PDF
Abstract
Due to its adsorption on graphite and superior thickening properties, carboxymethylcellulose (CMC) is widely used as a dispersant and rheology modifier in water-based anode slurries for lithium-ion batteries. CMC also provides cohesion to the dry anode layer but exhibits poor adhesion to the copper foil necessitating the addition of styrene-butadiene rubber (SBR) as an adhesion promoter. High adhesion between the electrode layer and the current collector is crucial in electrode fabrication, especially for electrodes with higher mass loadings. In this work, we investigate how a polymeric binder, originally intended as a thickening and dispersing agent, can significantly affect the adhesive strength between the anode layer and the current collector. Our results reveal that CMC, by adsorbing onto active material particles (graphite, micro-silicon or nano-silicon), indirectly influences the anode adhesion. The adsorbed CMC layer hinders the direct binding of SBR to the active material particles, thereby creating the weakest link between the active layer and the current collector. This effect is more pronounced the higher the CMC molecular weight. Moreover, we could show that graphite-nano-silicon composite anodes exhibit a significantly reduced adhesion to the copper foil despite a low adsorption of CMC on nano-silicon, since a large fraction of SBR particles are trapped in the porous, micron-sized nano-silicon aggregates. Our findings highlight the importance of considering thickener adsorption on active material particles within electrode design, as a factor that exerts an indirect, albeit significant, influence on anode adhesion.
Keywords
Adhesion
/
silicon anodes
/
CMC
/
SBR
/
polymeric binders
/
lithium-ion battery
Cite this article
Download citation ▾
Katarzyna Hofmann, Norbert Willenbacher.
How carboxymethylcellulose adsorption and porous active material particles diminish the adhesion of graphite-silicon anodes in lithium-ion batteries.
Energy Materials, 2025, 5(8): 500092 DOI:10.20517/energymater.2024.281
| [1] |
International Energy Agency (IEA), Paris, Global EV outlook 2024. Available from: https://www.iea.org/reports/global-ev-outlook-2024. [Last accessed on 14 Apr 2025]
|
| [2] |
Miao Y,von Jouanne A.Current Li-ion battery technologies in electric vehicles and opportunities for advancements.Energies2019;12:1074
|
| [3] |
Cholewinski A,Uceda M,Zhao B.Polymer binders: characterization and development toward aqueous electrode fabrication for sustainability.Polymers2021;13:631 PMCID:PMC7923802
|
| [4] |
Liu Y,Wang J.Current and future lithium-ion battery manufacturing.iScience2021;24:102332 PMCID:PMC8050716
|
| [5] |
Lestriez B.Functions of polymers in composite electrodes of lithium ion batteries.C R Chim2010;13:1341-50
|
| [6] |
Lopez CG,Colby RH,Cabral JT.Structure of sodium carboxymethyl cellulose aqueous solutions: a SANS and rheology study.J Polym Sci B Polym Phys2015;53:492-501 PMCID:PMC4681322
|
| [7] |
Lopez CG,Cabral JT.Electrostatic and hydrophobic interactions in NaCMC aqueous solutions: effect of degree of substitution.Macromolecules2018;51:3165-75
|
| [8] |
Lee J,Hackley VA.Effect of carboxymethyl cellulose on aqueous processing of natural graphite negative electrodes and their electrochemical performance for lithium batteries.J Electrochem Soc2005;152:A1763
|
| [9] |
Lim S,Yamamura M.Latex migration in battery slurries during drying.Langmuir2013;29:8233-44
|
| [10] |
Gordon R,Willenbacher N.Effect of carboxymethyl cellulose on the flow behavior of lithium-ion battery anode slurries and the electrical as well as mechanical properties of corresponding dry layers.J Mater Sci2020;55:15867-81
|
| [11] |
Jaiser S,Klaver J.Microstructure formation of lithium-ion battery electrodes during drying - an ex-situ study using cryogenic broad ion beam slope-cutting and scanning electron microscopy (Cryo-BIB-SEM).J Power Sources2017;345:97-107
|
| [12] |
Jaiser S,Baunach M,Scharfer P.Investigation of film solidification and binder migration during drying of Li-ion battery anodes.J Power Sources2016;318:210-9
|
| [13] |
Westphal BG.Critical electrode properties and drying conditions causing component segregation in graphitic anodes for lithium-ion batteries.J Energy Storage2018;18:509-17
|
| [14] |
Chen H,Hencz L.Exploring chemical, mechanical, and electrical functionalities of binders for advanced energy-storage devices.Chem Rev2018;118:8936-82
|
| [15] |
Petrie E.Adhesive bonding of textiles: principles, types of adhesive and methods of use. In: Joining Textiles Principles and Applications; Woodhead Publishing Series in Textiles; Elsevier, 2013; pp. 225-74.
