Counterion Control and the Spectral Signatures of Polarons, Coupled Polarons, and Bipolarons in Doped P3HT Films

Wu, E. S. C.; Salamat, Charlene Z.; Ruiz, Omar León; Qu, Thomas Xutong; Kim, Alexis; Tolbert, Sarah H.; Schwartz, Benjamin J.

doi:10.1002/adfm.202213652

Cited by 16 publications

(40 citation statements)

References 64 publications

(164 reference statements)

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“…In Figure , we present spectroelectrochemistry and GIWAXS measurements for 25:75, 50:50, and 75:25 RR/RRa P3HT blends. The steady-state spectroelectrochemistry measurements exhibit a decrease in the height of the π–π* absorption peak and the appearance and subsequent increase in the height of the polaron absorption peak as the voltage increases . For each blend, the red side of the π–π* peak decreases before the blue side of the π–π* peak, indicating that polarons form in the more crystalline, smaller band gap regions of the film before forming in the more amorphous, larger band gap regions of the film (Figure A).…”

Section: Resultsmentioning

confidence: 94%

“…The steady-state spectroelectrochemistry measurements exhibit a decrease in the height of the π−π* absorption peak and the appearance and subsequent increase in the height of the polaron absorption peak as the voltage increases. 46 For each blend, the red side of the π−π* peak decreases before the blue side of the π−π* peak, indicating that polarons form in the more crystalline, smaller band gap regions of the film before forming in the more amorphous, larger band gap regions of the film (Figure 2A). If there were no shift observed for the π−π* peak, we would hypothesize that the dopants enter the crystalline and amorphous regions simultaneously, but that is not the case with the P3HT blends.…”

Section: ■ Results and Discussionmentioning

confidence: 96%

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Crystallinity Determines Ion Injection Kinetics and Local Ion Density in Organic Mixed Conductors

et al. 2023

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Conjugated polymer organic mixed ionic–electronic conductors (OMIECs) consist of a complex arrangement of crystalline and amorphous regions at the nanoscale. The arrangement of ions in this heterogeneous environment upon electrochemical doping influences the performance of devices that leverage mixed conductivity. This study investigates how varying the ratio of amorphous and crystalline content affects the distribution of ions in blends of regiorandom (RRa) and regioregular (RR) poly(3-hexylthiophene) (P3HT). By correlating changes in the polymer lattice spacing upon ion uptake with spectroelectrochemistry measurements of polaron formation, we find that ions enter the crystalline regions of the polymer first. Using nanoscale infrared imaging with photoinduced force microscopy (PiFM) of the infrared-active PF6 – ions, we map the location of ions at the nanoscale and show that ions cluster in crystalline regions of P3HT thin films. We correlate the infrared images of ion locations with visible PiFM (785 nm) to map the presence of polarons in the film and find that the locations of ions and polarons are correlated. This study also reveals that balancing the distribution of amorphous and crystalline regions can enhance ion injection kinetics. These results underline the importance of controlling the nanoscale morphology of conjugated polymers for high-performing OMIECs.

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Section: Resultsmentioning

confidence: 94%

Section: ■ Results and Discussionmentioning

confidence: 96%

Crystallinity Determines Ion Injection Kinetics and Local Ion Density in Organic Mixed Conductors

et al. 2023

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“…43−45 For bipolaronic P3HT, point-charge counterions were placed on opposite sides of the center of the chain at a distance of 5 Å, as required for bipolarons to be bound in this system. 21 For geometry optimization with point charge(s), the terminal hydrogen atoms at the ends of the chain and one carbon atom at the middle of the chain (one of the carbon atoms that bridges monomer 5 and monomer 6) are fixed during geometry optimization. By fixing the positions of these three atoms, all the bonds are still able to fully relax, which was checked via frequency calculations.…”

Section: Resultsmentioning

confidence: 99%

“…The precise chain and counterion geometries are the same as those explored in our previous work. 21 To benchmark our use of TD-DFT as a quantum chemistry method to determine the electronic structure of doped conjugated polymers, in Figure 1 we compare the calculated and experimental absorption spectra of neutral and (bi)polaronic P3HT. As expected for any DFT-based method, 47−49 the calculated spectra are slightly blue-shifted from experiment, but remarkably, the two sets of spectra are quite similar.…”

Section: Resultsmentioning

confidence: 99%

“…Indeed, we recently argued that the new peaks that appear to the red of P1 at high doping concentrations should be assigned to coupled polarons and not to bipolarons. 21 Despite the fact that basic observations of the P1, P2, and BP1 transitions seem to fit well with the traditional band picture, several groups have argued on the basis of quantum chemistry calculations that borrowing the traditional band picture of conjugated polymer doping from inorganic semiconductors is incorrect. 25−31 These groups used density-functional theory (DFT)-based calculations, and upon examination of the density of states of the Kohn−Sham orbitals yielded by such calculations, concluded that polaron creation causes only one unoccupied state to move into the band gap and that states in the conduction and valence bands associated with the unpaired electron bend downward in energy.…”

Section: Introductionmentioning

confidence: 99%

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Does the Traditional Band Picture Describe the Electronic Structure of Doped Conjugated Polymers? TD-DFT and Natural Transition Orbital Study of Doped P3HT

Wu,

Schwartz

2023

J. Chem. Theory Comput.

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Polarons and bipolarons are created when one or two electrons are removed from the π-system of a p-type conjugated polymer, respectively. In the traditional band picture, the creation of a polaron causes two electronic energy levels to move into the band gap. The removal of a second electron to form a bipolaron causes the two intragap states to move further into the gap. Several groups, however, who looked at the energies of the Kohn−Sham orbitals from DFT calculations, have recently argued that the traditional band picture is incorrect for explaining the spectroscopy of doped conjugated polymers. Instead, the DFT calculations suggest that polaron creation causes only one unoccupied state to move into the band gap near the valence band edge while half-filled state in the valence band and the conduction band bend downward in energy. To understand the discrepancy, we performed TD-DFT calculations of polarons and bipolarons on poly(3-hexylthiophene) (P3HT). Not only do the TD-DFT-calculated absorption spectra match the experimental absorption spectra, but an analysis using natural transitional orbitals (NTOs), which provides an approximate one-electron picture from the many-electron TD-DFT results, supports the traditional band picture. Our TD-DFT/ NTO analysis indicates that the traditional band picture also works for bipolarons, a system for which DFT calculations were unable to determine the electronic structure.

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

Quill,

LeCroy,

Marks

et al. 2024

Advanced Materials

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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, we investigate both the operation and stability of a p‐type OMIEC material of various molecular weights. 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, we observe an increase in device hysteresis and a decrease in conductivity due to a drop in the hole mobility arising from long‐range microstructural disruptions. By employing operando X‐ray scattering techniques, we find two regimes of polaron‐induced structural changes: 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.This article is protected by copyright. All rights reserved

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Counterion Control and the Spectral Signatures of Polarons, Coupled Polarons, and Bipolarons in Doped P3HT Films

Cited by 16 publications

References 64 publications

Crystallinity Determines Ion Injection Kinetics and Local Ion Density in Organic Mixed Conductors

Crystallinity Determines Ion Injection Kinetics and Local Ion Density in Organic Mixed Conductors

Does the Traditional Band Picture Describe the Electronic Structure of Doped Conjugated Polymers? TD-DFT and Natural Transition Orbital Study of Doped P3HT

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

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