doping in conjugated polymers, thereby opening new avenues for the development of advanced polymer-based electronic devices., (© 2024 Wiley‐VCH GmbH.)

Published

2024

261. Designing Contact Independent High-Performance Low-Cost Flexible Electronics.

Author

Waldrip M, Yu Y, Dremann D, Losi T, Willner B, Caironi M, McCulloch I, and Jurchescu OD

Abstract

Organic semiconductors enable low-cost solution processing of optoelectronic devices on flexible substrates. Their use in contemporary applications, however, is sparse due to persistent challenges in achieving the requisite performance levels in a reliable and reproducible manner. A critical bottleneck is the inefficiency associated with charge injection. Here, large-scale simulations are employed to identify operational windows where key device parameters that are difficult to control experimentally, such as the contact resistance, become less consequential to overall device functionality. This design methodology overcomes injection barrier limitations in organic field-effect transistors (OFETs), leading to high charge carrier mobility and significantly expanding the range of suitable electrode materials. Leveraging this new understanding, all-organic, solution-deposited OFETs are successfully fabricated on flexible substrates. These devices incorporate printed contacts and showcase mobilities exceeding 5 cm 2  Vs -1 . These results provide a route for accessing the fundamental limits of material properties even in the absence of ideal contacts - a critical step in establishing reliable structure/property relationships and optimal material design paradigms. While reducing the injection barrier and contact resistance remains critical for achieving high OFET performance, this work demonstrates a path toward consistently achieving high charge carrier mobility through device geometry design, ultimately reducing processing complexity and cost., (© 2024 The Author(s). Advanced Materials published by Wiley‐VCH GmbH.)

Published

2024

262. Unveiling Nanoscale Ordering in Amorphous Semiconducting Polymers Using Four-Dimensional Scanning Transmission Electron Microscopy.

Author

Calderón Ortiz GA, Zhu M, Wadsworth A, Dou L, McCulloch I, and Hwang J

Abstract

We present four-dimensional (4D) scanning transmission electron microscopy (STEM) analysis to obtain a high level of detail regarding the nanoscale ordering within largely disordered organic semiconducting polymers. Understanding nanoscale molecular ordering in semiconducting polymers is crucial due to its connection to the materials' important properties. However, acquiring such information in a spatially localized manner has been limited by the lack of a nanoscale experimental probe, weak signal from ordering, and radiation damage to the sample. By collecting nanodiffraction patterns with a high dynamic range pixelated detector, we acquired statistically robust, high signal-to-noise ratio diffraction patterns from semiconducting organic materials, including poly(3-hexylthiophene-2,5-diyl) (P3HT), P3HT/[6,6]-phenyl C61 butyric acid methyl ester, and indacenodithiophene- co -benzothiadiazole (IDTBT), which largely have disordered structures. Real-space images of the ordered domains were reconstructed from the 4D-STEM data set for a variety of scattering vectors and in-plane angles to capture the different molecular stacking distances and their in-plane orientation. These were then analyzed to obtain the average size of the ordered domains within the sample. Such measurements were arranged in a two-dimensional (2D) histogram, which showed a direct relationship between the type and size of molecular ordering. Complementary analyses, such as intensity variance and angular correlation, were applied to obtain ordering and symmetry information. These analyses enabled us to directly characterize the alkyl and π-π stacking of P3HT, as well as the fullerene domains caused by donor segregation in the P3HT sample. Furthermore, the analysis also captured changes in the P3HT domains when the fullerenes are incorporated. Lastly, IDTBT showed a much lesser degree of ordering without much disinclination between the domains within the 2D histogram. The 4D-STEM analysis that we report here unveils new details of molecular ordering that can be used to optimize the properties of this important class of materials.

Published

2024

263. The hierarchical structure of organic mixed ionic-electronic conductors and its evolution in water.

Author

Tsarfati Y, Bustillo KC, Savitzky BH, Balhorn L, Quill TJ, Marks A, Donohue J, Zeltmann SE, Takacs CJ, Giovannitti A, McCulloch I, Ophus C, Minor AM, and Salleo A

Abstract

Polymeric organic mixed ionic-electronic conductors underpin several technologies in which their electrochemical properties are desirable. These properties, however, depend on the microstructure that develops in their aqueous operational environment. We investigated the structure of a model organic mixed ionic-electronic conductor across multiple length scales using cryogenic four-dimensional scanning transmission electron microscopy in both its dry and hydrated states. Four-dimensional scanning transmission electron microscopy allows us to identify the prevalent defects in the polymer crystalline regions and to analyse the liquid crystalline nature of the polymer. The orientation maps of the dry and hydrated polymers show that swelling-induced disorder is mostly localized in discrete regions, thereby largely preserving the liquid crystalline order. Therefore, the liquid crystalline mesostructure makes electronic transport robust to electrolyte ingress. This study demonstrates that cryogenic four-dimensional scanning transmission electron microscopy provides multiscale structural insights into complex, hierarchical structures such as polymeric organic mixed ionic-electronic conductors, even in their hydrated operating state., (© 2024. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2024

264. Perpendicular crossing chains enable high mobility in a noncrystalline conjugated polymer.

Author

Coker JF, Moro S, Gertsen AS, Shi X, Pearce D, van der Schelling MP, Xu Y, Zhang W, Andreasen JW, Snyder CR, Richter LJ, Bird MJ, McCulloch I, Costantini G, Frost JM, and Nelson J

Abstract

The nature of interchain π-system contacts, and their relationship to hole transport, are elucidated for the high-mobility, noncrystalline conjugated polymer C16-IDTBT by the application of scanning tunneling microscopy, molecular dynamics, and quantum chemical calculations. The microstructure is shown to favor an unusual packing motif in which paired chains cross-over one another at near-perpendicular angles. By linking to mesoscale microstructural features, revealed by coarse-grained molecular dynamics and previous studies, and performing simulations of charge transport, it is demonstrated that the high mobility of C16-IDTBT can be explained by the promotion of a highly interconnected transport network, stemming from the adoption of perpendicular contacts at the nanoscale, in combination with fast intrachain transport., Competing Interests: Competing interests statement:The authors declare no competing interest.

Published

2024

265. The Effect of Organic Semiconductor Electron Affinity on Preventing Parasitic Oxidation Reactions Limiting Performance of n-Type Organic Electrochemical Transistors.

