Elucidating the Interplay Between Structure and Electrochemical Behavior in Lignin-Based Polymer Electrolytes for Potassium Batteries

Giuseppe Pascuzzi , Sabrina Trano , Carlotta Francia , Stefano Turri , Federico Bella , Gianmarco Griffini

Battery Energy ›› 2025, Vol. 4 ›› Issue (2) : e70002

PDF
Battery Energy ›› 2025, Vol. 4 ›› Issue (2) : e70002 DOI: 10.1002/bte2.70002
RESEARCH ARTICLE

Elucidating the Interplay Between Structure and Electrochemical Behavior in Lignin-Based Polymer Electrolytes for Potassium Batteries

Author information +
History +
PDF

Abstract

Potassium batteries are very appealing for stationary applications and domestic use, offering a promising alternative to lithium-ion systems. To improve their safety and environmental impact, gel polymer electrolytes (GPEs) based on bioderived materials can be employed. In this work, a series of biobased membranes are developed by crosslinking pre-oxidized Kraft lignin as bio-based component and poly(ethylene glycol) diglycidyl ether (PEGDGE) as functional linker with 200, 500, and 1000 g mol−1 molecular weight. The influence of PEGDGE chain length on the physicochemical properties and electrochemical performance of GPEs for potassium batteries is investigated. These membranes exhibit thermal stability above 240°C and tunable glass transition temperatures depending on the PEGDGE molecular weight. Their mechanical properties are determined by rheology measurements in dry and swollen states, evidencing a slight decrease of elastic modulus (G′) by increasing PEGDGE chain length. An approximately one-order-of-magnitude lower G′ value is observed in swollen membranes versus their dry counterpart. Upon successful activation of the lignin-based membranes by swelling in the liquid electrolyte embedding potassium salts, these GPEs are tested in potassium metal cell prototypes. These systems exhibit ionic conductivity of ~10−3 S cm−1 at ambient temperature. Interestingly, battery devices equipped with the GPE based on PEGDGE 1000 g mol−1 withstand current densities as high as 1.5 mA cm−2 during operation. Moreover, the same devices reach specific capacities of 130 mAh g‒1 at 0.05 A g−1 in the first 100 cycles and long-term operation for over 2500 cycles, representing outstanding achievements as bio-sourced systems for potassium batteries.

Keywords

bio-based polymers / gel polymer electrolyte / lignin / postlithium batteries / potassium batteries / sustainable batteries

Cite this article

Download citation ▾
Giuseppe Pascuzzi, Sabrina Trano, Carlotta Francia, Stefano Turri, Federico Bella, Gianmarco Griffini. Elucidating the Interplay Between Structure and Electrochemical Behavior in Lignin-Based Polymer Electrolytes for Potassium Batteries. Battery Energy, 2025, 4(2): e70002 DOI:10.1002/bte2.70002

登录浏览全文

4963

注册一个新账户 忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

M. Zhou, P. Bai, X. Ji, J. Yang, C. Wang, and Y. Xu, “Electrolytes and Interphases in Potassium Ion Batteries,” Advanced Materials 33, no. 7 (2021): 2003741.
[2]

V. Anoopkumar, B. John, and T. D. Mercy, “Potassium-Ion Batteries: Key to Future Large-Scale Energy Storage?,” ACS Applied Energy Materials 3, no. 10 (2020): 9478-9492.
[3]

M. S. Guney and Y. Tepe, “Classification and Assessment of Energy Storage Systems,” Renewable and Sustainable Energy Reviews 75 (2017): 1187-1197.
[4]

N. L. Panwar, S. C. Kaushik, and S. Kothari, “Role of Renewable Energy Sources in Environmental Protection: A Review,” Renewable and Sustainable Energy Reviews 15, no. 3 (2011): 1513-1524.
[5]

C. Furlan and C. Mortarino, “Forecasting the Impact of Renewable Energies in Competition With Non-Renewable Sources,” Renewable and Sustainable Energy Reviews 81 (2018): 1879-1886.
[6]

A. B. Gallo, J. R. Simões-Moreira, H. K. M. Costa, M. M. Santos, and E. Moutinho dos Santos, “Energy Storage in the Energy Transition Context: A Technology Review,” Renewable and Sustainable Energy Reviews 65 (2016): 800-822.
[7]

W. F. Pickard, A. Q. Shen, and N. J. Hansing, “Parking the Power: Strategies and Physical Limitations for Bulk Energy Storage in Supply-Demand Matching on a Grid Whose Input Power Is Provided by Intermittent Sources,” Renewable and Sustainable Energy Reviews 13, no. 8 (2009): 1934-1945.
[8]

