Principles of Structural Design of Conjugated Polymers Showing Excellent Charge Transport toward Thermoelectrics and Bioelectronics Applications

Goel, Mahima; Heinrich, C. David; Krauss, Gert; Thelakkat, Mukundan

doi:10.1002/marc.201800915

Cited by 44 publications

(49 citation statements)

References 223 publications

(272 reference statements)

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“…The latter necessitates high electrochemical biases to populate a sufficient number of carriers in the lowest unoccupied molecular orbital (LUMO). However, the electrochemical window of water (<1 V) limits the extent to which CPs can be biased before they suffer from harmful electrochemical side products, restricting the operating range [16,17,21,22] Synthesis of n-types with LUMOs deeper than −4 eV mitigates stability issues in ambient environment, [21,23,24] yet the design of such materials remains extremely challenging.…”

Section: Introductionmentioning

confidence: 99%

Mixed Conduction in an N‐Type Organic Semiconductor in the Absence of Hydrophilic Side‐Chains

Surgailis

Savva

Druet

et al. 2021

Adv Funct Materials

118

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Organic electrochemical transistors (OECTs) are the building blocks of biosensors, neuromorphic devices, and complementary circuits. One rule in the materials design for OECTs is the inclusion of a hydrophilic component in the chemical structure to enable ion transport in the film. Here, it is shown that the ladder-type, side-chain free polymer poly(benzimidazobenzophenanthro line) (BBL) performs significantly better in OECTs than the donor-acceptor type copolymer bearing hydrophilic ethylene glycol side chains (P-90). A combination of electrochemical techniques reveals that BBL exhibits a more efficient ion-to-electron coupling and higher OECT mobility than P-90. In situ atomic force microscopy scans evidence that BBL, which swells negligibly in electrolytes, undergoes a drastic and permanent change in morphology upon electrochemical doping. In contrast, P-90 substantially swells when immersed in electrolytes and shows moderate morphology changes induced by dopant ions. Ex situ grazing incidence wide-angle X-ray scattering suggests that the particular packing of BBL crystallites is minimally affected after doping, in contrast to P-90. BBL's ability to show exceptional mixed transport is due to the crystallites' connectivity, which resists water uptake. This side chain-free route for the design of mixed conductors could bring the n-type OECT performance closer to the bar set by their p-type counterparts.

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Section: Introductionmentioning

confidence: 99%

Mixed Conduction in an N‐Type Organic Semiconductor in the Absence of Hydrophilic Side‐Chains

Surgailis

Savva

Druet

et al. 2021

Adv Funct Materials

118

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“…10 In general, the mixed conductors are attractive materials for several applications, such as thermoelectric devices, electrochromic displays and bioelectronics. 8,9,11,12 The widely studied class of p-type semiconductors for bioelectronics still comprises of polythiophene derivatives, due to their high crystallinity, excellent charge carrier properties, high solubility and the feasibility of a controlled synthesis. The synthesis of substituted polythiophenes is of exceptional character, due to the quasi living polymerization character of the Kumada catalyst transfer polymerization, which was initially developed for poly-3-hexylthiophene (P3HT).…”

Section: Introductionmentioning

confidence: 99%

The Key Role of Side Chain Linkage in Structure Formation and Mixed Conduction of Ethylene Glycol Substituted Polythiophenes