Author

Alsufyani M, Moss B, Tait CE, Myers WK, Shahi M, Stewart K, Zhao X, Rashid RB, Meli D, Wu R, Paulsen BD, Thorley K, Lin Y, Combe C, Kniebe-Evans C, Inal S, Jeong SY, Woo HY, Ritchie G, Kim JS, Rivnay J, Paterson A, Durrant JR, and McCulloch I

Abstract

A key challenge in the development of organic mixed ionic-electronic conducting materials (OMIEC) for high performance electrochemical transistors is their stable performance in ambient. When operating in aqueous electrolyte, potential reactions of the electrochemically injected electrons with air and water could hinder their persistence, leading to a reduction in charge transport. Here, the impact of deepening the LUMO energy level of a series of electron-transporting semiconducting polymers is evaluated, and subsequently rendering the most common oxidation processes of electron polarons thermodynamically unfavorable, on organic electrochemical transistors (OECTs) performance. Employing time resolved spectroelectrochemistry with three analogous polymers having varying electron affinities (EA), it is found that an EA below the thermodynamic threshold for oxidation of its electron polarons by oxygen significantly improves electron transport and lifetime in air. A polymer with a sufficiently large EA and subsequent thermodynamically unfavorable oxidation of electron polarons is reported, which is used as the semiconducting layer in an OECT, in its neutral and N-DMBI doped form, resulting in an excellent and air-stable OECT performance. These results show a general design methodology to avoid detrimental parasitic reactions under ambient conditions, and the benefits that arise in electrical performance., (© 2024 The Author(s). Advanced Materials published by Wiley‐VCH GmbH.)

Published

2024

266. A Universal Biocompatible and Multifunctional Solid Electrolyte in p-Type and n-Type Organic Electrochemical Transistors for Complementary Circuits and Bioelectronic Interfaces.

Author

Tang CG, Wu R, Chen Y, Zhou Z, He Q, Li T, Wu X, Hou K, Kousseff CJ, McCulloch I, and Leong WL

Abstract

The development of soft and flexible devices for collection of bioelectrical signals is gaining momentum for wearable and implantable applications. Among these devices, organic electrochemical transistors (OECTs) stand out due to their low operating voltage and large signal amplification capable of transducing weak biological signals. While liquid electrolytes have demonstrated efficacy in OECTs, they limit its operating temperature and pose challenges for electronic packaging due to potential leakage. Conversely, solid electrolytes offer advantages such as mechanical flexibility, robustness against environmental factors, and ability to bridge the interface between rigid dry electronics systems and soft wet biological tissues. However, few systems have demonstrated generality and compatibility with a wide range of state-of-the-art organic mixed ionic-electronic conductors (OMIECs). This paper introduces a highly stretchable, flexible, biocompatible, self-healable gelatin-based solid-state electrolyte, compatible with both p- and n-type OMIEC channels while maintaining high performance and excellent stability. Furthermore, this nonvolatile electrolyte is stable up to 120 °C and exhibits high ionic conductivity even in dry environment. Additionally, an OECT-based complementary inverter with a record-high normalized-gain of 228 V -1 and a corresponding ultralow static power consumption of 1 nW is demonstrated. These advancements pave the way for versatile applications ranging from bioelectronics to power-efficient implants., (© 2024 The Author(s). Advanced Materials published by Wiley‐VCH GmbH.)

Published

2024

267. Multi-heterojunctioned plastics with high thermoelectric figure of merit.

Author

Wang D, Ding J, Ma Y, Xu C, Li Z, Zhang X, Zhao Y, Zhao Y, Di Y, Liu L, Dai X, Zou Y, Kim B, Zhang F, Liu Z, McCulloch I, Lee M, Chang C, Yang X, Wang D, Zhang D, Zhao LD, Di CA, and Zhu D

Abstract

Conjugated polymers promise inherently flexible and low-cost thermoelectrics for powering the Internet of Things from waste heat 1,2 . Their valuable applications, however, have been hitherto hindered by the low dimensionless figure of merit (ZT) 3-6 . Here we report high-ZT thermoelectric plastics, which were achieved by creating a polymeric multi-heterojunction with periodic dual-heterojunction features, where each period is composed of two polymers with a sub-ten-nanometre layered heterojunction structure and an interpenetrating bulk-heterojunction interface. This geometry produces significantly enhanced interfacial phonon-like scattering while maintaining efficient charge transport. We observed a significant suppression of thermal conductivity by over 60 per cent and an enhanced power factor when compared with individual polymers, resulting in a ZT of up to 1.28 at 368 kelvin. This polymeric thermoelectric performance surpasses that of commercial thermoelectric materials and existing flexible thermoelectric candidates. Importantly, we demonstrated the compatibility of the polymeric multi-heterojunction structure with solution coating techniques for satisfying the demand for large-area plastic thermoelectrics, which paves the way for polymeric multi-heterojunctions towards cost-effective wearable thermoelectric technologies., (© 2024. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2024

268. Reconfiguration of organic electrochemical transistors for high-accuracy potentiometric sensing.

Author

Salvigni L, Nayak PD, Koklu A, Arcangeli D, Uribe J, Hama A, Silva R, Hidalgo Castillo TC, Griggs S, Marks A, McCulloch I, and Inal S

Abstract

Organic electrochemical transistors have emerged as a promising alternative to traditional 2/3 electrode setups for sensing applications, offering in-situ transduction, electrochemical amplification, and noise reduction. Several of these devices are designed to detect potentiometric-derived signals. However, potentiometric sensing should be performed under open circuit potential conditions, allowing the system to reach thermodynamic equilibrium. This criterion is not met by conventional organic electrochemical transistors, where voltages or currents are directly applied to the sensing interface, that is, the gate electrode. In this work, we introduce an organic electrochemical transistor sensing configuration called the potentiometric‑OECT (pOECT), which maintains the sensing electrode under open circuit potential conditions. The pOECT exhibits a higher response than the 2-electrode setup and offers greater accuracy, response, and stability compared to conventional organic electrochemical transistors. Additionally, it allows for the implementation of high-impedance electrodes as gate/sensing surfaces, all without compromising the overall device size., (© 2024. The Author(s).)

Published

2024

269. Stable n-Type Perylene Derivative Ladder Polymer with Antiambipolarity for Electrically Reconfigurable Organic Logic Gates.

Author

Wu X, He Q, Zhou Z, Tam TLD, Tang C, Lin M, Moser M, Griggs S, Marks A, Chen S, Xu J, McCulloch I, and Leong WL

Abstract

Organic electrochemical transistors (OECTs) are one of the promising building blocks to realize next-generation bioelectronics. To date, however, the performance and signal processing capabilities of these devices remain limited by their stability and speed. Herein, the authors demonstrate stable and fast n-type organic electrochemical transistors based on a side-chain-free ladder polymer, poly(benzimidazoanthradiisoquinolinedione). The device demonstrated fast normalized transient speed of 0.56 ± 0.17 ms um -2 and excellent long-term stability in aqueous electrolytes, with no significant drop in its doping current after 50 000 successive doping/dedoping cycles and 2-month storage at ambient conditions. These unique characteristics make this polymer especially suitable for bioelectronics, such as being used as a pull-down channel in a complementary inverter for long-term stable detection of electrophysiological signals. Moreover, the developed device shows a reversible anti-ambipolar behavior, enabling reconfigurable electronics to be realized using a single material. These results go beyond the conventional OECT and demonstrate the potential of OECTs to exhibit dynamically configurable functionalities for next-generation reconfigurable electronics., (© 2024 Wiley‐VCH GmbH.)

