A Solid State Zwitterionic Plastic Crystal With High Static Dielectric Constant

Zitan Huang; Yifan Liu; Tiago Outerelo Corvo; Ain Uddin; Michelle L. Lehmann; Tomonori Saito; Valentino R. Cooper; Ralph H. Colby

doi:10.1002/adma.202517774

A Solid State Zwitterionic Plastic Crystal With High Static Dielectric Constant

Zitan Huang
, Yifan Liu
, Tiago Outerelo Corvo
, Ain Uddin
, Michelle L. Lehmann
, Tomonori Saito
, Valentino R. Cooper
, Ralph H. Colby

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

Abstract

Solid materials with a high dielectric constant have a wide range of applications in the energy storage field. In this research, an imidazolium-based zwitterion is designed, synthesized, and confirmed to have a plastic crystal phase based on the following experimental and computational evidence: (i) the presence of long-range order with weak intermolecular forces and competing attractive-repulsive interactions along different crystallographic directions; (ii) the observation of more than one endotherm on heating including a solid-solid phase transition at T_s-s = −26 °C and melting of the plastic crystal at T_m = 72°C; (iii) a low entropy of fusion at melting (2.1 JK⁻¹mol⁻¹); (iv) a strongly anisotropic morphology; (v) relatively fast dynamics originating from short-range degrees of freedom. Furthermore, it exhibits a very high dielectric constant in the plastic crystal solid state (147 at −10°C and 103 at 70°C) due to the rotational degrees of freedom of plastic crystals that arise from weak net intermolecular interactions of zwitterions due to only having two carbons between the anion and cation. This material conveniently remains in the plastic crystal phase within 50 K of ambient temperature. This discovery opens new opportunities in the search for solid-state high dielectric constant materials.

Original language	English
Journal	Advanced Materials
DOIs	https://doi.org/10.1002/adma.202517774
State	Accepted/In press - 2026

Funding

This work was supported as part of Fast and Cooperative Ion Transport in Polymer‐Based Materials (FaCT), an Energy Frontier Research Center funded by the US. Department of Energy (DOE), Office of Science, Office of Basic Energy Sciences. This research used resources of the National Energy Research Scientific Computing Center (NERSC), a Department of Energy Office of Science User Facility, using NERSC award BES‐ERCAPm4305. Research reported here was partially supported by Shared Instrument Grant (S10) of the National Institutes of Health under award numbers 1S10OD028589‐01 and 1S10RR023439‐01 for the X‐ray instrumentation.

Keywords

dielectric relaxation
long-range order
rotational degree of freedom

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10.1002/adma.202517774

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title = "A Solid State Zwitterionic Plastic Crystal With High Static Dielectric Constant",

abstract = "Solid materials with a high dielectric constant have a wide range of applications in the energy storage field. In this research, an imidazolium-based zwitterion is designed, synthesized, and confirmed to have a plastic crystal phase based on the following experimental and computational evidence: (i) the presence of long-range order with weak intermolecular forces and competing attractive-repulsive interactions along different crystallographic directions; (ii) the observation of more than one endotherm on heating including a solid-solid phase transition at Ts-s = −26 °C and melting of the plastic crystal at Tm = 72°C; (iii) a low entropy of fusion at melting (2.1 JK−1mol−1); (iv) a strongly anisotropic morphology; (v) relatively fast dynamics originating from short-range degrees of freedom. Furthermore, it exhibits a very high dielectric constant in the plastic crystal solid state (147 at −10°C and 103 at 70°C) due to the rotational degrees of freedom of plastic crystals that arise from weak net intermolecular interactions of zwitterions due to only having two carbons between the anion and cation. This material conveniently remains in the plastic crystal phase within 50 K of ambient temperature. This discovery opens new opportunities in the search for solid-state high dielectric constant materials.",

keywords = "dielectric relaxation, long-range order, rotational degree of freedom",

author = "Zitan Huang and Yifan Liu and Corvo, \{Tiago Outerelo\} and Ain Uddin and Lehmann, \{Michelle L.\} and Tomonori Saito and Cooper, \{Valentino R.\} and Colby, \{Ralph H.\}",

note = "Publisher Copyright: {\textcopyright} 2026 The Author(s). Advanced Materials published by Wiley-VCH GmbH.",

year = "2026",

doi = "10.1002/adma.202517774",

language = "English",

journal = "Advanced Materials",

issn = "0935-9648",

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TY - JOUR

T1 - A Solid State Zwitterionic Plastic Crystal With High Static Dielectric Constant

AU - Huang, Zitan

AU - Liu, Yifan

AU - Corvo, Tiago Outerelo

AU - Uddin, Ain

AU - Lehmann, Michelle L.

AU - Saito, Tomonori

AU - Cooper, Valentino R.

AU - Colby, Ralph H.

PY - 2026

Y1 - 2026

N2 - Solid materials with a high dielectric constant have a wide range of applications in the energy storage field. In this research, an imidazolium-based zwitterion is designed, synthesized, and confirmed to have a plastic crystal phase based on the following experimental and computational evidence: (i) the presence of long-range order with weak intermolecular forces and competing attractive-repulsive interactions along different crystallographic directions; (ii) the observation of more than one endotherm on heating including a solid-solid phase transition at Ts-s = −26 °C and melting of the plastic crystal at Tm = 72°C; (iii) a low entropy of fusion at melting (2.1 JK−1mol−1); (iv) a strongly anisotropic morphology; (v) relatively fast dynamics originating from short-range degrees of freedom. Furthermore, it exhibits a very high dielectric constant in the plastic crystal solid state (147 at −10°C and 103 at 70°C) due to the rotational degrees of freedom of plastic crystals that arise from weak net intermolecular interactions of zwitterions due to only having two carbons between the anion and cation. This material conveniently remains in the plastic crystal phase within 50 K of ambient temperature. This discovery opens new opportunities in the search for solid-state high dielectric constant materials.

AB - Solid materials with a high dielectric constant have a wide range of applications in the energy storage field. In this research, an imidazolium-based zwitterion is designed, synthesized, and confirmed to have a plastic crystal phase based on the following experimental and computational evidence: (i) the presence of long-range order with weak intermolecular forces and competing attractive-repulsive interactions along different crystallographic directions; (ii) the observation of more than one endotherm on heating including a solid-solid phase transition at Ts-s = −26 °C and melting of the plastic crystal at Tm = 72°C; (iii) a low entropy of fusion at melting (2.1 JK−1mol−1); (iv) a strongly anisotropic morphology; (v) relatively fast dynamics originating from short-range degrees of freedom. Furthermore, it exhibits a very high dielectric constant in the plastic crystal solid state (147 at −10°C and 103 at 70°C) due to the rotational degrees of freedom of plastic crystals that arise from weak net intermolecular interactions of zwitterions due to only having two carbons between the anion and cation. This material conveniently remains in the plastic crystal phase within 50 K of ambient temperature. This discovery opens new opportunities in the search for solid-state high dielectric constant materials.

KW - dielectric relaxation

KW - long-range order

KW - rotational degree of freedom

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U2 - 10.1002/adma.202517774

DO - 10.1002/adma.202517774

M3 - Article

AN - SCOPUS:105027644974

SN - 0935-9648

JO - Advanced Materials

JF - Advanced Materials

ER -

A Solid State Zwitterionic Plastic Crystal With High Static Dielectric Constant

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