Schmode

Savva

Kahl

et al. 2020

ACS Appl. Mater. Interfaces

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136

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Functionalizing conjugated polymers with polar ethylene glycol side chains enables enhanced swelling and facilitates ion transport in addition to electronic transport in such systems. Here we investigate three polythiophene homopolymers (P3MEET, P3MEEMT and P3MEEET), having differently linked (without, methyl and ethyl spacer, respectively) diethylene glycol side chains. All the polymers were tested in organic electrochemical transistors (OECTs). They show drastic differences in the device performance. The highest µ OECT C* product of 11.5 F/cmVs was obtained for ethyl spaced P3MEEET. How the injection and transport of ions is influenced by the side-chain linkage was studied with electrochemical impedance spectroscopy (EIS), which shows a dramatic increase in volumetric capacitance from 80± 9 up to 242±17 F/cm 3 on going from P3MEET to P3MEEET. Thus, ethyl-spaced P3MEEET exhibits one of the highest reported volumetric capacitance values among p-type polymers. Moreover, P3MEEET exhibits in dry thin films an OFET hole mobility of 0.005 cm 2 /Vs, highest among the three, which is one order of magnitude higher than for P3MEEMT. The extracted hole mobility from OECT (oxidized swollen state) and the hole mobility in solid state thin films (OFET) show contradictory trends for P3MEEMT and P3MEEET. In order to understand exactly the properties in the hydrated and dry states, the crystal structure of the polymers was investigated with WAXS and GIWAXS and the water uptake under applied potential was monitored using E-QCMD. These measurements reveal an amorphous state for P3MEET and a semicrystalline state for P3MEEMT and P3MEEEET. On the other hand, E-QCMD confirms that P3MEEET swells ten times more than P3MEEMT in the oxidized state. Thus, the importance of the ethyl spacer towards crystallinity and mixedconduction properties was clearly demonstrated, emphasizing the impact of side chain-linkage of diethylene glycol. This detailed study offers a better understanding how to design high performance organic mixed conductors.

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“…Conjugated polymers have become ubiquitous in many kinds of electronic applications, such as light emitting diodes, [ 1,2 ] solar cells, [ 3–5 ] field effect transistors, [ 6 ] and thermoelectrics, [ 7–10 ] and naturally they also found their way into the field of organic bioelectronics. [ 11 ] In bioelectronic devices, mixed ion‐electron conductors (MIECs) are required as the active materials to transport both electrical charges and ions.…”

Section: Introductionmentioning

confidence: 99%

Polydiketopyrrolopyrroles Carrying Ethylene Glycol Substituents as Efficient Mixed Ion‐Electron Conductors for Biocompatible Organic Electrochemical Transistors

Thelakkat

Meichsner

Hochgesang

et al. 2021

Adv Funct Materials

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A comprehensive investigation of four polydiketopyrrolopyrroles (PDPPs) with increasing ethylene glycol (EG) content and varying nature of comonomer is presented, and guidelines for the design of efficient mixed ion‐electron conductors (MIECs) are deduced. The studies in NaCl electrolyte‐gated organic electrochemical transistors (OECTs) reveal that a high amount of EG on the DPP moiety is essential for MIEC. The PDPP containing 52 wt% EG exhibits a high volumetric capacitance of 338 F cm−3 (at 0.8 V), a high hole mobility in aqueous medium (0.13 cm2 V−1 s−1), and a μC* product of 45 F cm−1 V−1 s−1. OECTs using this polymer retain 97% of the initial drain‐current after 1200 cycles (90 min of continuous operation). In a cell growth medium, the OECT‐performance is fully maintained as in the NaCl electrolyte. In vitro cytotoxicity and cell viability assays reveal the excellent cell compatibility of these novel systems, showing no toxicity after 24 h of culture. Due to the excellent OECT performance with a considerable cycling stability for 1200 cycles and an outstanding cell compatibility, these PDPPs render themselves viable for in vitro and in vivo bioelectronics.

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Principles of Structural Design of Conjugated Polymers Showing Excellent Charge Transport toward Thermoelectrics and Bioelectronics Applications

Cited by 44 publications

References 223 publications

Mixed Conduction in an N‐Type Organic Semiconductor in the Absence of Hydrophilic Side‐Chains

Mixed Conduction in an N‐Type Organic Semiconductor in the Absence of Hydrophilic Side‐Chains

The Key Role of Side Chain Linkage in Structure Formation and Mixed Conduction of Ethylene Glycol Substituted Polythiophenes

Polydiketopyrrolopyrroles Carrying Ethylene Glycol Substituents as Efficient Mixed Ion‐Electron Conductors for Biocompatible Organic Electrochemical Transistors

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