Published

2024

270. Non-equilibrium transport in polymer mixed ionic-electronic conductors at ultrahigh charge densities.

Author

Tjhe DHL, Ren X, Jacobs IE, D'Avino G, Mustafa TBE, Marsh TG, Zhang L, Fu Y, Mansour AE, Opitz A, Huang Y, Zhu W, Unal AH, Hoek S, Lemaur V, Quarti C, He Q, Lee JK, McCulloch I, Heeney M, Koch N, Grey CP, Beljonne D, Fratini S, and Sirringhaus H

Abstract

Conducting polymers are mixed ionic-electronic conductors that are emerging candidates for neuromorphic computing, bioelectronics and thermoelectrics. However, fundamental aspects of their many-body correlated electron-ion transport physics remain poorly understood. Here we show that in p-type organic electrochemical transistors it is possible to remove all of the electrons from the valence band and even access deeper bands without degradation. By adding a second, field-effect gate electrode, additional electrons or holes can be injected at set doping states. Under conditions where the counterions are unable to equilibrate in response to field-induced changes in the electronic carrier density, we observe surprising, non-equilibrium transport signatures that provide unique insights into the interaction-driven formation of a frozen, soft Coulomb gap in the density of states. Our work identifies new strategies for substantially enhancing the transport properties of conducting polymers by exploiting non-equilibrium states in the coupled system of electronic charges and counterions., (© 2024. The Author(s).)

Published

2024

271. SpyDirect: A Novel Biofunctionalization Method for High Stability and Longevity of Electronic Biosensors.

Author

Guo K, Grünberg R, Ren Y, Chang T, Wustoni S, Strnad O, Koklu A, Díaz-Galicia E, Agudelo JP, Druet V, Castillo TCH, Moser M, Ohayon D, Hama A, Dada A, McCulloch I, Viola I, Arold ST, and Inal S

Subjects

Gold chemistry, Electrodes, Electrochemical Techniques methods, Electrochemical Techniques instrumentation, Single-Domain Antibodies chemistry, Biosensing Techniques methods, Biosensing Techniques instrumentation

Abstract

Electronic immunosensors are indispensable tools for diagnostics, particularly in scenarios demanding immediate results. Conventionally, these sensors rely on the chemical immobilization of antibodies onto electrodes. However, globular proteins tend to adsorb and unfold on these surfaces. Therefore, self-assembled monolayers (SAMs) of thiolated alkyl molecules are commonly used for indirect gold-antibody coupling. Here, a limitation associated with SAMs is revealed, wherein they curtail the longevity of protein sensors, particularly when integrated into the state-of-the-art transducer of organic bioelectronics-the organic electrochemical transistor. The SpyDirect method is introduced, generating an ultrahigh-density array of oriented nanobody receptors stably linked to the gold electrode without any SAMs. It is accomplished by directly coupling cysteine-terminated and orientation-optimized spyTag peptides, onto which nanobody-spyCatcher fusion proteins are autocatalytically attached, yielding a dense and uniform biorecognition layer. The structure-guided design optimizes the conformation and packing of flexibly tethered nanobodies. This biolayer enhances shelf-life and reduces background noise in various complex media. SpyDirect functionalization is faster and easier than SAM-based methods and does not necessitate organic solvents, rendering the sensors eco-friendly, accessible, and amenable to scalability. SpyDirect represents a broadly applicable biofunctionalization method for enhancing the cost-effectiveness, sustainability, and longevity of electronic biosensors, all without compromising sensitivity., (© 2023 The Authors. Advanced Science published by Wiley‐VCH GmbH.)

Published

2024

272. Li Promoting Long Afterglow Organic Light-Emitting Transistor for Memory Optocoupler Module.

Author

Chen Y, Wang H, Chen H, Zhang W, Pätzel M, Han B, Wang K, Xu S, Montes-García V, McCulloch I, Hecht S, and Samorì P

Subjects

Humans, Memory, Light, Organic Chemicals chemistry, Brain physiology, Transistors, Electronic, Lithium chemistry

Abstract

The artificial brain is conceived as advanced intelligence technology, capable to emulate in-memory processes occurring in the human brain by integrating synaptic devices. Within this context, improving the functionality of synaptic transistors to increase information processing density in neuromorphic chips is a major challenge in this field. In this article, Li-ion migration promoting long afterglow organic light-emitting transistors, which display exceptional postsynaptic brightness of 7000 cd m -2 under low operational voltages of 10 V is presented. The postsynaptic current of 0.1 mA operating as a built-in threshold switch is implemented as a firing point in these devices. The setting-condition-triggered long afterglow is employed to drive the photoisomerization process of photochromic molecules that mimic neurotransmitter transfer in the human brain for realizing a key memory rule, that is, the transition from long-term memory to permanent memory. The combination of setting-condition-triggered long afterglow with photodiode amplifiers is also processed to emulate the human responding action after the setting-training process. Overall, the successful integration in neuromorphic computing comprising stimulus judgment, photon emission, transition, and encoding,  to emulate the complicated decision tree of the human brain is demonstrated., (© 2024 The Authors. Advanced Materials published by Wiley‐VCH GmbH.)

Published

2024

273. Unravelling the operation of organic artificial neurons for neuromorphic bioelectronics.

Author

Belleri P, Pons I Tarrés J, McCulloch I, Blom PWM, Kovács-Vajna ZM, Gkoupidenis P, and Torricelli F

Subjects

Action Potentials physiology, Neural Networks, Computer, Neurons physiology, Electronics instrumentation, Models, Neurological

Abstract

Organic artificial neurons operating in liquid environments are crucial components in neuromorphic bioelectronics. However, the current understanding of these neurons is limited, hindering their rational design and development for realistic neuronal emulation in biological settings. Here we combine experiments, numerical non-linear simulations, and analytical tools to unravel the operation of organic artificial neurons. This comprehensive approach elucidates a broad spectrum of biorealistic behaviors, including firing properties, excitability, wetware operation, and biohybrid integration. The non-linear simulations are grounded in a physics-based framework, accounting for ion type and ion concentration in the electrolytic medium, organic mixed ionic-electronic parameters, and biomembrane features. The derived analytical expressions link the neurons spiking features with material and physical parameters, bridging closer the domains of artificial neurons and neuroscience. This work provides streamlined and transferable guidelines for the design, development, engineering, and optimization of organic artificial neurons, advancing next generation neuronal networks, neuromorphic electronics, and bioelectronics., (© 2024. The Author(s).)

Published

2024

274. N-Type polymeric mixed conductors for all-in-one aqueous electrolyte gated photoelectrochemical transistors.

Author

Almulla L, Druet V, E Petoukhoff C, Shan W, Alshehri N, Griggs S, Wang Y, Alsufyani M, Yue W, McCulloch I, Laquai F, and Inal S

Abstract

An organic photoelectrochemical transistor (OPECT) is an organic electrochemical transistor (OECT) that utilizes light to toggle between ON and OFF states. The current response to light and voltage fluxes in aqueous media renders the OPECT ideal for the development of next-generation bioelectronic devices, including light-assisted biosensors, light-controlled logic gates, and artificial photoreceptors. However, existing OPECT architectures are complex, often requiring photoactive nanostructures prepared through labor-intensive synthetic methods, and despite this complexity, their performance remains limited. In this study, we develop aqueous electrolyte-compatible optoelectronic transistors using a single n-type semiconducting polymer. The n-type film performs multiple tasks: (1) gating the channel, (2) generating a photovoltage in response to light, and (3) coupling and transporting cations and electrons in the channel. We systematically investigate the photoelectrochemical properties of a range of n-type polymeric mixed conductors to understand the material requirements for maximizing phototransistor performance. Our findings contribute to the identification of crucial material and device properties necessary for constructing high-performance OPECTs with simplified design features and a direct interface with biological systems.

