Multi-Phase Synergy Enhances Lithium-Ion Storage Performance of Transition Metal Oxalates

Liying Xue , Stefanie Arnold , Jean Gustavo de Andrade Ruthes , Oliver Janka , Chaochao Dun , Volker Presser

Battery Energy ›› 2026, Vol. 5 ›› Issue (3) : e70103

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Battery Energy ›› 2026, Vol. 5 ›› Issue (3) :e70103 DOI: 10.1002/bte2.70103
RESEARCH ARTICLE
Multi-Phase Synergy Enhances Lithium-Ion Storage Performance of Transition Metal Oxalates
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Abstract

Transition metal oxalates have been proven to be a promising electrode material for lithium-ion batteries. Here, we have designed a series of multi-phase transition metal oxalates with different structures and compositions by simply adjusting the proportions of five transition metal elements. Among them, the multi-phase mixture (MC2O4·2H2O - CuC2O4 - MC2O4·2H2O, M = Mn, Fe, Co, Ni, Cu) provides a more stable framework for the material during lithiation and delithiation, effectively alleviating the structural collapse during the cycling process. In addition, the electron transport and fast charge compensation processes of multiple electrochemically active metal pairs also contribute to the improvement of performance. Therefore, the multi-phase transition metal oxalate TMOx-2 electrode with an additional CuC2O4 phase exhibits high reversible capacity and long-term cycling stability. After 400 cycles at 100 and 500 mA/g, the specific discharge capacities are 827 mAh/g and 498 mAh/g, respectively. Constructing multi-metal, multi-phase systems by combining different transition metals enables control over potential, reaction pathways, and stability of high-performance electrodes.

Keywords

anode materials / lithium-ion batteries / multi-phase structure / transition metal oxalates

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Liying Xue, Stefanie Arnold, Jean Gustavo de Andrade Ruthes, Oliver Janka, Chaochao Dun, Volker Presser. Multi-Phase Synergy Enhances Lithium-Ion Storage Performance of Transition Metal Oxalates. Battery Energy, 2026, 5 (3) : e70103 DOI:10.1002/bte2.70103

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References

[1]

M. Wakihara, “Recent Developments in Lithium Ion Batteries,” Materials Science and Engineering: R: Reports 33, no. 4 (2001): 109–134.

[2]

P. G. Bruce, B. Scrosati, and J. M. Tarascon, “Nanomaterials for Rechargeable Lithium Batteries,” Angewandte Chemie International Edition 47, no. 16 (2008): 2930–2946.

[3]

P. Roy and S. K. Srivastava, “Nanostructured Anode Materials for Lithium Ion Batteries,” Journal of Materials Chemistry A 3, no. 6 (2015): 2454–2484.

[4]

K. Yuan, Y. Lin, X. Li, et al., “High-Safety Anode Materials for Advanced Lithium-Ion Batteries, Energy & Environmental,” Materials 7, no. 5 (2024): e12759.

[5]

M. Li, J. Lu, Z. Chen, and K. Amine, “30 Years of Lithium-Ion Batteries,” Advanced Materials 30, no. 33 (2018): e1800561.

[6]

S. K. Nemani, M. Torkamanzadeh, B. C. Wyatt, V. Presser, and B. Anasori, “Functional Two-Dimensional High-Entropy Materials,” Communications Materials 4, no. 1 (2023): 16.

[7]

B. Jin, G. Gao, Q. Zhao, et al., “Recycling Acidic Iron Wastewater for the Production of an Iron Oxalate Anode Material With Superior Long-Cycling Lithium Storage Ability,” Journal of Materials Chemistry C 13, no. 19 (2025): 9554–9567.

[8]

J. S. Yeoh, I. Di Bernardo, N. G. White, V. Otieno-Alego, T. Tsuzuki, and A. Lowe, “Iron-Based Energy Storage Materials From Carbon Dioxide and Scrap Metal,” Materials Advances 2, no. 1 (2021): 292–302.

[9]

B. Simon, S. Flandrois, K. Guerin, A. Fevrier-Bouvier, I. Teulat, and P. Biensan, “On the Choice of Graphite for Lithium Ion Batteries,” Journal of Power Sources 81–82 (1999): 312–316.

