Charge transport in high-mobility conjugated polymers and molecular semiconductors

Fratini, Simone; Nikolka, Mark; Salleo, Alberto; Schweicher, Guillaume; Sirringhaus, Henning

doi:10.1038/s41563-020-0647-2

Cited by 538 publications

(571 citation statements)

References 118 publications

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“…At the heart of OECTs working principle is the active material, which is usually a π-conjugated polymer or polymer blend able to host or be chemically linked to charged groups. 10 The greatest challenges of developing organic mixed ionic-electronic conductors (OMIECs) is the need to optimize the seemingly contrasting processes of electronic and ionic charge transport: while the factors governing electronic charge transport in conjugated polymers is now fairly well understood, [11][12][13] little is known about how the presence of water and ions affects both the microstructure of the materials and its transport characteristics. On the other hand, although ion transport has been extensively studied in the context of capacitors and batteries, where it is one of the main governing processes, a systematic understanding of ion percolation in OMIECs is still in its infancy and limited to a few widespread materials.…”

Section: Introductionmentioning

confidence: 99%

Ion Coordination and Chelation in a Glycolated Polymer Semiconductor: Molecular Dynamics and X-ray Fluorescence Study

Matta

Wu²,

Paulsen³

et al. 2020

Chem. Mater.

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Section: Introductionmentioning

confidence: 99%

Ion Coordination and Chelation in a Glycolated Polymer Semiconductor: Molecular Dynamics and X-ray Fluorescence Study

Matta

Wu²,

Paulsen³

et al. 2020

Chem. Mater.

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“…It is now well established that the weak molecular interactions between the molecules of OSs give rise to slow intermolecular vibrations [6][7][8] that strongly impact charge carrier mobility and device performance. This (dynamical) disorder also places charge transport in a difficult regime where the relevant transport parameters (electronic coupling, reorganization energy, site energy and electronic coupling fluctuations, and thermal energy) are all on the same energy scale, typically 10-200 meV.…”

mentioning

confidence: 99%

“…The theory was successfully used to show that charge transport in the high mobility planes of typical singlecrystalline OSs is enhanced if electronic couplings between the molecules within the plane are isotropic and are of specific sign combinations. [7,26,27] TLT has also recently been connected to the standard band transport description in the case of small disorder. [28] Yet, we note that TLT does not give information on how the charge carrier moves across the material in real time due to the assumptions of this theory with regards to the dynamics.…”

mentioning

confidence: 99%

Flickering Polarons Extending over Ten Nanometres Mediate Charge Transport in High‐Mobility Organic Crystals

Giannini

Ziogos

Carof

et al. 2020

Advcd Theory and Sims

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Progress in the design of high‐mobility organic semiconductors has been hampered by an incomplete fundamental understanding of the elusive charge carrier dynamics mediating electrical current in these materials. To address this problem, a novel fully atomistic non‐adiabatic molecular dynamics approach termed fragment orbital‐based surface hopping (FOB‐SH) that propagates the electron‐nuclear motion has been further improved and, for the first time, used to calculate the full 2D charge mobility tensor for the conductive planes of six structurally well characterized organic single crystals, in good agreement with available experimental data. The nature of the charge carrier in these materials is best described as a flickering polaron constantly changing shape and extensions under the influence of thermal disorder. Thermal intra‐band excitations from modestly delocalized band edge states (up to 5 nm or 10–20 molecules) to highly delocalized tail states (up to 10 nm or 40–60 molecules in the most conductive materials) give rise to short, ≈ 10 fs‐long bursts of the charge carrier wavefunction that drives the spatial displacement of the polaron, resulting in carrier diffusion and mobility. This study implies that key to the design of high‐mobility materials is a high density of strongly delocalized and thermally accessible tail states.

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“…[45,56] The localization of charges limits the electronic conductivity of polymers, typically giving rise to traps in the presence of high disorder or in the absence of connectivity between the segments within the complex polymer microstructure. [56] A semiconducting polymer can become conducting (i.e., charged or doped) i) chemically, by exposing the polymer to a reducing or oxidizing solution that contains dopant acceptor or donor molecules, or ii) upon application of an electric field to the film interfacing an electrolyte that contains ionic species which electrostatically compensate for the electronic charges that are injected from a metal contact. [45,57] For bioelectronic devices where the CP film has an interface with an electrolyte, the latter summarizes the operation principle.…”

Section: Ionic-to-electronic Charge Coupling In Cpsmentioning

confidence: 99%

Organic Bioelectronics: From Functional Materials to Next‐Generation Devices and Power Sources

2020

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Conjugated polymers (CPs) possess a unique set of features setting them apart from other materials. These properties make them ideal when interfacing the biological world electronically. Their mixed electronic and ionic conductivity can be used to detect weak biological signals, deliver charged bioactive molecules, and mechanically or electrically stimulate tissues. CPs can be functionalized with various (bio)chemical moieties and blend with other functional materials, with the aim of modulating biological responses or endow specificity toward analytes of interest. They can absorb photons and generate electronic charges that are then used to stimulate cells or produce fuels. These polymers also have catalytic properties allowing them to harvest ambient energy and, along with their high capacitances, are promising materials for next‐generation power sources integrated with bioelectronic devices. In this perspective, an overview of the key properties of CPs and examination of operational mechanism of electronic devices that leverage these properties for specific applications in bioelectronics is provided. In addition to discussing the chemical structure–functionality relationships of CPs applied at the biological interface, the development of new chemistries and form factors that would bring forth next‐generation sensors, actuators, and their power sources, and, hence, advances in the field of organic bioelectronics is described.

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Charge transport in high-mobility conjugated polymers and molecular semiconductors

Cited by 538 publications

References 118 publications

Ion Coordination and Chelation in a Glycolated Polymer Semiconductor: Molecular Dynamics and X-ray Fluorescence Study

Ion Coordination and Chelation in a Glycolated Polymer Semiconductor: Molecular Dynamics and X-ray Fluorescence Study

Flickering Polarons Extending over Ten Nanometres Mediate Charge Transport in High‐Mobility Organic Crystals

Organic Bioelectronics: From Functional Materials to Next‐Generation Devices and Power Sources

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