Published

2024

275. Bio-inspired multimodal learning with organic neuromorphic electronics for behavioral conditioning in robotics.

Author

Krauhausen I, Griggs S, McCulloch I, den Toonder JMJ, Gkoupidenis P, and van de Burgt Y

Subjects

Electronics instrumentation, Learning physiology, Humans, Robotics instrumentation, Robotics methods, Neural Networks, Computer

Abstract

Biological systems interact directly with the environment and learn by receiving multimodal feedback via sensory stimuli that shape the formation of internal neuronal representations. Drawing inspiration from biological concepts such as exploration and sensory processing that eventually lead to behavioral conditioning, we present a robotic system handling objects through multimodal learning. A small-scale organic neuromorphic circuit locally integrates and adaptively processes multimodal sensory stimuli, enabling the robot to interact intelligently with its surroundings. The real-time handling of sensory stimuli via low-voltage organic neuromorphic devices with synaptic functionality forms multimodal associative connections that lead to behavioral conditioning, and thus the robot learns to avoid potentially dangerous objects. This work demonstrates that adaptive neuro-inspired circuitry with multifunctional organic materials, can accommodate locally efficient bio-inspired learning for advancing intelligent robotics., (© 2024. The Author(s).)

Published

2024

276. In Recognition of the Instrumental Contribution of Donal Bradley to the Field of Condensed Matter and Applied Physics.

Author

McCulloch I, Stingelin N, and Anthopoulos TD

Published

2024

277. Templated 2D Polymer Heterojunctions for Improved Photocatalytic Hydrogen Production.

Author

Aitchison CM, Gonzalez-Carrero S, Yao S, Benkert M, Ding Z, Young NP, Willner B, Moruzzi F, Lin Y, Tian J, Nellist PD, Durrant JR, and McCulloch I

Abstract

2D polymers have emerged as one of the most promising classes of organic photocatalysts for solar fuel production due to their tunability, charge-transport properties, and robustness. They are however difficult to process and so there are limited studies into the formation of heterojunction materials incorporating these components. In this work, a novel templating approach is used to combine an imine-based donor polymer and an acceptor polymer formed through Knoevenagel condensation. Heterojunction formation is shown to be highly dependent on the topological match of the donor and acceptor polymers with the most active templated material found to be between three and nine times more active for photocatalysis than its constituent components. Transient absorption spectroscopy reveals that this improvement is due to faster charge separation and more efficient charge extraction in the templated heterojunction. The templated material shows a very high hydrogen evolution rate of >20 mmol h -1 m -2 with an ascorbic acid hole scavenger but also produces hydrogen in the presence of only water and a cobalt-based redox mediator. This suggests the improved charge-separation interface and reduced trapping accessed through this approach could be suitable for Z-scheme formation., (© 2023 The Authors. Advanced Materials published by Wiley‐VCH GmbH.)

Published

2024

278. Drug delivery via a 3D electro-swellable conjugated polymer hydrogel.

Author

Abdel Aziz I, Gladisch J, Griggs S, Moser M, Biesmans H, Beloqui A, McCulloch I, Berggren M, and Stavrinidou E

Subjects

Insulin administration & dosage, Insulin chemistry, Particle Size, Thiophenes chemistry, Porosity, Drug Carriers chemistry, Drug Liberation, Surface Properties, Hydrogels chemistry, Polymers chemistry, Drug Delivery Systems

Abstract

Spatiotemporal controlled drug delivery minimizes side-effects and enables therapies that require specific dosing patterns. Conjugated polymers (CP) can be used for electrically controlled drug delivery; however so far, most demonstrations were limited to molecules up to 500 Da. Larger molecules could be incorporated only during the CP polymerization and thus limited to a single delivery. This work harnesses the record volume changes of a glycolated polythiophene p(g3T2) for controlled drug delivery. p(g3T2) undergoes reversible volumetric changes of up to 300% during electrochemical doping, forming pores in the nm-size range, resulting in a conducting hydrogel. p(g3T2)-coated 3D carbon sponges enable controlled loading and release of molecules spanning molecular weights of 800-6000 Da, from simple dyes up to the hormone insulin. Molecules are loaded as a combination of electrostatic interactions with the charged polymer backbone and physical entrapment in the porous matrix. Smaller molecules leak out of the polymer while larger ones could not be loaded effectively. Finally, this work shows the temporally patterned release of molecules with molecular weight of 1300 Da and multiple reloading and release cycles without affecting the on/off ratio.

Published

2024

279. Electrochemical modulation of mechanical properties of glycolated polythiophenes.

Author

Abdel Aziz I, Gladisch J, Musumeci C, Moser M, Griggs S, Kousseff CJ, Berggren M, McCulloch I, and Stavrinidou E

Abstract

Electrochemical doping of organic mixed ionic-electronic conductors is key for modulating their conductivity, charge storage and volume enabling high performing bioelectronic devices such as recording and stimulating electrodes, transistors-based sensors and actuators. However, electrochemical doping has not been explored to the same extent for modulating the mechanical properties of OMIECs on demand. Here, we report a qualitative and quantitative study on how the mechanical properties of a glycolated polythiophene, p(g3T2), change in situ during electrochemical doping and de-doping. The Young's modulus of p(g3T2) changes from 69 MPa in the dry state to less than 10 MPa in the hydrated state and then further decreases down to 0.4 MPa when electrochemically doped. With electrochemical doping-dedoping the Young's modulus of p(g3T2) changes by more than one order of magnitude reversibly, representing the largest modulation reported for an OMIEC. Furthermore, we show that the electrolyte concentration affects the magnitude of the change, demonstrating that in less concentrated electrolytes more water is driven into the film due to osmosis and therefore the film becomes softer. Finally, we find that the oligo ethylene glycol side chain functionality, specifically the length and asymmetry, affects the extent of modulation. Our findings show that glycolated polythiophenes are promising materials for mechanical actuators with a tunable modulus similar to the range of biological tissues, thus opening a pathway for new mechanostimulation devices.

Published

2024

280. A modular organic neuromorphic spiking circuit for retina-inspired sensory coding and neurotransmitter-mediated neural pathways.