B. Kale and S. Chatterjee, “Electrochemical Energy Storage Systems: India Perspective,” Bulletin of Materials Science 43, no. 1 (2020): 96.
[9]

Y. Sun, Z. Zhao, M. Yang, D. Jia, W. Pei, and B. Xu, “Overview of Energy Storage in Renewable Energy Power Fluctuation Mitigation,” CSEE Journal of Power and Energy Systems 6, no. 1 (2020): 160-173.
[10]

G. Coppez, S. Chowdhury, and S. P. Chowdhury, “The Importance of Energy Storage in Renewable Power Generation: A Review,” In 45th International Universities Power Engineering Conference UPEC 2010, (United Kingdom: Institute of Electrical and Electronics Engineers [IEEE], 2010), 1281-1285.
[11]

H. Kim, J. Hong, K. Y. Park, H. Kim, S. W. Kim, and K. Kang, “Aqueous Rechargeable Li and Na Ion Batteries,” Chemical Reviews 114, no. 23 (2014): 11788-11827.
[12]

T. Placke, R. Kloepsch, S. Dühnen, and M. Winter, “Lithium Ion, Lithium Metal, and Alternative Rechargeable Battery Technologies: The Odyssey for High Energy Density,” Journal of Solid State Electrochemistry 21, no. 7 (2017): 1939-1964.
[13]

B. Wang, W. Du, Y. Yang, et al., “Two-Dimensional Germanium Sulfide Nanosheets as an Ultra-Stable and High Capacity Anode for Lithium Ion Batteries,” Chemistry—A European Journal 26, no. 29 (2020): 6554-6560.
[14]

Y. Zhao, O. Pohl, A. I. Bhatt, et al., “A Review on Battery Market Trends, Second-Life Reuse, and Recycling,” Sustainable Chemistry 2, no. 1 (2021): 167-205.
[15]

J. M. Tarascon and M. Armand, “Issues and Challenges Facing Rechargeable Lithium Batteries,” Nature 414 (2001): 359-367.
[16]

B. K. Sovacool, S. H. Ali, M. Bazilian, et al., “Sustainable Minerals and Metals for a Low-Carbon Future,” Science 367, no. 6473 (2020): 30-33.
[17]

C. Vaalma, D. Buchholz, M. Weil, and S. Passerini, “A Cost and Resource Analysis of Sodium-Ion Batteries,” Nature Reviews Materials 3, no. 4 (2018): 18013.
[18]

European Commission, Communication From the Commission to the European Parliament, the Council, the European Economic and Social Committee and the Committee of the Regions Youth Opportunities Initiative (European Commission, 2011).
[19]

Inkwood Research, Size of the Global Battery Market From 2018 to 2021, With a Forecast Through 2030, by Technology (in Million U.S. dollars) 2022, https://www.statista.com/statistics/1339880/global-battery-market-size-by-technology/.
[20]

Statista Estimates; BloombergNEF; US Department of Energy, Projected Global Battery Demand From 2020 to 2030, by Application (in Gigawatt Hours) 2021, https://www.statista.com/statistics/1103218/global-battery-demand-forecast/.
[21]

M. Walter, M. V. Kovalenko, and K. V. Kravchyk, “Challenges and Benefits of Post-Lithium-Ion Batteries,” New Journal of Chemistry 44, no. 5 (2020): 1677-1683.
[22]

R. Rajagopalan, Y. Tang, X. Ji, C. Jia, and H. Wang, “Advancements and Challenges in Potassium Ion Batteries: A Comprehensive Review,” Advanced Functional Materials 30, no. 12 (2020): 1909486.
[23]

Y. Xu, T. Ding, D. Sun, X. Ji, and X. Zhou, “Recent Advances in Electrolytes for Potassium-Ion Batteries,” Advanced Functional Materials 33, no. 6 (2023): 2211290.
[24]

Q. Yao and C. Zhu, “Advanced Post-Potassium-Ion Batteries as Emerging Potassium-Based Alternatives for Energy Storage,” Advanced Functional Materials 30, no. 49 (2020): 2005209.
[25]

Z. Zhang, M. Li, Y. Gao, et al., “Fast Potassium Storage in Hierarchical Ca0.5Ti2(PO4)3@C Microspheres Enabling High-Performance Potassium-Ion Capacitors,” Advanced Functional Materials 28, no. 36 (2018): 1802684.
[26]

