Charge state-dependent ion condensation near conjugated polymer backbones

Dilara Meli; Quentin Thomas; Nicolas Rolland; Guillaume Freychet; Christina J. Kousseff; Priscila Cavassin; Lucas Q. Flagg; Vincent Lemaur; Abhijith Surendran; Zeinab Hamid; Sophie Griggs; Ruiheng Wu; Rosalba A. Huerta; Isaiah D. Duplessis; Bryan D. Paulsen; Tobin J. Marks; Lincoln J. Lauhon; Iain McCulloch; Lee J. Richter; David Beljonne; Jonathan Rivnay

doi:10.1039/d5mh01939g

Charge state-dependent ion condensation near conjugated polymer backbones

Dilara Meli
, Quentin Thomas
, Nicolas Rolland
, Guillaume Freychet
, Christina J. Kousseff
, Priscila Cavassin
, Lucas Q. Flagg
, Vincent Lemaur
, Abhijith Surendran
, Zeinab Hamid
, Sophie Griggs
, Ruiheng Wu
, Rosalba A. Huerta
, Isaiah D. Duplessis
, Bryan D. Paulsen
, Tobin J. Marks
, Lincoln J. Lauhon
, Iain McCulloch
, Lee J. Richter
, David Beljonne

Jonathan Rivnay

Research output: Contribution to journal › Article › peer-review

Abstract

Despite the technological appeal of polymeric organic mixed ionic/electronic conductors (OMIECs) for diverse applications, a deep understanding of the fundamentals of mixed charge transport in these materials, especially regarding the complex interplay between polymer, ion and solvent structure in determining transport, is lacking. Herein, extensive molecular dynamics (MD) simulations of a model OMIEC representing various electrochemically gated states are reported that reveal charge state-dependent counterion condensation. X-ray diffraction simulations based on the MD data predict a measurable change in the scattering intensity at the counterion absorption edge, indicative of counterion repositioning with charging. We leverage an operando resonant X-ray scattering technique to experimentally corroborate the simulated scattering and report excellent agreement between predicted and experimental data, confirming that counterions preferentially reside in the lamellar mid-plane of crystallites at low doping, and near the polymer backbone at higher doping. Driving forces for ion type-dependent spatial repositioning and implications thereof are discussed.

Original language	English (US)
Journal	Materials Horizons
DOIs	https://doi.org/10.1039/d5mh01939g
State	Accepted/In press - 2025
Externally published	Yes

All Science Journal Classification (ASJC) codes

General Materials Science
Mechanics of Materials
Process Chemistry and Technology
Electrical and Electronic Engineering

Access to Document

10.1039/d5mh01939g

Cite this

Meli, D., Thomas, Q., Rolland, N., Freychet, G., Kousseff, C. J., Cavassin, P., Flagg, L. Q., Lemaur, V., Surendran, A., Hamid, Z., Griggs, S., Wu, R., Huerta, R. A., Duplessis, I. D., Paulsen, B. D., Marks, T. J., Lauhon, L. J., McCulloch, I., Richter, L. J., ... Rivnay, J. (Accepted/In press). Charge state-dependent ion condensation near conjugated polymer backbones. Materials Horizons. https://doi.org/10.1039/d5mh01939g

@article{af26cc7ac72b49c5b0e876258d941c4c,

title = "Charge state-dependent ion condensation near conjugated polymer backbones",

abstract = "Despite the technological appeal of polymeric organic mixed ionic/electronic conductors (OMIECs) for diverse applications, a deep understanding of the fundamentals of mixed charge transport in these materials, especially regarding the complex interplay between polymer, ion and solvent structure in determining transport, is lacking. Herein, extensive molecular dynamics (MD) simulations of a model OMIEC representing various electrochemically gated states are reported that reveal charge state-dependent counterion condensation. X-ray diffraction simulations based on the MD data predict a measurable change in the scattering intensity at the counterion absorption edge, indicative of counterion repositioning with charging. We leverage an operando resonant X-ray scattering technique to experimentally corroborate the simulated scattering and report excellent agreement between predicted and experimental data, confirming that counterions preferentially reside in the lamellar mid-plane of crystallites at low doping, and near the polymer backbone at higher doping. Driving forces for ion type-dependent spatial repositioning and implications thereof are discussed.",