Author

Matrone GM, van Doremaele ERW, Surendran A, Laswick Z, Griggs S, Ye G, McCulloch I, Santoro F, Rivnay J, and van de Burgt Y

Subjects

Humans, Action Potentials physiology, Neurons, Afferent, Synapses physiology, Neurotransmitter Agents, Neurons physiology, Interneurons

Abstract

Signal communication mechanisms within the human body rely on the transmission and modulation of action potentials. Replicating the interdependent functions of receptors, neurons and synapses with organic artificial neurons and biohybrid synapses is an essential first step towards merging neuromorphic circuits and biological systems, crucial for computing at the biological interface. However, most organic neuromorphic systems are based on simple circuits which exhibit limited adaptability to both external and internal biological cues, and are restricted to emulate only specific the functions of an individual neuron/synapse. Here, we present a modular neuromorphic system which combines organic spiking neurons and biohybrid synapses to replicate a neural pathway. The spiking neuron mimics the sensory coding function of afferent neurons from light stimuli, while the neuromodulatory activity of interneurons is emulated by neurotransmitters-mediated biohybrid synapses. Combining these functions, we create a modular connection between multiple neurons to establish a pre-processing retinal pathway primitive., (© 2024. The Author(s).)

Published

2024

281. Charge Carrier Induced Structural Ordering And Disordering in Organic Mixed Ionic Electronic Conductors.

Author

Quill TJ, LeCroy G, Marks A, Hesse SA, Thiburce Q, McCulloch I, Tassone CJ, Takacs CJ, Giovannitti A, and Salleo A

Abstract

Operational stability underpins the successful application of organic mixed ionic-electronic conductors (OMIECs) in a wide range of fields, including biosensing, neuromorphic computing, and wearable electronics. In this work, both the operation and stability of a p-type OMIEC material of various molecular weights are investigated. Electrochemical transistor measurements reveal that device operation is very stable for at least 300 charging/discharging cycles independent of molecular weight, provided the charge density is kept below the threshold where strong charge-charge interactions become likely. When electrochemically charged to higher charge densities, an increase in device hysteresis and a decrease in conductivity due to a drop in the hole mobility arising from long-range microstructural disruptions are observed. By employing operando X-ray scattering techniques, two regimes of polaron-induced structural changes are found: 1) polaron-induced structural ordering at low carrier densities, and 2) irreversible structural disordering that disrupts charge transport at high carrier densities, where charge-charge interactions are significant. These operando measurements also reveal that the transfer curve hysteresis at high carrier densities is accompanied by an analogous structural hysteresis, providing a microstructural basis for such instabilities. This work provides a mechanistic understanding of the structural dynamics and material instabilities of OMIEC materials during device operation., (© 2024 Wiley‐VCH GmbH.)

Published

2024

282. The Role of Side Chains and Hydration on Mixed Charge Transport in n-Type Polymer Films.

Author

Surgailis J, Flagg LQ, Richter LJ, Druet V, Griggs S, Wu X, Moro S, Ohayon D, Kousseff CJ, Marks A, Maria IP, Chen H, Moser M, Costantini G, McCulloch I, and Inal S

Abstract

Introducing ethylene glycol (EG) side chains to a conjugated polymer backbone is a well-established synthetic strategy for designing organic mixed ion-electron conductors (OMIECs). However, the impact that film swelling has on mixed conduction properties has yet to be scoped, particularly for electron-transporting (n-type) OMIECs. Here, the authors investigate the effect of the length of branched EG chains on mixed charge transport of n-type OMIECs based on a naphthalene-1,4,5,8-tetracarboxylic-diimide-bithiophene backbone. Atomic force microscopy (AFM), grazing-incidence wide-angle X-ray scattering (GIWAXS), and scanning tunneling microscopy (STM) are used to establish the similarities between the common-backbone films in dry conditions. Electrochemical quartz crystal microbalance with dissipation monitoring (EQCM-D) and in situ GIWAXS measurements reveal stark changes in film swelling properties and microstructure during electrochemical doping, depending on the side chain length. It is found that even in the loss of the crystallite content upon contact with the aqueous electrolyte, the films can effectively transport charges and that it is rather the high water content that harms the electronic interconnectivity within the OMIEC films. These results highlight the importance of controlling water uptake in the films to impede charge transport in n-type electrochemical devices., (© 2024 The Authors. Advanced Materials published by Wiley‐VCH GmbH.)

Published

2024

283. Complementary integration of organic electrochemical transistors for front-end amplifier circuits of flexible neural implants.

Author

Uguz I, Ohayon D, Yilmaz S, Griggs S, Sheelamanthula R, Fabbri JD, McCulloch I, Inal S, and Shepard KL

Abstract

The ability to amplify, translate, and process small ionic potential fluctuations of neural processes directly at the recording site is essential to improve the performance of neural implants. Organic front-end analog electronics are ideal for this application, allowing for minimally invasive amplifiers owing to their tissue-like mechanical properties. Here, we demonstrate fully organic complementary circuits by pairing depletion- and enhancement-mode p- and n-type organic electrochemical transistors (OECTs). With precise geometry tuning and a vertical device architecture, we achieve overlapping output characteristics and integrate them into amplifiers with single neuronal dimensions (20 micrometers). Amplifiers with combined p- and n-OECTs result in voltage-to-voltage amplification with a gain of >30 decibels. We also leverage depletion and enhancement-mode p-OECTs with matching characteristics to demonstrate a differential recording capability with high common mode rejection rate (>60 decibels). Integrating OECT-based front-end amplifiers into a flexible shank form factor enables single-neuron recording in the mouse cortex with on-site filtering and amplification.

Published

2024

284. Photocatalytic CO 2 reduction by topologically matched polymer-polymer heterojunction nanosheets.

Author

Aitchison CM, Zhang Y, Lu W, and McCulloch I

Abstract

Conversion of solar energy into chemical fuel can be achieved through a number of routes but direct conversion, via photocatalysis, is potentially the simplest and cheapest route to the transformation of low-value substances, water and CO 2 , to useful chemical fuels or feedstocks such as hydrogen, formate, methanol, and syngas. 2D polymers, including carbon nitrides and COFs, have emerged as one of the most promising classes of organic photocatalysts for solar fuels production due to their energetic tunability, charge transport properties and robustness. They are, however, difficult to process and so there have been limited studies into the formation of heterojunction materials incorporating these components. In this work we use our novel templating approach to combine topologically matched imine-based donor polymers with acceptor polymers formed through Knoevenagel condensation. An efficient heterojunction interface was formed by matching the isostructural nodes and linkers that make up the D1 and A1 semiconductors and this was reflected in the increased photocatalytic activity of the heterojunction material T1. Tuning of the templating synthesis route to give heterojunctions with optimised donor : acceptor ratios, as well as the photocatalytic conditions, resulted in CO production rates that were between 1.5 and 10 times higher than those of the individual polymers. A further set of polymers A5 and D5 were developed with more optimised structures for CO 2 reduction including increased overpotential for the reduction reaction and the presence of co-catalyst chelating groups. These had increased activity compared to the group 1 family and again showed higher activity for CO production by the templated heterojunction, T5, than either individual component or a physical mixture of the donor and acceptor.

Published

2024

285. Organic Photovoltaic Materials for Solar Fuel Applications: A Perfect Match?

Author

Aitchison CM and McCulloch I

Abstract

This work discusses the use of donor and acceptor materials from organic photovoltaics in solar fuel applications. These two routes to solar energy conversion have many shared materials design parameters, and in recent years there has been increasing overlap of the molecules and polymers used in each. Here, we examine whether this is a good approach, where knowledge can be translated, and where further consideration to molecular design is required., Competing Interests: The authors declare no competing financial interest., (© 2024 The Authors. Published by American Chemical Society.)

