Grain Size Control Toward Room-Temperature Operable Solid Polymer Electrolytes

Yanrui Pan; Zhaokun Wang; Chen Li; Zuohang Li; Yue Ma; Mingfu Ye; Xixi Shi; Hongzhou Zhang; Dawei Song; Lianqi Zhang

doi:10.1002/cnl2.70085

Carbon Neutralization ›› 2026, Vol. 5 ›› Issue (1) :e70085 DOI: 10.1002/cnl2.70085

RESEARCH ARTICLE

Grain Size Control Toward Room-Temperature Operable Solid Polymer Electrolytes

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Abstract

The practical application of solid polymer electrolytes (SPE) is limited due to notorious high crystallinity and low ionic conductivity. Existing research concentrated on reducing crystallinity and increasing Li salt concentration have made certain process. However, the segmentation and isolation effects of large and numerous grains on amorphous region have always been overlooked and the effect of grain size remains largely unexplored. Herein, take polyethylene oxide (PEO) as an example, “grain size refinement” strategy is adopted to improve the related room-temperature ionic conductivity by simply placing PEO based SPE on Li sheets coated with ester monomers and conducting in-situ polymerization. During these processes, in addition to reducing the interaction force between polymer chains and decreasing the driving force for crystallization, ester monomers are conducive to form interface with polymer clusters, which serves as additional nucleation sites and promotes the formation of refined grains. Then instantaneous high-temperature provided by muffle furnace triggers rapid solidification of monomers, leading to the locking of refined grain structure and the formation of more interconnected amorphous regions. Time-of-flight secondary ion mass spectrometry and polarization microscope confirm these processes, while small-angle X-ray scattering results indicate that the grain size reduces to one-third of its original size. Then the room-temperature conductivity increased by at least two orders of magnitude for PEO-based SPE.

Keywords

grain refinement / polyethylene oxide / rapid Li ion transfer / solid polymer electrolyte

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Yanrui Pan, Zhaokun Wang, Chen Li, Zuohang Li, Yue Ma, Mingfu Ye, Xixi Shi, Hongzhou Zhang, Dawei Song, Lianqi Zhang. Grain Size Control Toward Room-Temperature Operable Solid Polymer Electrolytes. Carbon Neutralization, 2026, 5(1): e70085 DOI:10.1002/cnl2.70085

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References

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[1]	H. Xu, D. Zhang, W. Wang, G. Yu, M. Zhu, and Y. Liu, “Interfacial Storage for Next-Generation Batteries: Mechanisms, Advances, and Challenges,” Carbon Neutralization 4 (2025): e70031.

[2]	Y. Zhang, J. Yu, H. Shi, et al., “Fiber-Reinforced Ultrathin Solid Polymer Electrolyte for Solid-State Lithium-Metal Batteries,” Advanced Functional Materials 35 (2025): 2421054.

[3]	C. Li, Y. Zhong, R. Liao, et al., “Robust and Antioxidative Quasi-Solid-State Polymer Electrolytes for Long-Cycling 4.6 V Lithium Metal Batteries,” Advanced Materials 37 (2025): e2500142.

[4]	S. Zou, Y. Yang, J. Wang, et al., “In Situ Polymerization of Solid-State Polymer Electrolytes for Lithium Metal Batteries: A Review,” Energy & Environmental Science 17 (2024): 4426–4460.

[5]	M. S. Tu, Z. H. Wang, Q. H. Chen, Z. P. Guo, F. F. Cao, and H. Ye, “Li-Ion Nanorobots With Enhanced Mobility for Fast-Ion Conducting Polymer Electrolytes,” Energy & Environmental Science 18 (2025): 2873–2882.

[6]	D. Hu, H. Huang, C. Wang, et al., “Tailoring Multiple Interactions in Poly (Urethane-Urea)-Based Solid-State Polymer Electrolytes for Long-Term Cycling Lithium Metal Batteries,” Advanced Energy Materials 15 (2025): 2406176.

[7]	Y. Wang, T. Fang, C. Wang, et al., “Oxygen Vacancy-Li₂ZrO₃: A New Choice for Boosting Homogenous Distribution and Transport of Lithium Ion in Composite Solid-State Electrolytes,” Advanced Materials 37 (2025): e2505209.

[8]	C. D. Fang, Y. Huang, Y. F. Sun, et al., “Revealing and Reconstructing The 3D Li-Ion Transportation Network for Superionic Poly(Ethylene) Oxide Conductor,” Nature Communications 15 (2024): 6781.

[9]

J. F. Wang, M. Weiling, F. Pfeiffer, K. L. Liu, and M. Baghernejad, “Molecular Insights Into the Interfacial Phenomena at the Li Metal-Polymer Solid-State Electrolyte in Anode-Free Configuration During Li Plating-Stripping via Advanced Operando ATR-FTIR Spectroscopy,” Advanced Energy Materials 15 (2024): 2404569.