author = "Dilara Meli and Quentin Thomas and Nicolas Rolland and Guillaume Freychet and Kousseff, \{Christina J.\} and Priscila Cavassin and Flagg, \{Lucas Q.\} and Vincent Lemaur and Abhijith Surendran and Zeinab Hamid and Sophie Griggs and Ruiheng Wu and Huerta, \{Rosalba A.\} and Duplessis, \{Isaiah D.\} and Paulsen, \{Bryan D.\} and Marks, \{Tobin J.\} and Lauhon, \{Lincoln J.\} and Iain McCulloch and Richter, \{Lee J.\} and David Beljonne and Jonathan Rivnay",

note = "Publisher Copyright: This journal is {\textcopyright} The Royal Society of Chemistry",

year = "2025",

doi = "10.1039/d5mh01939g",

language = "English (US)",

journal = "Materials Horizons",

issn = "2051-6347",

publisher = "Royal Society of Chemistry",

}

Meli, D, Thomas, Q, Rolland, N, Freychet, G, Kousseff, CJ, Cavassin, P, Flagg, LQ, Lemaur, V, Surendran, A, Hamid, Z, Griggs, S, Wu, R, Huerta, RA, Duplessis, ID, Paulsen, BD, Marks, TJ, Lauhon, LJ, McCulloch, I, Richter, LJ, Beljonne, D & Rivnay, J 2025, 'Charge state-dependent ion condensation near conjugated polymer backbones', Materials Horizons. https://doi.org/10.1039/d5mh01939g

TY - JOUR

T1 - Charge state-dependent ion condensation near conjugated polymer backbones

AU - Meli, Dilara

AU - Thomas, Quentin

AU - Rolland, Nicolas

AU - Freychet, Guillaume

AU - Kousseff, Christina J.

AU - Cavassin, Priscila

AU - Flagg, Lucas Q.

AU - Lemaur, Vincent

AU - Surendran, Abhijith

AU - Hamid, Zeinab

AU - Griggs, Sophie

AU - Wu, Ruiheng

AU - Huerta, Rosalba A.

AU - Duplessis, Isaiah D.

AU - Paulsen, Bryan D.

AU - Marks, Tobin J.

AU - Lauhon, Lincoln J.

AU - McCulloch, Iain

AU - Richter, Lee J.

AU - Beljonne, David

AU - Rivnay, Jonathan

PY - 2025

Y1 - 2025

N2 - Despite the technological appeal of polymeric organic mixed ionic/electronic conductors (OMIECs) for diverse applications, a deep understanding of the fundamentals of mixed charge transport in these materials, especially regarding the complex interplay between polymer, ion and solvent structure in determining transport, is lacking. Herein, extensive molecular dynamics (MD) simulations of a model OMIEC representing various electrochemically gated states are reported that reveal charge state-dependent counterion condensation. X-ray diffraction simulations based on the MD data predict a measurable change in the scattering intensity at the counterion absorption edge, indicative of counterion repositioning with charging. We leverage an operando resonant X-ray scattering technique to experimentally corroborate the simulated scattering and report excellent agreement between predicted and experimental data, confirming that counterions preferentially reside in the lamellar mid-plane of crystallites at low doping, and near the polymer backbone at higher doping. Driving forces for ion type-dependent spatial repositioning and implications thereof are discussed.

AB - Despite the technological appeal of polymeric organic mixed ionic/electronic conductors (OMIECs) for diverse applications, a deep understanding of the fundamentals of mixed charge transport in these materials, especially regarding the complex interplay between polymer, ion and solvent structure in determining transport, is lacking. Herein, extensive molecular dynamics (MD) simulations of a model OMIEC representing various electrochemically gated states are reported that reveal charge state-dependent counterion condensation. X-ray diffraction simulations based on the MD data predict a measurable change in the scattering intensity at the counterion absorption edge, indicative of counterion repositioning with charging. We leverage an operando resonant X-ray scattering technique to experimentally corroborate the simulated scattering and report excellent agreement between predicted and experimental data, confirming that counterions preferentially reside in the lamellar mid-plane of crystallites at low doping, and near the polymer backbone at higher doping. Driving forces for ion type-dependent spatial repositioning and implications thereof are discussed.

UR - https://www.scopus.com/pages/publications/105022896897

UR - https://www.scopus.com/pages/publications/105022896897#tab=citedBy

U2 - 10.1039/d5mh01939g

DO - 10.1039/d5mh01939g

M3 - Article

C2 - 41295917

AN - SCOPUS:105022896897

SN - 2051-6347

JO - Materials Horizons

JF - Materials Horizons

ER -

Charge state-dependent ion condensation near conjugated polymer backbones

Abstract

All Science Journal Classification (ASJC) codes

Access to Document

Other files and links

Fingerprint

Cite this