Published

2024

286. Eutectogels as a Semisolid Electrolyte for Organic Electrochemical Transistors.

Author

Zhong Y, Lopez-Larrea N, Alvarez-Tirado M, Casado N, Koklu A, Marks A, Moser M, McCulloch I, Mecerreyes D, and Inal S

Abstract

Organic electrochemical transistors (OECTs) are signal transducers offering high amplification, which makes them particularly advantageous for detecting weak biological signals. While OECTs typically operate with aqueous electrolytes, those employing solid-like gels as the dielectric layer can be excellent candidates for constructing wearable electrophysiology probes. Despite their potential, the impact of the gel electrolyte type and composition on the operation of the OECT and the associated device design considerations for optimal performance with a chosen electrolyte have remained ambiguous. In this work, we investigate the influence of three types of gel electrolytes-hydrogels, eutectogels, and iongels, each with varying compositions on the performance of OECTs. Our findings highlight the superiority of the eutectogel electrolyte, which comprises poly(glycerol 1,3-diglycerolate diacrylate) as the polymer matrix and choline chloride in combination with 1,3-propanediol deep eutectic solvent as the ionic component. This eutectogel electrolyte outperforms hydrogel and iongel counterparts of equivalent dimensions, yielding the most favorable transient and steady-state performance for both p-type depletion and p-type/n-type enhancement mode transistors gated with silver/silver chloride (Ag/AgCl). Furthermore, the eutectogel-integrated enhancement mode OECTs exhibit exceptional operational stability, reflected in the absence of signal-to-noise ratio (SNR) variation in the simulated electrocardiogram (ECG) recordings conducted continuously over a period of 5 h, as well as daily measurements spanning 30 days. Eutectogel-based OECTs also exhibit higher ECG signal amplitudes and SNR than their counterparts, utilizing the commercially available hydrogel, which is the most common electrolyte for cutaneous electrodes. These findings underscore the potential of eutectogels as a semisolid electrolyte for OECTs, particularly in applications demanding robust and prolonged physiological signal monitoring., Competing Interests: The authors declare no competing financial interest., (© 2024 The Authors. Published by American Chemical Society.)

Published

2024

287. Flexible switch matrix addressable electrode arrays with organic electrochemical transistor and pn diode technology.

Author

Uguz I, Ohayon D, Arslan V, Sheelamanthula R, Griggs S, Hama A, Stanton JW, McCulloch I, Inal S, and Shepard KL

Abstract

Due to their effective ionic-to-electronic signal conversion and mechanical flexibility, organic neural implants hold considerable promise for biocompatible neural interfaces. Current approaches are, however, primarily limited to passive electrodes due to a lack of circuit components to realize complex active circuits at the front-end. Here, we introduce a p-n organic electrochemical diode using complementary p- and n-type conducting polymer films embedded in a 15-μm -diameter vertical stack. Leveraging the efficient motion of encapsulated cations inside this polymer stack and the opposite doping mechanisms of the constituent polymers, we demonstrate high current rectification ratios ([Formula: see text]) and fast switching speeds (230 μs). We integrate p-n organic electrochemical diodes with organic electrochemical transistors in the front-end pixel of a recording array. This configuration facilitates the access of organic electrochemical transistor output currents within a large network operating in the same electrolyte, while minimizing crosstalk from neighboring elements due to minimized reverse-biased leakage. Furthermore, we use these devices to fabricate time-division-multiplexed amplifier arrays. Lastly, we show that, when fabricated in a shank format, this technology enables the multiplexing of amplified local field potentials directly in the active recording pixel (26-μm diameter) in a minimally invasive form factor with shank cross-sectional dimensions of only 50×8 [Formula: see text]., (© 2024. The Author(s).)

Published

2024

288. The organic electrochemical transistor conundrum when reporting a mixed ionic-electronic transport figure of merit.

Author

Shahi M, Le VN, Alarcon Espejo P, Alsufyani M, Kousseff CJ, McCulloch I, and Paterson AF

Published

2024

289. Ground-state electron transfer in all-polymer donor:acceptor blends enables aqueous processing of water-insoluble conjugated polymers.

Author

Liu T, Heimonen J, Zhang Q, Yang CY, Huang JD, Wu HY, Stoeckel MA, van der Pol TPA, Li Y, Jeong SY, Marks A, Wang XY, Puttisong Y, Shimolo AY, Liu X, Zhang S, Li Q, Massetti M, Chen WM, Woo HY, Pei J, McCulloch I, Gao F, Fahlman M, Kroon R, and Fabiano S

Abstract

Water-based conductive inks are vital for the sustainable manufacturing and widespread adoption of organic electronic devices. Traditional methods to produce waterborne conductive polymers involve modifying their backbone with hydrophilic side chains or using surfactants to form and stabilize aqueous nanoparticle dispersions. However, these chemical approaches are not always feasible and can lead to poor material/device performance. Here, we demonstrate that ground-state electron transfer (GSET) between donor and acceptor polymers allows the processing of water-insoluble polymers from water. This approach enables macromolecular charge-transfer salts with 10,000× higher electrical conductivities than pristine polymers, low work function, and excellent thermal/solvent stability. These waterborne conductive films have technological implications for realizing high-performance organic solar cells, with efficiency and stability superior to conventional metal oxide electron transport layers, and organic electrochemical neurons with biorealistic firing frequency. Our findings demonstrate that GSET offers a promising avenue to develop water-based conductive inks for various applications in organic electronics., (© 2023. The Author(s).)

Published

2023

290. Ionic Liquid Gated Organic Electrochemical Transistors with Broadened Bandwidth.

Author

Zhong Y, Nayak PD, Wustoni S, Surgailis J, Parrado Agudelo JZ, Marks A, McCulloch I, and Inal S

Abstract

The organic electrochemical transistor (OECT) is a biosignal transducer known for its high amplification but relatively slow operation. Here, we demonstrate that the use of an ionic liquid as the dielectric medium significantly improves the switching speed of a p-type enhancement-mode OECT, regardless of the gate electrode used. The OECT response time with the ionic liquid improves up to ca. 41-fold and 46-fold for the silver/silver chloride (Ag/AgCl) and gold (Au) gates, respectively, compared with devices gated with the phosphate buffered saline (PBS) solution. Notably, the transistor gain remains uncompromised, and its maximum is reached at lower voltages compared to those of PBS-gated devices with Ag/AgCl as the gate electrode. Through ultraviolet-visible spectroscopy and etching X-ray photoelectron spectroscopy characterizations, we reveal that the enhanced bandwidth is associated with the prediffused ionic liquid inside the polymer, leading to a higher doping level compared to PBS. Using the ionic liquid-gated OECTs, we successfully detect electrocardiography (ECG) signals, which exhibit a complete waveform with well-distinguished features and a stable signal baseline. By integrating nonaqueous electrolytes that enhance the device bandwidth, we unlock the potential of enhancement-mode OECTs for physiological signal acquisition and other real-time biosignal monitoring applications.