K. Lei, F. Li, C. Mu, et al., “High K-Storage Performance Based on the Synergy of Dipotassium Terephthalate and Ether-Based Electrolytes,” Energy & Environmental Science 10, no. 2 (2017): 552-557.
[27]

Z. Liu, X. Liu, B. Wang, et al., “Ultra-Thick, Dense Dual-Encapsulated Sb Anode Architecture With Conductively Elastic Networks Promises Potassium-Ion Batteries With High Areal and Volumetric Capacities,” eScience 3, no. 6 (2023): 100177.
[28]

L. Ni, G. Xu, C. Li, and G. Cui, “Electrolyte Formulation Strategies for Potassium-Based Batteries,” Exploration 2, no. 2 (2022): 20210239.
[29]

Y. K. Liu, C. Z. Zhao, J. Du, X. Q. Zhang, A. B. Chen, and Q. Zhang, “Research Progresses of Liquid Electrolytes in Lithium-Ion Batteries,” Small 19, no. 8 (2023): 2205315.
[30]

B. Li, Y. Chao, M. Li, et al., “A Review of Solid Electrolyte Interphase (SEI) and Dendrite Formation in Lithium Batteries,” Electrochemical Energy Reviews 6, no. 1 (2023): 7.
[31]

P. Jaumaux, J. Wu, D. Shanmukaraj, et al., “Non-Flammable Liquid and Quasi-Solid Electrolytes Toward Highly-Safe Alkali Metal-Based Batteries,” Advanced Functional Materials 31, no. 10 (2021): 2008644.
[32]

N. E. Galushkin, N. N. Yazvinskaya, and D. N. Galushkin, “Mechanism of Thermal Runaway in Lithium-Ion Cells,” Journal of the Electrochemical Society 165, no. 7 (2018): A1303-A1308.
[33]

X. Gong, D. Shi, H. Zeng, et al., “Facile One Pot Polycondensation Method to Synthesize the Crosslinked Polyethylene Glycol-Based Copolymer Electrolytes,” Macromolecular Chemistry and Physics 217, no. 14 (2016): 1607-1613.
[34]

Y. Wang, J. Qiu, J. Peng, J. Li, and M. Zhai, “One-Step Radiation Synthesis of Gel Polymer Electrolytes With High Ionic Conductivity for Lithium-Ion Batteries,” Journal of Materials Chemistry A 5, no. 24 (2017): 12393-12399.
[35]

X. Cheng, J. Pan, Y. Zhao, M. Liao, and H. Peng, “Gel Polymer Electrolytes for Electrochemical Energy Storage,” Advanced Energy Materials 8, no. 7 (2018): 1702184.
[36]

W. Ren, C. Ding, X. Fu, and Y. Huang, “Advanced Gel Polymer Electrolytes for Safe and Durable Lithium Metal Batteries: Challenges, Strategies, and Perspectives,” Energy Storage Materials 34 (2021): 515-535.
[37]

J. Pan, N. Wang, and H. J. Fan, “Gel Polymer Electrolytes Design for Na-Ion Batteries,” Small Methods 6, no. 11 (2022): 2201032.
[38]

S. Liang, W. Yan, X. Wu, et al., “Gel Polymer Electrolytes for Lithium Ion Batteries: Fabrication, Characterization and Performance,” Solid State Ionics 318 (2018): 2-18.
[39]

Z. Xiao, B. Zhou, J. Wang, et al., “PEO-Based Electrolytes Blended With Star Polymers With Precisely Imprinted Polymeric Pseudo-Crown Ether Cavities for Alkali Metal Ion Batteries,” Journal of Membrane Science 576 (2019): 182-189.
[40]

N. K. Jyothi, K. K. Venkataratnam, P. N. Murty, and K. V. Kumar, “Preparation and Characterization of PAN-KI Complexed Gel Polymer Electrolytes for Solid-State Battery Applications,” Bulletin of Materials Science 39, no. 4 (2016): 1047-1055.
[41]

H. Gao, L. Xue, S. Xin, and J. B. Goodenough, “A High-Energy-Density Potassium Battery With a Polymer-Gel Electrolyte and a Polyaniline Cathode,” Angewandte Chemie International Edition 57, no. 19 (2018): 5449-5453.
[42]

S. Wang, L. Zhang, Q. Zeng, et al., “Designing Polymer Electrolytes via Ring-Opening Polymerization for Advanced Lithium Batteries,” Advanced Energy Materials 14, no. 3 (2024): 2302876.
[43]