[10]	Y. Fan, O. I. Malyi, H. Wang, et al., “Surface-Confined Disordered Hydrogen Bonds Enable Efficient Lithium Transport in All-Solid-State PEO-Based Lithium Battery,” Angewandte Chemie International Edition 64 (2025): e202421777.

[11]	Y. Song, S. Xue, Z. Xu, et al., “1D ZrCl₄ Matrices for Enhanced Ion Transport in Glassy Chloride Electrolytes,” Advanced Energy Materials 15 (2025): 2500913.

[12]	Y. Ren, S. Chen, M. Odziomek, et al., “Mixing Functionality in Polymer Electrolytes: A New Horizon for Achieving High-Performance All-Solid-State Lithium Metal Batteries,” Angewandte Chemie International Edition 64 (2025): e202422169.

[13]	X. Chen, Z. Wang, M. Si, et al., “Reinforced Anti-Oxidative Degradation and Interface Stabilization in Bimetal Oxide Filler-Based PEO Electrolytes for Lithium Metal Batteries,” Advanced Functional Materials 35 (2025): 2504306.

[14]	Y. You, D. Zhang, Z. Wu, et al., “Grain Boundary Amorphization as A Strategy to Mitigate Lithium Dendrite Growth in Solid-State Batteries,” Nature Communications 16 (2025): 4630.

[15]	J. Deng, W. Li, R. Zeng, et al., “Acceptor Crystallinity Engineering Enables > 20% Efficiency Binary Organic Solar Cells With 83.0% Fill Factor,” Advanced Materials 37 (2025): e2501243.

[16]	A. K. Ahmed, M. Atiqullah, D. R. Pradhan, and M. A. Al-Harthi, “Crystallization and Melting Behavior of I-PP: A Perspective From Flory's Thermodynamic Equilibrium Theory and Dsc Experiment,” RSC Advances 7 (2017): 42491–42504.

[17]	M. Wang, Z. Song, G. Liu, and D. Wang, “Entropic Origin of Polymer Nucleation at Amorphous Solid Interfaces,” Physical Review Letters 135 (2025): 018101.

[18]	J. Deng, X. Huang, Y. Che, et al., “Salt-Based Catalyzer to Aid Heterogeneous Nucleation Enabling > 23% Efficient Electron-Transport-Layer-Free Perovskite Solar Cells,” Advanced Functional Materials 34 (2024): 202408392.

[19]	J. Zheng, S. Liu, H. Huang, et al., “Heterocyclic Polymer Supported Cathode/Li Interface Layers to Lower the Operational Temperature of Peo-Based Li-Batteries,” Nano Energy 118 (2023): 108975.

[20]	Y. Jin, R. Lin, Y. Li, et al., “Revealing the Influence of Electron Migration Inside Polymer Electrolyte on Li⁺ Transport and Interphase Reconfiguration for Li Metal Batteries,” Angewandte Chemie International Edition 63 (2024): e202403661.

[21]	T. Xu, S. Huang, Y. Min, and Q. Xu, “Gelatin Network Reinforced Poly (Vinylene Carbonate-Acrylonitrile) Based Composite Solid Electrolyte for All-Solid-State Lithium Metal Batteries,” Chemical Engineering Journal 475 (2023): 146409.

[22]	Z. Li, X.-Y. Zhou, and X. Guo, “High-Performance Lithium Metal Batteries With Ultraconformal Interfacial Contacts of Quasi-Solid Electrolyte to Electrodes,” Energy Storage Materials 29 (2020): 149–155.

[23]	L. Fan, Z. Dang, C.-W. Nan, and M. Li, “Thermal, Electrical and Mechanical Properties of Plasticized Polymer Electrolytes Based on PEO/P(VDF-HFP) Blends,” Electrochimica Acta 48 (2002): 205–209.

[24]	Y. Yang, S. Biswas, R. Xu, et al., “Capacity Recovery by Transient Voltage Pulse in Silicon-Anode Batteries,” Science 386 (2024): 322–327.

[25]	S. Li, M. Li, X. Chi, X. Yin, Z. Luo, and J. Yu, “High-Stable Aqueous Zinc Metal Anodes Enabled by an Oriented ZnQ Zeolite Protective Layer With Facile Ion Migration Kinetics,” Acta Physico-Chimica Sinica 41 (2025): 100003.

[26]	X. Chi, M. Li, X. Chen, et al., “Enabling High-Performance All-Solid-State Batteries via Guest Wrench in Zeolite Strategy,” Journal of the American Chemical Society 145 (2023): 24116–24125.

[27]	N. Ding, S. W. Chien, T. L. D. Tam, et al., “Revealing Phase Transitions in Poly(Ethylene Oxide)-Based Electrolyte for Room-Temperature Solid-State Batteries,” Advanced Energy Materials 14 (2024): 202402986.