Published

2023

291. Effects of Processing-Induced Contamination on Organic Electronic Devices.

Author

Simatos D, Jacobs IE, Dobryden I, Nguyen M, Savva A, Venkateshvaran D, Nikolka M, Charmet J, Spalek LJ, Gicevičius M, Zhang Y, Schweicher G, Howe DJ, Ursel S, Armitage J, Dimov IB, Kraft U, Zhang W, Alsufyani M, McCulloch I, Owens RM, Claesson PM, Knowles TPJ, and Sirringhaus H

Abstract

Organic semiconductors are a family of pi-conjugated compounds used in many applications, such as displays, bioelectronics, and thermoelectrics. However, their susceptibility to processing-induced contamination is not well understood. Here, it is shown that many organic electronic devices reported so far may have been unintentionally contaminated, thus affecting their performance, water uptake, and thin film properties. Nuclear magnetic resonance spectroscopy is used to detect and quantify contaminants originating from the glovebox atmosphere and common laboratory consumables used during device fabrication. Importantly, this in-depth understanding of the sources of contamination allows the establishment of clean fabrication protocols, and the fabrication of organic field effect transistors (OFETs) with improved performance and stability. This study highlights the role of unintentional contaminants in organic electronic devices, and demonstrates that certain stringent processing conditions need to be met to avoid scientific misinterpretation, ensure device reproducibility, and facilitate performance stability. The experimental procedures and conditions used herein are typical of those used by many groups in the field of solution-processed organic semiconductors. Therefore, the insights gained into the effects of contamination are likely to be broadly applicable to studies, not just of OFETs, but also of other devices based on these materials., (© 2023 The Authors. Small Methods published by Wiley-VCH GmbH.)

Published

2023

292. Photo-Chemical Stimulation of Neurons with Organic Semiconductors.

Author

Savva A, Hama A, Herrera-López G, Schmidt T, Migliaccio L, Steiner N, Kawan M, Fiumelli H, Magistretti PJ, McCulloch I, Baran D, Gasparini N, Schindl R, Głowacki ED, and Inal S

Subjects

Stimulation, Chemical, Cell Culture Techniques, Polymers chemistry, Semiconductors, Neurons

Abstract

Recent advances in light-responsive materials enabled the development of devices that can wirelessly activate tissue with light. Here it is shown that solution-processed organic heterojunctions can stimulate the activity of primary neurons at low intensities of light via photochemical reactions. The p-type semiconducting polymer PDCBT and the n-type semiconducting small molecule ITIC (a non-fullerene acceptor) are coated on glass supports, forming a p-n junction with high photosensitivity. Patch clamp measurements show that low-intensity white light is converted into a cue that triggers action potentials in primary cortical neurons. The study shows that neat organic semiconducting p-n bilayers can exchange photogenerated charges with oxygen and other chemical compounds in cell culture conditions. Through several controlled experimental conditions, photo-capacitive, photo-thermal, and direct hydrogen peroxide effects on neural function are excluded, with photochemical delivery being the possible mechanism. The profound advantages of low-intensity photo-chemical intervention with neuron electrophysiology pave the way for developing wireless light-based therapy based on emerging organic semiconductors., (© 2023 The Authors. Advanced Science published by Wiley-VCH GmbH.)

Published

2023

293. Sustainability considerations for organic electronic products.

Author

McCulloch I, Chabinyc M, Brabec C, Nielsen CB, and Watkins SE

Abstract

The development of organic electronic applications has reached a critical point. While markets, including the Internet of Things, transparent solar and flexible displays, gain momentum, organic light-emitting diode displays lead the way, with a current market size of over $25 billion, helping to create the infrastructure and ecosystem for other applications to follow. It is imperative to design built-in sustainability into the materials selection, processing and device architectures of all of these emerging applications, and to close the loop for a circular approach. In this Perspective, we evaluate the status of embedded carbon in organic electronics, as well as options for more sustainable materials and manufacturing, including engineered recycling solutions that can be applied within the product architecture and at the end of life. This emerging industry has a responsibility to ensure a 'cradle-to-cradle' approach. We highlight that ease of dismantling and recycling needs to closely relate to the product lifetime, and that regeneration should be facilitated in product design. Materials choices should consider the environmental effects of synthesis, processing and end-product recycling as well as performance., (© 2023. Springer Nature Limited.)

Published

2023

294. Impact of Oligoether Side-Chain Length on the Thermoelectric Properties of a Polar Polythiophene.

Author

Craighero M, Guo J, Zokaei S, Griggs S, Tian J, Asatryan J, Kimpel J, Kroon R, Xu K, Reparaz JS, Martín J, McCulloch I, Campoy-Quiles M, and Müller C

Abstract

Conjugated polymers with oligoether side chains make up a promising class of thermoelectric materials. In this work, the impact of the side-chain length on the thermoelectric and mechanical properties of polythiophenes is investigated. Polymers with tri-, tetra-, or hexaethylene glycol side chains are compared, and the shortest length is found to result in thin films with the highest degree of order upon doping with the p-dopant 2,3,5,6-tetrafluoro-7,7,8,8-tetracyanoquinodimethane (F 4 TCNQ). As a result, a stiff material with an electrical conductivity of up to 830 ± 15 S cm -1 is obtained, resulting in a thermoelectric power factor of about 21 μW m -1 K -2 in the case of as-cast films. Aging at ambient conditions results in an initial decrease in thermoelectric properties but then yields a highly stable performance for at least 3 months, with values of about 200 S cm -1 and 5 μW m -1 K -2 . Evidently, identification of the optimal side-chain length is an important criterion for the design of conjugated polymers for organic thermoelectrics., Competing Interests: The authors declare no competing financial interest., (© 2023 The Authors. Published by American Chemical Society.)

Published

2023

295. A single n-type semiconducting polymer-based photo-electrochemical transistor.

Author

Druet V, Ohayon D, Petoukhoff CE, Zhong Y, Alshehri N, Koklu A, Nayak PD, Salvigni L, Almulla L, Surgailis J, Griggs S, McCulloch I, Laquai F, and Inal S

Abstract

Conjugated polymer films, which can conduct both ionic and electronic charges, are central to building soft electronic sensors and actuators. Despite the possible interplay between light absorption and the mixed conductivity of these materials in aqueous biological media, no single polymer film has been utilized to create a solar-switchable organic bioelectronic circuit that relies on a fully reversible and redox reaction-free potentiometric photodetection and current modulation. Here we demonstrate that the absorption of light by an electron and cation-transporting polymer film reversibly modulates its electrochemical potential and conductivity in an aqueous electrolyte, which is harnessed to design an n-type photo-electrochemical transistor (n-OPECT). By controlling the intensity of light incident on the n-type polymeric gate electrode, we generate transistor output characteristics that mimic the modulation of the polymeric channel current achieved through gate voltage control. The micron-scale n-OPECT exhibits a high signal-to-noise ratio and an excellent sensitivity to low light intensities. We demonstrate three direct applications of the n-OPECT, i.e., a photoplethysmogram recorder, a light-controlled inverter circuit, and a light-gated artificial synapse, underscoring the suitability of this platform for a myriad of biomedical applications that involve light intensity changes., (© 2023. Springer Nature Limited.)