[10]

U. Kasavajjula, C. Wang, and A. J. Appleby, “Nano- and Bulk-Silicon-Based Insertion Anodes for Lithium-Ion Secondary Cells,” Journal of Power Sources 163, no. 2 (2007): 1003–1039.

[11]

M. C. López, J. L. Tirado, and C. Pérez Vicente, “Structural and Comparative Electrochemical Study of M(II) Oxalates, M = Mn, Fe, Co, Ni, Cu, Zn,” Journal of Power Sources 227 (2013): 65–71.

[12]

K. Zhang, Y. Li, Y. Wang, et al., “Enhanced Electrochemical Properties of Iron Oxalate With More Stable Li+ Ions Diffusion Channels by Controlling Polymorphic Structure,” Chemical Engineering Journal 384 (2020): 123281.

[13]

Y. N. Zhang, S. S. Li, H. X. Kuai, et al., “Proton Solvent-Controllable Synthesis of Manganese Oxalate Anode Material for Lithium-Ion Batteries,” RSC Advances 11, no. 38 (2021): 23259–23269.

[14]

W. A. Ang, Y. L. Cheah, C. L. Wong, R. Prasanth, H. H. Hng, and S. Madhavi, “Mesoporous Cobalt Oxalate Nanostructures as High-Performance Anode Materials for Lithium-Ion Batteries: Ex Situ Electrochemical Mechanistic Study,” Journal of Physical Chemistry C 117, no. 32 (2013): 16316–16325.

[15]

J. Xu, L. He, H. Liu, et al., “Controlled Synthesis of Porous Anhydrous Cobalt Oxalate Nanorods With High Reversible Capacity and Excellent Cycling Stability,” Electrochimica Acta 170 (2015): 85–91.

[16]

K. Zhang, Y. Li, X. Hu, et al., “Inhibitive Role of Crystal Water on Lithium Storage for Multilayer FeC2O4 · xH2O Anode Materials,” Chemical Engineering Journal 404 (2021): 126464.

[17]

B. Sun, L. Kuang, G. Li, et al., “Synergistic Structure and Oxygen-Vacancies Engineering of Lithium Vanadate for Kinetically Accelerated and Pseudocapacitance-Dominated Lithium Storage,” Chemical Engineering Journal 484 (2024): 149609.

[18]

J. Zhang, X. Bo, R. Wu, et al., “Transition Metal Carbonates/Oxalates for Advanced Lithium Storage: Optimization Strategies, further Faradic Reactions and Capacitive/Interfacial Charge Storage,” Nano Energy 139 (2025): 110928.

[19]

S. Liang, H. Wang, Y. Li, H. Qin, Z. Luo, and L. Chen, “Ternary Synergistic Transition Metal Oxalate 2D Porous Thin Sheets Assembled by 3D Nanoflake Array With High Performance for Supercapattery,” Applied Surface Science 567 (2021): 150809.

[20]

T. Chen, Z. Liu, H. Fan, L. Guo, and X. Tao, “Optimization Design of Orthorhombic-Monoclinic Co1-xNixC2O4 · 2H2O Solid Solutions for High-Performance Pseudocapacitors,” Journal of Alloys and Compounds 808 (2019): 151722.

[21]

B. León, C. P. Vicente, and J. L. Tirado, “New Mixed Transition Metal Oxysalts as Negative Electrode Materials for Lithium-Ion Batteries,” Solid State Ionics 225 (2012): 518–521.

[22]

W. A. E. Ang, Y. L. Cheah, C. L. Wong, H. H. Hng, and S. Madhavi, “One-Pot Solvothermal Synthesis of Co1-xMnxC2O4 and Their Application as Anode Materials for Lithium-Ion Batteries,” Journal of Alloys and Compounds 638 (2015): 324–333.

[23]

L. Wang, J. L. Shi, H. Su, et al., “Composite-Structure Material Design for High-Energy Lithium Storage,” Small 14, no. 34 (2018): e1800887.