|
| [16] |
Mcbain JW.On adhesives and adhesive action.J Phys Chem1925;29:188-204
|
| [17] |
Hofmann K,Liu-theato X,Smith A.Effect of mechanical properties on processing behavior and electrochemical performance of aqueous processed graphite anodes for lithium-ion batteries.J Power Sources2024;593:233996
|
| [18] |
Choi S,Coskun A.Highly elastic binders integrating polyrotaxanes for silicon microparticle anodes in lithium ion batteries.Science2017;357:279-83
|
| [19] |
Ye R,Tian J.Novel binder with cross-linking reconfiguration functionality for silicon anodes of lithium-ion batteries.ACS Appl Mater Interfaces2024;16:16820-9
|
| [20] |
Yu Y,Jiang Y,Zhang J.Consecutive covalent bonds reconstruct robust dual-interfaces by carbonized binder to enable conductive-additive-free durable silicon anode.Nano Energy2024;130:110108
|
| [21] |
Ren WF,Li JT.Improving the electrochemical property of silicon anodes through hydrogen-bonding cross-linked thiourea-based polymeric binders.ACS Appl Mater Interfaces2021;13:639-49
|
| [22] |
Xiang Y,Deng J,Nazir MA.Spiderweb-like three-dimensional cross-linked AGE binder for high performance silicon-based lithium battery.ACS Appl Energy Mater2025;8:2973-81
|
| [23] |
Kumberg J,Schmatz J.Reduced drying time of anodes for lithium-ion batteries through simultaneous multilayer coating.Energy Tech2021;9:2100367
|
| [24] |
Bak C,Lee H.Advanced multilayer model electrode for binder distribution within composite electrodes of lithium batteries.Chem Eng J2024;483:148913
|
| [25] |
Burger D,Shabbir J.Simultaneous primer coating for fast drying of battery electrodes.Energy Tech2025;13:2401668
|
| [26] |
Lee J,Hackley VA.Effect of poly(acrylic acid) on adhesion strength and electrochemical performance of natural graphite negative electrode for lithium-ion batteries.J Power Sources2006;161:612-6
|
| [27] |
Mori T.Effect of adsorption behaviour of polyelectrolytes on fluidity and packing ability of aqueous graphite slurries.Adv Powder Technol2017;28:280-7
|
| [28] |
Bridel J,Morcrette M,Larcher D.In situ observation and long-term reactivity of Si/C/CMC composites electrodes for Li-ion batteries.J Electrochem Soc2011;158:A750-9
|
| [29] |
Huang L,Li C,Lee J.Dispersion homogeneity and electrochemical performance of Si anodes with the addition of various water-based binders.J Electrochem Soc2018;165:A2239-46
|
| [30] |
Kim KJ.Effects of sodium carboxymethyl cellulose and poly (acrylic acid) on the agglomeration behavior of aqueous silicon suspensions.Colloids Surf A Physicochem Eng Asp2023;673:131801
|
| [31] |
Park JH,Ahn KH.Rheological behavior and microstructure formation of Si/C anode slurries for Li-ion batteries.Korea-Aust Rheol J2023;35:335-47
|
| [32] |
Kim B,Youn B.Dispersion homogeneity of silicon anode slurries with various binders for Li-ion battery anode coating.Polymers2023;15:1152 PMCID:PMC10007508
|
| [33] |
Haberzettl P,Vrankovic D.Processing of aqueous graphite-silicon oxide slurries and its impact on rheology, coating behavior, microstructure, and cell performance.Batteries2023;9:581
|
| [34] |
Andrews EH.Mechanics of adhesive failure. I.Proc R Soc Lond A1973;332:385-99
|
| [35] |
Kinloch AJ.Adhesion and adhesives: science and technology, 1th ed.; Springer Science & Business Media, 2087.
|
| [36] |
Y.K. Surface energy of crystalline and vitreous silica.Glass Ceram2000;57:374-7
|
| [37] |
Murdock AT,Britton J.Targeted removal of copper foil surface impurities for improved synthesis of CVD graphene.Carbon2017;122:207-16
|
| [38] |
Chang WJ,Cheon YJ.Direct observation of carboxymethyl cellulose and styrene-butadiene rubber binder distribution in practical graphite anodes for Li-ion batteries.ACS Appl Mater Interfaces2019;11:41330-7
|
| [39] |
Burdette-trofimov MK,Rogers AM.Understanding binder-silicon interactions during slurry processing.J Phys Chem C2020;124:13479-94
|
| [40] |
Kwon TW,Coskun A.The emerging era of supramolecular polymeric binders in silicon anodes.Chem Soc Rev2018;47:2145-64
|
| [41] |
Lee YM,Shim H,Park J.SEI layer formation on amorphous Si Thin electrode during precycling.J Electrochem Soc2007;154:A515
|
| [42] |
Hochgatterer NS,Koller S.Silicon/graphite composite electrodes for high-capacity anodes: influence of binder chemistry on cycling stability.Electrochem Solid-State Lett2008;11:A76
|
| [43] |
Mazouzi D,Roué L.Silicon composite electrode with high capacity and long cycle life.Electrochem Solid-State Lett2009;12:A215
|
| [44] |
Zhang Q,Gu M.Dispersion and rheological properties of concentrated silicon aqueous suspension.Powder Technol2006;161:130-4
|
| [45] |
Vogl US,Weber AZ,Kostecki R.Mechanism of interactions between CMC binder and Si single crystal facets.Langmuir2014;30:10299-307
|
| [46] |
Bitsch B. Verwendung von kapillarsuspensionen zur prozessierung von lithium-ionen batterieelektroden. Ph.D. Dissertation, Karlsruher Institut für Technologie (KIT), Karlsruhe,Germany, 2017. Available from: https://publikationen.bibliothek.kit.edu/1000064637. [Last accessed on 15 Apr 2025]
|
| [47] |
Salini PS,Kalpakasseri A,Thelakkattu Devassy M.Toward greener and sustainable Li-ion cells: an overview of aqueous-based binder systems.ACS Sustain Chem Eng2020;8:4003-25
|