Published

2023

296. Hole-limited electrochemical doping in conjugated polymers.

Author

Keene ST, Laulainen JEM, Pandya R, Moser M, Schnedermann C, Midgley PA, McCulloch I, Rao A, and Malliaras GG

Abstract

Simultaneous transport and coupling of ionic and electronic charges is fundamental to electrochemical devices used in energy storage and conversion, neuromorphic computing and bioelectronics. While the mixed conductors enabling these technologies are widely used, the dynamic relationship between ionic and electronic transport is generally poorly understood, hindering the rational design of new materials. In semiconducting electrodes, electrochemical doping is assumed to be limited by motion of ions due to their large mass compared to electrons and/or holes. Here, we show that this basic assumption does not hold for conjugated polymer electrodes. Using operando optical microscopy, we reveal that electrochemical doping speeds in a state-of-the-art polythiophene can be limited by poor hole transport at low doping levels, leading to substantially slower switching speeds than expected. We show that the timescale of hole-limited doping can be controlled by the degree of microstructural heterogeneity, enabling the design of conjugated polymers with improved electrochemical performance., (© 2023. The Author(s).)

Published

2023

297. New Chemical Dopant and Counterion Mechanism for Organic Electrochemical Transistors and Organic Mixed Ionic-Electronic Conductors.

Author

Le VN, Bombile JH, Rupasinghe GS, Baustert KN, Li R, Maria IP, Shahi M, Alarcon Espejo P, McCulloch I, Graham KR, Risko C, and Paterson AF

Abstract

Organic mixed ionic-electronic conductors (OMIECs) have varied performance requirements across a diverse application space. Chemically doping the OMIEC can be a simple, low-cost approach for adapting performance metrics. However, complex challenges, such as identifying new dopant materials and elucidating design rules, inhibit its realization. Here, these challenges are approached by introducing a new n-dopant, tetrabutylammonium hydroxide (TBA-OH), and identifying a new design consideration underpinning its success. TBA-OH behaves as both a chemical n-dopant and morphology additive in donor acceptor co-polymer naphthodithiophene diimide-based polymer, which serves as an electron transporting material in organic electrochemical transistors (OECTs). The combined effects enhance OECT transconductance, charge carrier mobility, and volumetric capacitance, representative of the key metrics underpinning all OMIEC applications. Additionally, when the TBA + counterion adopts an "edge-on" location relative to the polymer backbone, Coulombic interaction between the counterion and polaron is reduced, and polaron delocalization increases. This is the first time such mechanisms are identified in doped-OECTs and doped-OMIECs. The work herein therefore takes the first steps toward developing the design guidelines needed to realize chemical doping as a generic strategy for tailoring performance metrics in OECTs and OMIECs., (© 2023 The Authors. Advanced Science published by Wiley-VCH GmbH.)

Published

2023

298. Controlling swelling in mixed transport polymers through alkyl side-chain physical cross-linking.

Author

Siemons N, Pearce D, Yu H, Tuladhar SM, LeCroy GS, Sheelamanthula R, Hallani RK, Salleo A, McCulloch I, Giovannitti A, Frost JM, and Nelson J

Abstract

Semiconducting conjugated polymers bearing glycol side chains can simultaneously transport both electronic and ionic charges with high charge mobilities, making them ideal electrode materials for a range of bioelectronic devices. However, heavily glycolated conjugated polymer films have been observed to swell irreversibly when subjected to an electrochemical bias in an aqueous electrolyte. The excessive swelling can lead to the degradation of their microstructure, and subsequently reduced device performance. An effective strategy to control polymer film swelling is to copolymerize glycolated repeat units with a fraction of monomers bearing alkyl side chains, although the microscopic mechanism that constrains swelling is unknown. Here we investigate, experimentally and computationally, a series of archetypal mixed transporting copolymers with varying ratios of glycolated and alkylated repeat units. Experimentally we observe that exchanging 10% of the glycol side chains for alkyl leads to significantly reduced film swelling and an increase in electrochemical stability. Through molecular dynamics simulation of the amorphous phase of the materials, we observe the formation of polymer networks mediated by alkyl side-chain interactions. When in the presence of water, the network becomes increasingly connected, counteracting the volumetric expansion of the polymer film.

Published

2023

299. Vacuum-Deposited Donors for Low-Voltage-Loss Nonfullerene Organic Solar Cells.

Author

Kaienburg P, Bristow H, Jungbluth A, Habib I, McCulloch I, Beljonne D, and Riede M

Abstract

The advent of nonfullerene acceptors (NFAs) enabled records of organic photovoltaics (OPVs) exceeding 19% power conversion efficiency in the laboratory. However, high-efficiency NFAs have so far only been realized in solution-processed blends. Due to its proven track record in upscaled industrial production, vacuum thermal evaporation (VTE) is of prime interest for real-world OPV commercialization. Here, we combine the benchmark solution-processed NFA Y6 with three different evaporated donors in a bilayer (planar heterojunction) architecture. We find that voltage losses decrease by hundreds of millivolts when VTE donors are paired with the NFA instead of the fullerene C 60 , the current standard acceptor in VTE OPVs. By showing that evaporated small-molecule donors behave much like solution-processed donor polymers in terms of voltage loss when combined with NFAs, we highlight the immense potential for evaporable NFAs and the urgent need to direct synthesis efforts toward making smaller, evaporable compounds.

Published

2023

300. Role of aggregates and microstructure of mixed-ionic-electronic-conductors on charge transport in electrochemical transistors.

Author

LeCroy G, Cendra C, Quill TJ, Moser M, Hallani R, Ponder JF Jr, Stone K, Kang SD, Liang AY, Thiburce Q, McCulloch I, Spano FC, Giovannitti A, and Salleo A

Abstract

Synthetic efforts have delivered a library of organic mixed ionic-electronic conductors (OMIECs) with high performance in electrochemical transistors. The most promising materials are redox-active conjugated polymers with hydrophilic side chains that reach high transconductances in aqueous electrolytes due to volumetric electrochemical charging. Current approaches to improve transconductance and device stability focus mostly on materials chemistry including backbone and side chain design. However, other parameters such as the initial microstructure and microstructural rearrangements during electrochemical charging are equally important and are influenced by backbone and side chain chemistry. In this study, we employ a polymer system to investigate the fundamental electrochemical charging mechanisms of OMIECs. We couple in situ electronic charge transport measurements and spectroelectrochemistry with ex situ X-ray scattering electrochemical charging experiments and find that polymer chains planarize during electrochemical charging. Our work shows that the most effective conductivity modulation is related to electrochemical accessibility of well-ordered, interconnected aggregates that host high mobility electronic charge carriers. Electrochemical stress cycling induces microstructural changes, but we find that these aggregates can largely maintain order, providing insights on the structural stability and reversibility of electrochemical charging in these systems. This work shows the importance of material design for creating OMIECs that undergo structural rearrangements to accommodate ions and electronic charge carriers during which percolating networks are formed for efficient electronic charge transport.

Published

2023