[24]

Z. Liu, Y. Bai, H. Sun, et al., “Synergistic Dual-Phase Air Electrode Enables High and Durable Performance of Reversible Proton Ceramic Electrochemical Cells,” Nature Communications 15, no. 1 (2024): 472.

[25]

J. Wang, W. Bai, Y. Zhou, et al., “Sea Cucumber-Inspired Multi-Phase Metal Sulfides With Hierarchical Structure Towards Energy Storage With Promoted Safety,” Journal of Energy Storage 76 (2024): 109743.

[26]

Y. Zhou, Y. Wang, Y. Zhang, et al., “Abundant Cu3P/Co2P/CoP@NC Heterostructures Boost Charge Transfer Toward Fast and Durable Sodium Storage,” Carbon Energy 7, no. 6 (2025): e721.

[27]

A. Lichchhavi, A. Kanwade, and P. M. Shirage, “A Review on Synergy of Transition Metal Oxide Nanostructured Materials: Effective and Coherent Choice for Supercapacitor Electrodes,” Journal of Energy Storage 55 (2022): 105692.

[28]

H. M. Rietveld, “Line Profiles of Neutron Powder-Diffraction Peaks for Structure Refinement,” Acta Crystallographica 22, no. 1 (1967): 151–152.

[29]

H. M. Rietveld, “A Profile Refinement Method for Nuclear and Magnetic Structures,” Journal of Applied Crystallography 2, no. 2 (1969): 65–71.

[30]

B. Krüner, A. Schreiber, A. Tolosa, et al., “Nitrogen-Containing Novolac-Derived Carbon Beads as Electrode Material for Supercapacitors,” Carbon 132 (2018): 220–231.

[31]

M. Zeiger, N. Jäckel, D. Weingarth, and V. Presser, “Vacuum or Flowing Argon: What Is the Best Synthesis Atmosphere for Nanodiamond-Derived Carbon Onions for Supercapacitor Electrodes?,” Carbon 94 (2015): 507–517.

[32]

T. Marino, M. Toscano, N. Russo, and A. Grand, “Structural and Electronic Characterization of the Complexes Obtained by the Interaction Between Bare and Hydrated First-Row Transition-Metal Ions (Mn2+, Fe2+, Co2+, Ni2+, Cu2+, Zn2+) and Glycine,” Journal of Physical Chemistry B 110, no. 48 (2006): 24666–24673.

[33]

A. M. Mohammed, “Hydration Structure and Water Exchange Dynamics of Fe(II) Ion in Aqueous Solution,” Bulletin of the Chemical Society of Ethiopia 24, no. 2 (2010): 239–250.

[34]

C. Zhao, Y. Jiang, S. Liang, F. Gao, L. Xie, and L. Chen, “Two-Dimensional Porous Nickel Oxalate Thin Sheets Constructed by Ultrathin Nanosheets as Electrode Materials for High-Performance Aqueous Supercapacitors,” CrystEngComm 22, no. 17 (2020): 2953–2963.

[35]

I. Persson, “Hydrated Metal Ions in Aqueous Solution: How Regular Are Their Structures?,” Pure and Applied Chemistry 82, no. 10 (2010): 1901–1917.

[36]

J. Kopp, P. Novák, S. Lisníková, V. Vrba, and V. Procházka, “Co-Precipitation of Fe-Cu Bimetal Oxalates in An Aqueous Solution and Their Thermally Induced Decomposition,” European Journal of Inorganic Chemistry 2021, no. 37 (2021): 3886–3895.

[37]

S. Caric, “Amélioration de la Structure de la Humboldtine FeC2O4 ⋅ 2H2O,” Bulletin of the French Society of Mineralogy and Crystallography 82 (1959): 50–55.

[38]

L. Zwiener, F. Girgsdies, R. Schlögl, and E. Frei, “Investigations of Cu/Zn Oxalates From Aqueous Solution: Single-Phase Precursors and Beyond,” Chemistry – A European Journal 24, no. 56 (2018): 15080–15088.

[39]

A. N. Christensen, B. Lebech, N. H. Andersen, and J.-C. Grivel, “The Crystal Structure of Paramagnetic Copper(II) Oxalate (CuC2O4): Formation and Thermal Decomposition of Randomly Stacked Anisotropic Nano-Sized Crystallites,” Dalton Transactions 43, no. 44 (2014): 16754–16768.