[28]	R. Li, H. Hua, X. Yang, et al., “The Deconstruction of A Polymeric Solvation Cage: A Critical Promotion Strategy for Peo-Based All-Solid Polymer Electrolytes,” Energy & Environmental Science 17 (2024): 5601–5612.

[29]	S. Dong, Y. Zheng, Q. Duan, et al., “Surface-Modified Batio₃ as A Functional Filler in Poly(Ethylene Oxide)-Based Solid Polymer Electrolytes for Lithium-Metal Batteries,” Journal of Materials Chemistry A 13 (2025): 9453–9461.

[30]	Y. Zhang, L. Zou, C. Wan, et al., “Study on the Regulation Mechanism of A Coral-Like Li₇La₃Zr₂O₁₂ Inorganic Filler on the Properties of Poly(Ethylene Oxide)-Based Composite Solid Electrolytes,” Journal of Materials Chemistry A 13 (2025): 22809–22821.

[31]	S. Wang, Q. Sun, W. Peng, et al., “Ameliorating the Interfacial Issues of All-Solid-State Lithium Metal Batteries by Constructing Polymer/Inorganic Composite Electrolyte,” Journal of Energy Chemistry 58 (2021): 85–93.

[32]	C. Ślusarczyk, K. Suchocka-Gałaś, J. Fabia, and A. Włochowicz, “Small-Angle X-Ray Scattering Study of Poly(Ethylene-Oxide) and Styrene-Based Ionomers Blends,” Journal of Applied Crystallography 36 (2003): 698–701.

[33]	T. Yamada, J. Li, C. Koyanagi, T. Iyoda, and H. Yoshida, “Effect of Lithium Trifluoromethanesulfonate on the Phase Diagram of A Liquid-Crystalline Amphiphilic Diblock Copolymer,” Journal of Applied Crystallography 40 (2007): s585–s589.

[34]	S. D. Perera, R. B. Archer, C. A. Damin, R. Mendoza-Cruz, and C. P. Rhodes, “Controlling Interlayer Interactions in Vanadium Pentoxide-Poly(Ethylene Oxide) Nanocomposites for Enhanced Magnesium-Ion Charge Transport and Storage,” Journal of Power Sources 343 (2017): 580–591.

[35]	Y. Zheng, D. Wu, T. Wang, et al., “Advanced Eutectogel Electrolyte for High-Performance and Wide-Temperature Flexible Zinc-Air Batteries,” Angewandte Chemie International Edition 64 (2025): e202418223.

[36]	A. Maradesa, B. Py, J. Huang, et al., “Advancing Electrochemical Impedance Analysis Through Innovations in the Distribution of Relaxation Times Method,” Joule 8 (2024): 1958–1981.

[37]	S. J. Kim, D. Woo, D. Kim, T. K. Lee, J. Lee, and W. Lee, “Interface Engineering of an Electrospun Nanofiber-Based Composite Cathode for Intermediate-Temperature Solid Oxide Fuel Cells,” International Journal of Extreme Manufacturing 5 (2023): 015506.

[38]	M. Yang, T. Chen, G. Wang, et al., “A Surface-to-Interface Boronation Engineering Strategy Stabilizing the O/Mn Redox Chemistry of Lithium-Rich Manganese Based Oxides Towards High Energy-Density Cathodes,” Energy & Environmental Science 18 (2025): 6168–6179.

[39]	J.-L. Li, L. Shen, Z.-N. Cheng, et al., “Unveiling Solid-Solid Contact States in All-Solid-State Lithium Batteries: An Electrochemical Impedance Spectroscopy Viewpoint,” Journal of Energy Chemistry 101 (2025): 16–22.

[40]	Y. Zhang, Z. Wang, Y. Pan, et al., “Tailoring A Multi-System Adaptable Gel Polymer Electrolyte for the Realization of Carbonate Ester and Ether-Based Li-Span Batteries,” Energy & Environmental Science 17 (2024): 2576–2587.

[41]	S. Wang, C. Li, Y. Ma, et al., “Regulating Crystalline Phase/Plane of Polymer Electrolyte for Rapid Lithium Ion Transfer,” Angewandte Chemie International Edition 64 (2025): e202420698.

[42]	Q. Jiang, M. Li, J. Li, et al., “LiF-Rich Cathode Electrolyte Interphases Homogenizing Li⁺ Fluxes Toward Stable Interface in Li-Rich Mn-Based Cathodes,” Advanced Materials 37 (2025): e2417620.

[43]	R. Hou, L. Zheng, T. Shi, et al., “An Unexpected Low-Temperature Battery Formation Technology Enabling Fast-Charging Graphite Anodes,” Advanced Functional Materials 35 (2025): 2500481.