A. Nishimoto, K. Agehara, N. Furuya, T. Watanabe, and M. Watanabe, “High Ionic Conductivity of Polyether-Based Network Polymer Electrolytes With Hyperbranched Side Chains,” Macromolecules 32, no. 5 (1999): 1541-1548.
[44]

S. I. Lee, M. Schömer, H. Peng, et al., “Correlations Between Ion Conductivity and Polymer Dynamics in Hyperbranched Poly(Ethylene Oxide) Electrolytes for Lithium-Ion Batteries,” Chemistry of Materials 23, no. 11 (2011): 2685-2688.
[45]

E. A. R. Zuiderveen, K. J. J. Kuipers, C. Caldeira, et al., “The Potential of Emerging Bio-Based Products to Reduce Environmental Impacts,” Nature Communications 14, no. 1 (2023): 8521.
[46]

L. Liu, N. Solin, and O. Inganäs, “Bio Based Batteries,” Advanced Energy Materials 11, no. 43 (2021): 2003713.
[47]

X. Zhu, J. C. Roy, X. Li, J. Li, and L. Zhang, “Toward Improved Sustainability in Lithium Ion Batteries Using Bio-Based Materials,” Trends in Chemistry 5, no. 5 (2023): 393-403.
[48]

M. Rayung, M. M. Aung, S. C. Azhar, et al., “Bio-Based Polymer Electrolytes for Electrochemical Devices: Insight Into the Ionic Conductivity Performance,” Materials 13, no. 4 (2020): 838.
[49]

S. Ahmed, P. Sharma, S. Bairagi, et al., “Nature-Derived Polymers and Their Composites for Energy Depository Applications in Batteries and Supercapacitors: Advances, Prospects and Sustainability,” Journal of Energy Storage 66 (2023): 107391.
[50]

E. P. Feofilova and I. S. Mysyakina, “Lignin: Chemical Structure, Biodegradation, and Practical Application (A Review),” Applied Biochemistry and Microbiology 52, no. 6 (2016): 573-581.
[51]

H. Fei, Y. Liu, Y. An, et al., “Stable All-Solid-State Potassium Battery Operating at Room Temperature With a Composite Polymer Electrolyte and a Sustainable Organic Cathode,” Journal of Power Sources 399 (2018): 294-298.
[52]

H. Liu, T. Xu, K. Liu, et al., “Lignin-Based Electrodes for Energy Storage Application,” Industrial Crops and Products 165 (2021): 113425.
[53]

X. Meng, M. Poonia, C. G. Yoo, and A. J. Ragauskas, “Recent Advances in Synthesis and Application of Lignin Nanoparticles,” in Lignin Utilization Strategies: From Processing to Applications, ed. C. G. Yoo and A. Ragauskas (American Chemical Society, 2021), 11-273.
[54]

A. T. Smit, E. Bellinetto, T. Dezaire, et al., “Tuning the Properties of Biobased PU Coatings via Selective Lignin Fractionation and Partial Depolymerization,” ACS Sustainable Chemistry & Engineering 11, no. 18 (2023): 7193-7202.
[55]

E. Bellinetto, N. Fumagalli, M. Astorri, S. Turri, and G. Griffini, “Elucidating the Role of Lignin Type and Functionality in the Development of High-Performance Biobased Phenolic Thermoset Resins,” ACS Applied Polymer Materials 6, no. 2 (2024): 1191-1203.
[56]

S. Trano, F. Corsini, G. Pascuzzi, et al., “Lignin as Polymer Electrolyte Precursor for Stable and Sustainable Potassium Batteries,” Chemsuschem 15, no. 12 (2022): e202200294.
[57]

J. Han, A. Mariani, H. Zhang, et al., “Gelified Acetate-Based Water-In-Salt Electrolyte Stabilizing Hexacyanoferrate Cathode for Aqueous Potassium-Ion Batteries,” Energy Storage Materials 30 (2020): 196-205.
[58]

L. Passauer, K. Fischer, and F. Liebner, “Activation of Pine Kraft Lignin by Fenton-Type Oxidation for Cross-Linking With Oligo (Oxyethylene) Diglycidyl Ether,” Holzforschung 65 (2011): 319-326.
[59]

A. More, T. Elder, and Z. Jiang, “A Review of Lignin Hydrogen Peroxide Oxidation Chemistry With Emphasis on Aromatic Aldehydes and Acids,” Holzforschung 75, no. 9 (2021): 806-823.
[60]