[40]

A. Koleżyński, B. Handke, and E. Drożdż-Cieśla, “Crystal Structure, Electronic Structure, and Bonding Properties of Anhydrous Nickel Oxalate,” Journal of Thermal Analysis and Calorimetry 113, no. 1 (2013): 319–328.

[41]

J. Romann, V. Chevallier, A. Merlen, and J.-C. Valmalette, “Self-Organized Assembly of Copper Oxalate Nanocrystals,” Journal of Physical Chemistry C 113, no. 13 (2009): 5068–5074.

[42]

M. C. D'Antonio, A. Wladimirsky, D. Palacios, et al., “Spectroscopic Investigations of Iron(II) and Iron(III) Oxalates,” Journal of the Brazilian Chemical Society 20, no. 3 (2009): 445–450.

[43]

W. Song, J. Zhang, C. Wen, et al., “Synchronous Redox Reactions in Copper Oxalate Enable High-Capacity Anode for Proton Battery,” Journal of the American Chemical Society 146, no. 7 (2024): 4762–4770.

[44]

I. I. Conde-Morales, L. Hinojosa-Reyes, J. L. Guzmán-Mar, and A. Hernández-Ramírez, “I.D.C. Sáenz-Tavera, M. Villanueva-Rodríguez, Different Iron Oxalate Sources as Catalysts on Pyrazinamide Degradation by the Photo-Fenton Process at Different pH Values,” Water, Air, & Soil Pollution 231, no. 8 (2020): 425.

[45]

K. Chen, Z. Li, K. Zhang, et al., “Coordinate Regulation of Amorphous Carbon Microspheres and Crystal Structure of Iron Oxalate for High Rate Lithium Storage Ability,” Journal of Alloys and Compounds 1008 (2024): 176844.

[46]

Y. Zhang, C. Wang, Y. Dong, R. Wei, and J. Zhang, “Understanding the High-Performance Anode Material of CoC2O4 ⋅2H2O Microrods Wrapped by Reduced Graphene Oxide for Lithium-Ion and Sodium-Ion Batteries,” Chemistry – A European Journal 27, no. 3 (2021): 993–1001.

[47]

L. Wang, R. Zhang, Y. Jiang, et al., “Interfacial Synthesis of Micro-Cuboid Ni0.55Co0.45C2O4 Solid Solution With Enhanced Electrochemical Performance for Hybrid Supercapacitors,” Nanoscale 11, no. 29 (2019): 13894–13902.

[48]

X. L. Wang, E. M. Jin, G. Sahoo, and S. M. Jeong, “High-Entropy Metal Oxide (NiMnCrCoFe)3O4 Anode Materials With Controlled Morphology for High-Performance Lithium-Ion Batteries,” Batteries 9, no. 3 (2023): 147.

[49]

B. Shen, Z. Chen, H. Mao, et al., “CTAB-Induced Synthesis of Two-Dimensional Copper Oxalate Particles: Using L-Ascorbic Acid as the Source of Oxalate Ligand,” RSC Advances 14, no. 32 (2024): 23225–23231.

[50]

F.-F. Xing, X.-Y. Huang, Y.-X. He, et al., “Synthesis of Mesoporous Rod-Like MnC2O4/MWCNT Composite Anode Material for Lithium-Ion Batteries,” Journal of Electronic Materials 52, no. 6 (2023): 4179–4190.

[51]

S. Chenakin and N. Kruse, “XPS Characterization of Transition Metal Oxalates,” Applied Surface Science 515 (2020): 146041.

[52]

K. Zhang, Q. Zhao, D. Cui, et al., “Enhancing Electrochemical Lithium-Storage Properties of Hydrated Iron Oxalate (FeC2O4·2H2O) Anode Material by Combining With Dual-States Copper,” Journal of Alloys and Compounds 976 (2024): 173036.

[53]

Z. Li, Q. Zhao, K. Zhang, et al., “Achieving Super Lithium Storage of FeC2O4/Gs Composites With Dual-Level Structured Graphene Sheets Through Electrostatic Adherence,” Journal of Materials Chemistry C 12, no. 37 (2024): 15012–15023.