J. C. de Haro, E. Tatsi, L. Fagiolari, et al., “Lignin-Based Polymer Electrolyte Membranes for Sustainable Aqueous Dye-Sensitized Solar Cells,” ACS Sustainable Chemistry & Engineering 9, no. 25 (2021): 8550-8560.
[61]

J. H. Park, H. H. Rana, J. Y. Lee, and H. S. Park, “Renewable Flexible Supercapacitors Based on All-Lignin-Based Hydrogel Electrolytes and Nanofiber Electrodes,” Journal of Materials Chemistry A 7, no. 28 (2019): 16962-16968.
[62]

L. Passauer, K. Fischer, and F. Liebner, “Preparation and Physical Characterization of Strongly Swellable Oligo (Oxyethylene) Lignin Hydrogel,” Holzforschung 65 (2011): 309-317.
[63]

J. Clayden, N. Greeves, and S. Warren, Organic Chemistry (Oxford University Press, 2012).
[64]

Z. Xue, D. He, and X. Xie, “Poly(Ethylene Oxide)-Based Electrolytes for Lithium-Ion Batteries,” Journal of Materials Chemistry A 3, no. 38 (2015): 19218-19253.
[65]

M. Jaipal Reddy, J. Siva Kumar, U. V. Subba Rao, and P. P. Chu, “Structural and Ionic Conductivity of PEO Blend PEG Solid Polymer Electrolyte,” Solid State Ionics 177, no. 3 (2006): 253-256.
[66]

W. Lyu, X. Yu, Y. Lv, A. M. Rao, J. Zhou, and B. Lu, “Building Stable Solid-State Potassium Metal Batteries,” Advanced Materials 36, no. 24 (2024): 2305795.
[67]

S. Chapi, M. V. Murugendrappa, A. Rayar, et al., “Enhanced Structural, Electrical, and Electrochemical Performance of Polyethylene Oxides (PEO)-Based Polymer Electrolytes for Solid State K+ Ion Batteries,” Journal of Applied Polymer Science 141, no. 20 (2024): e55390.
[68]

G. Socrates, Infrared and Raman Characteristic Group Frequencies: Tables and Charts (John Wiley & Sons, 2004).
[69]

J. A. Baird, R. Olayo-Valles, C. Rinaldi, and L. S. Taylor, “Effect of Molecular Weight, Temperature, and Additives on the Moisture Sorption Properties of Polyethylene Glycol,” Journal of Pharmaceutical Sciences 99, no. 1 (2010): 154-168.
[70]

C. M. Popescu, C. Vasile, M. C. Popescu, G. Singurel, V. Popa, and B. Munteanu, “Analytical Methods for Lignin Characterization. II. Spectroscopic Studies,” Cellulose Chemistry and Technology 40 (2006): 597-621.
[71]

C. Allegretti, E. Bellinetto, P. D'Arrigo, et al., “Towards a Complete Exploitation of Brewers'; Spent Grain From a Circular Economy Perspective,” Fermentation 8, no. 4 (2022): 8040151.
[72]

C. G. Boeriu, D. Bravo, R. J. A. Gosselink, and J. E. G. van Dam, “Characterisation of Structure-Dependent Functional Properties of Lignin With Infrared Spectroscopy,” Industrial Crops and Products 20, no. 2 (2004): 205-218.
[73]

F. G. Calvo-Flores, J. A. Dobado, and F. J. M. M. Joaquín Isac-García, “Functional and Spectroscopic Characterization of Lignins,” in Lignin and Lignans as Renewable Raw Materials: Chemistry,Technology and Applications, ed. F. G. Calvo-Flores, J. A. Dobado, J. Isac-García, and F. J. Martín-MartíNez (John Wiley & Sons, 2015), 145-188.
[74]

V. Passoni, C. Scarica, M. Levi, S. Turri, and G. Griffini, “Fractionation of Industrial Softwood Kraft Lignin: Solvent Selection as a Tool for Tailored Material Properties,” ACS Sustainable Chemistry & Engineering 4, no. 4 (2016): 2232-2242.
[75]

P. Tanasini, G. Widmer, and R. Raballand, “Crosslinking and Decomposition of Epoxy Resins Induced by Contamination With Water-Assessment of an Industrial Scale Scenario,” Chemical Engineering Transactions 48 (2016): 703-708.
[76]