[54]

S. Chenakin and N. Kruse, “Thermal Decomposition of Nickel Oxalate Dihydrate: A Detailed XPS Insight,” Journal of Physical Chemistry C 123, no. 51 (2019): 30926–30936.

[55]

S. P. Chenakin, R. Szukiewicz, R. Barbosa, and N. Kruse, “Surface Analysis of Transition Metal Oxalates: Damage Aspects,” Journal of Electron Spectroscopy and Related Phenomena 209 (2016): 66–77.

[56]

S. P. Chenakin and N. Kruse, “Surface Composition and Electronic Properties of Co-Cu Mixed Oxalates: A Detailed XPS Analysis,” Applied Surface Science 669 (2024): 160460.

[57]

K. Zhang, D. Cui, X. Huang, et al., “Insights into the Interfacial Chemistry and Conversion Mechanism of Iron Oxalate Toward the Reduction by Lithium,” Chemical Engineering Journal 426 (2021): 131446.

[58]

Y. Jia, A. Cheng, W. Ke, et al., “Hierarchical Structure Constructed by Manganese Oxalate Framework With Accurate Iron Doping for Ultra-Efficient Lithium Storage,” Electrochimica Acta 380 (2021): 138217.

[59]

F. Feng, W. Kang, F. Yu, H. Zhang, and Q. Shen, “High-Rate Lithium Storage Capability of Cupric-Cobaltous Oxalate Induced by Unavoidable Crystal Water and Functionalized Graphene Oxide,” Journal of Power Sources 282 (2015): 109–117.

[60]

W. Kang and Q. Shen, “The Shape-Controlled Synthesis and Novel Lithium Storage Mechanism of as-Prepared CuC2O4·xH2O Nanostructures,” Journal of Power Sources 238 (2013): 203–209.

[61]

M. J. Aragón, B. León, T. Serrano, C. Pérez Vicente, and J. L. Tirado, “Synergistic Effects of Transition Metal Substitution in Conversion Electrodes for Lithium-Ion Batteries,” Journal of Materials Chemistry 21, no. 27 (2011): 10102.

[62]

Y. Zhang, Z. Lu, M. Guo, Z. Bai, and B. Tang, “Porous CoC2O4 Nanorods as High Performance Anode Material for Lithium Ion Batteries,” JOM 68, no. 11 (2016): 2952–2957.

[63]

X. Yang, H. Wang, Y. Song, et al., “Low-Temperature Synthesis of a Porous High-Entropy Transition-Metal Oxide as an Anode for High-Performance Lithium-Ion Batteries,” ACS Applied Materials & Interfaces 14, no. 23 (2022): 26873–26881.

[64]

T. C. Liu, W. G. Pell, B. E. Conway, and S. L. Roberson, “Behavior of Molybdenum Nitrides as Materials for Electrochemical Capacitors: Comparison With Ruthenium Oxide,” Journal of the Electrochemical Society 145, no. 6 (1998): 1882–1888.

[65]

J. Wang, J. Polleux, J. Lim, and B. Dunn, “Pseudocapacitive Contributions to Electrochemical Energy Storage in TiO2 (Anatase) Nanoparticles,” Journal of Physical Chemistry C 111, no. 40 (2007): 14925–14931.

[66]

E. W. C. Spotte-Smith, R. L. Kam, D. Barter, et al., “Toward a Mechanistic Model of Solid-Electrolyte Interphase Formation and Evolution in Lithium-Ion Batteries,” ACS Energy Letters 7, no. 4 (2022): 1446–1453.

[67]

M. H. Hossain, M. A. Chowdhury, N. Hossain, M. A. Islam, and M. H. Mobarak, “Advances of Lithium-Ion Batteries Anode Materials—A Review,” Chemical Engineering Journal Advances 16 (2023): 100569.

[68]

F. Baakes, D. Witt, and U. Krewer, “Impact of Electrolyte Impurities and SEI Composition on Battery Safety,” Chemical Science 14, no. 47 (2023): 13783–13798.

[69]

C. Hu, M. Geng, H. Yang, et al., “A Review of Capacity Fade Mechanism and Promotion Strategies for Lithium Iron Phosphate Batteries,” Coatings 14, no. 7 (2024): 832.

[70]

K. Zhang, R. Xu, R. Wei, et al., “Tunable Polymorph and Morphology Synthesis of Iron Oxalate Nanoparticles as Anode Materials for Lithium Ion Batteries,” Materials Chemistry and Physics 243 (2020): 122676.

[71]

C. Heubner, K. Nikolowski, S. Reuber, M. Schneider, M. Wolter, and A. Michaelis, “Recent Insights into Rate Performance Limitations of Li-Ion,” Batteries, Batteries & Supercaps 4, no. 2 (2020): 268–285.

[72]

K. Zhang, D. Zhang, Y. Li, et al., “FeC2O4@Fe2O3/rGO Composites With a Novel Interfacial Characteristic and Enhanced Ultrastable Lithium Storage Performance,” Applied Surface Science 507 (2020): 145051.

[73]

W. A. Ang, N. Gupta, R. Prasanth, and S. Madhavi, “High-Performing Mesoporous Iron Oxalate Anodes for Lithium-Ion Batteries,” ACS Applied Materials & Interfaces 4, no. 12 (2012): 7011–7019.

[74]

T. Song, G. Gao, D. Cui, et al., “Achieving Ultrastability and Efficient Lithium Storage Capacity With High-Energy Iron(II) Oxalate Anode Materials by Compositing Ge Nano-Conductive Sites,” Nanoscale 15, no. 6 (2023): 2700–2713.

[75]

Y. Zhang, Y. Dong, R. Wei, et al., “Rod-Like Ni0.5Co0.5C2O4.2H2O In-Situ Formed on rGO by an Interface Induced Engineering: Extraordinary Rate and Cycle Performance as an Anode in Lithium-Ion and Sodium-Ion Half/Full Cells,” Journal of Colloid and Interface Science 607, no. Pt 2 (2022): 1153–1162.

[76]

Y. Lu, X. Hou, L. Miao, et al., “Cyclohexanehexone With Ultrahigh Capacity as Cathode Materials for Lithium-Ion Batteries,” Angewandte Chemie International Edition 58, no. 21 (2019): 7020–7024.

[77]

Y. Zhao, X. Li, B. Yan, et al., “Recent Developments and Understanding of Novel Mixed Transition-Metal Oxides as Anodes in Lithium Ion Batteries,” Advanced Energy Materials 6, no. 8 (2016): 1502175.

[78]

B. Ran, R. Cheng, Y. Zhong, et al., “High Entropy Activated and Stabilized Nickel-Based Prussian Blue Analogue for High-Performance Aqueous Sodium-Ion Batteries,” Energy Storage Materials 71 (2024): 103583.

[79]

Y. Liu, T. Liu, X. Wang, et al., “Subsurface Electron Trap Enabled Long-Cycling Oxalate-Based Li-CO2 Battery,” Advanced Materials 37, no. 39 (2025): e2507871.

[80]

B. S. Parimalam, A. D. MacIntosh, R. Kadam, and B. L. Lucht, “Decomposition Reactions of Anode Solid Electrolyte Interphase (SEI) Components With LiPF6,” Journal of Physical Chemistry C 121, no. 41 (2017): 22733–22738.

[81]

M. Dixit, B. Witherspoon, N. Muralidharan, et al., “Insights into the Critical Materials Supply Chain of the Battery Market for Enhanced Energy Security,” ACS Energy Letters 9, no. 8 (2024): 3780–3789.

[82]

Y. Zhang, H. Shen, Y. Li, Y. Hu, and Y. Li, “Prelithiation Strategies for Enhancing the Performance of Lithium-Ion Batteries,” RSC Advances 15, no. 2 (2025): 1249–1274.

[83]

Z. Li, J. Jin, Z. Yuan, and W. Yang, “Surface Modification of SiOx Film Anodes by Laser Annealing and Improvement of Cyclability for Lithium-Ion Batteries,” Materials Science in Semiconductor Processing 121 (2021): 105300.

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