Y. Noishiki and T. Miyata, “Polyepoxy Compound Fixation,” in Encyclopedia of Biomedical Polymers and Polymeric Biomaterials, ed. M. Mishra, Vol. 11, 1st ed. (CRC Press, 2015), 9.
[77]

J. Leach, J. Wolinsky, P. Stone, and J. Wong, “Crosslinked α-Elastin Biomaterials: Towards a Processable Elastin Mimetic Scaffold,” Acta Biomaterialia 1, no. 2 (2005): 155-164.
[78]

E. Cortés-Triviño, C. Valencia, M. A. Delgado, and J. M. Franco, “Modification of Alkali Lignin With Poly(Ethylene Glycol) Diglycidyl Ether to Be Used as a Thickener in Bio-Lubricant Formulations,” Polymers 10, no. 6 (2018): 670.
[79]

V. Madhani, D. Kumar, D. K. Kanchan, and M. Singh Rathore, “Recent Advances and Prospects of K-Ion Conducting Polymer Electrolytes,” Journal of Electroanalytical Chemistry 935 (2023): 117334.
[80]

K. Aruchamy, S. Ramasundaram, S. Divya, M. Chandran, K. Yun, and T. H. Oh, “Gel Polymer Electrolytes: Advancing Solid-State Batteries for High-Performance Applications,” Gels 9, no. 7 (2023): 585.
[81]

R. Verma, P. N. Didwal, J. Y. Hwang, and C. J. Park, “Recent Progress in Electrolyte Development and Design Strategies for Next-Generation Potassium-Ion Batteries,” Batteries & Supercaps 4, no. 9 (2021): 1428-1450.
[82]

H. Yin, C. Han, Q. Liu, F. Wu, F. Zhang, and Y. Tang, “Recent Advances and Perspectives on the Polymer Electrolytes for Sodium/Potassium-Ion Batteries,” Small 17, no. 31 (2021): 2006627.
[83]

M. Zhu, J. Wu, Y. Wang, et al., “Recent Advances in Gel Polymer Electrolyte for High-Performance Lithium Batteries,” Journal of Energy Chemistry 37 (2019): 126-142.
[84]

K. H. Chen, K. N. Wood, E. Kazyak, et al., “Dead Lithium: Mass Transport Effects on Voltage, Capacity, and Failure of Lithium Metal Anodes,” Journal of Materials Chemistry A 5, no. 23 (2017): 11671-11681.
[85]

M. L. Lehmann, G. Yang, J. Nanda, and T. Saito, “Well-Designed Crosslinked Polymer Electrolyte Enables High Ionic Conductivity and Enhanced Salt Solvation,” Journal of the Electrochemical Society 167, no. 7 (2020): 070539.
[86]

M. Dirican, C. Yan, P. Zhu, and X. Zhang, “Composite Solid Electrolytes for All-Solid-State Lithium Batteries,” Materials Science and Engineering: R: Reports 136 (2019): 27-46.
[87]

M. A. Ratner, P. Johansson, and D. F. Shriver, “Polymer Electrolytes: Ionic Transport Mechanisms and Relaxation Coupling,” MRS Bulletin 25, no. 3 (2000): 31-37.
[88]

Z. Wu, J. Zou, S. Shabanian, K. Golovin, and J. Liu, “The Roles of Electrolyte Chemistry in Hard Carbon Anode for Potassium-Ion Batteries,” Chemical Engineering Journal 427 (2022): 130972.
[89]

Y. Lei, L. Qin, R. Liu, et al., “Exploring Stability of Nonaqueous Electrolytes for Potassium-Ion Batteries,” ACS Applied Energy Materials 1, no. 5 (2018): 1828-1833.
[90]

H. Wang, D. Zhai, and F. Kang, “Solid Electrolyte Interphase (SEI) in Potassium Ion Batteries,” Energy & Environmental Science 13, no. 12 (2020): 4583-4608.
[91]

M. Nishida, Y. Uraki, and Y. Sano, “Lignin Gel With Unique Swelling Property,” Bioresource Technology 88, no. 1 (2003): 81-83.
[92]

D. Vural, J. C. Smith, and L. Petridis, “Polymer Principles Behind Solubilizing Lignin With Organic Cosolvents for Bioenergy,” Green Chemistry 22, no. 13 (2020): 4331-4340.

RIGHTS & PERMISSIONS

2025 The Author(s). Battery Energy published by Xijing University and John Wiley & Sons Australia, Ltd.

AI Summary AI Mindmap
PDF

36

Accesses

0

Citation

Detail
Sections
Recommended

AI思维导图

/