SiO2 Based Composites For Lithium Ion Battery Anodes: A Review

Authors

  • Yayuk Astuti Chemistry Department, Faculty of Sciences and Mathematics, Universitas Diponegoro, Central Java 50275, Indonesia
  • Yurike Candra Sefia Chemistry Department, Faculty of Sciences and Mathematics, Universitas Diponegoro, Central Java 50275, Indonesia
  • Iis Nurhasanah Physics Department, Faculty of Science and Mathematics, Universitas Diponegoro, Central Java 50275, Indonesia

DOI:

https://doi.org/10.48048/tis.2026.13129

Keywords:

Lithium-ion battery, SiO2 materials, SiO2 anode, SiO2/C composite, SiO2/metal composite, Lithium-Ion battery, SiO2 materials, SiO2 anode, SiO2/C composite, SiO2/metal composite

Abstract

The application of SiO2 as a lithium-ion battery anode material has attracted attention due to its higher theoretical capacity compared to commercial carbon, low discharge potential, and abundance in nature. However, SiO2 has limitations that restrict its widespread use as an anode due to its low electrical conductivity and volume expansion during cycling. Modifying the properties of SiO₂ using other materials as composites is an effective strategy to overcome these limitations. In this review, the progress and role of SiO2-based composites in improving electrochemical performance will be discussed. First, we briefly discuss the development and sources of SiO2 material as a lithium-ion battery anode. In addition, the mechanism of lithium storage and the challenges faced in the application of SiO2 anodes are discussed by reviewing solutions to overcome them, including modifications to the nano and porous structure of SiO2. Furthermore, the review focuses on the application and development of SiO2-based composites in improving the electrochemical performance of lithium-ion batteries to provide an overview of the challenges and prospects for the development of SiO2 anodes in lithium-ion batteries.

HIGHLIGHTS

  • SiO2 is an alternative material that is abundant in nature, inexpensive, and has low toxicity.
  • SiO2 has poor electrical conductivity, which poses a challenge for its application as a battery anode.
  • The electrochemical performance of SiO2 anodes can be improved by modifying the nano structure, particle and pore size, SiO2 composition, and the material synthesis method.

GRAPHICAL ABSTRACT

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References

P Lv, H Zhao, J Wang, X Liu, T Zhang and Q Xia. Facile preparation and electrochemical properties of amorphous SiO2/C composite as anode material for lithium ion batteries. Journal of Power Sources 2013; 237, 291-294.

KM Abraham. How comparable are sodium-ion batteries to lithium-ion counterparts? ACS Energy Letters 2020; 5(11), 3544-3547.

B Dunn, H Kamath and JM Tarascon. Electrical energy storage for the grid: A battery of choices. Science 2011; 334(6058), 928-935.

K Askaruly, M Yeleuov, A Taurbekov, B Sarsembayeva, A Tolynbekov, N Zhylybayeva, S Azat, A Abdisattar and C Daulbayev. A facile synthesis of graphite-coated amorphous SiO2 from biosources as anode material for libs. Materials Today Communications 2023; 34, 105136.

P Slowik, N Lutsey and CW Hsu. How technology, recycling, and policy can mitigate supply risks to the long-term transition to zero-emission vehicles. International Council on Clean Transportation 2020. https://doi.org/10.13140/RG.2.2.30613.35041

S Cui, S Chen and L Deng. Si nanoparticles encapsulated in CNTs arrays with tubular sandwich structure for high performance Li ion battery. Ceramics International 2020; 46(3), 3242-3249.

M Jiao, K Liu, Z Shi and C Wang. SiO2/Carbon composite microspheres with hollow core - shell structure as a high‐stability electrode for lithium‐ion batteries. ChemElectroChem 2017; 4(3), 542-549.

S Wang, N Zhao, C Shi, E Liu, C He, F He and L Ma. In-situ grown CNTs modified SiO2/C composites as anode with improved cycling stability and rate capability for lithium storage. Applied Surface Science 2018; 433, 428-436.

RR Arulanantham, AD Savariraj and V Ragupathi. MXene-Metal oxide composites: Prospectus, progress and challenges as anode material for lithium-ion batteries. Journal of Alloys and Compounds 2025; 1022, 179761.

E Feyzi, AKMR, X Li, S Deng, J Nanda and K Zaghib. A comprehensive review of silicon anodes for high-energy lithium-ion batteries: Challenges, latest developments, and perspectives. Next Energy 2024; 5, 100176.

YM Peralta, R Molina and S Moreno. Rice HUSK silica: A review from conventional uses to new catalysts for advanced oxidation processes. Journal of Environmental Management 2024; 370, 122735.

F Adam, JN Appaturi and A Iqbal. The utilization of rice husk silica as a catalyst: Review and recent progress. Catalysis Today 2012; 190(1), 2-14.

AJG Lunt, P Chater and AM Korsunsky. On the origins of strain inhomogeneity in amorphous materials. Scientific Reports 2018; 8(1), 1-9.

PU Nzereogu, AD Omah, FI Ezema, EI Iwuoha and AC Nwanya. Silica extraction from rice husk: Comprehensive review and applications. Hybrid Advances 2023; 4, 100111.

H Maleki, L Durães, CA García-González, P del Gaudio, A Portugal and M Mahmoudi. Synthesis and biomedical applications of aerogels: Possibilities and challenges. Advances in Colloid and Interface Science 2016; 236, 1-27.

H Liu, W Sha, AT Cooper and M Fan. Preparation and characterization of a novel silica aerogel as adsorbent for toxic organic compounds. Colloids and Surfaces A: Physicochemical and Engineering Aspects 2009; 347(1-3), 38-44.

Z Shariatinia and A Esmaeilzadeh. Hybrid silica aerogel nanocomposite adsorbents designed for Cd(II) removal from aqueous solution. Water Environment Research 2019; 91(12), 1624-1637.

NH Embong, N Hindryawati, P Bhuyar, N Govindan, MHA Rahim and GP Maniam. Enhanced biodiesel production via esterification of palm fatty acid distillate (PFAD) using rice husk ash (NiSO4)/SiO2 catalyst. Applied Nanoscience 2023; 13(3), 2241-2249.

DJ Boday, B Muriithi, RJ Stover and DA Loy. Polyaniline nanofiber-silica composite aerogels. Journal of Non-Crystalline Solids 2012; 358(12-13), 1575-1580.

H Wang, P Wu, H Shi, W Tang, Y Tang, Y Zhou, P She and T Lu. Hollow porous silicon oxide nanobelts for high-performance lithium storage. Journal of Power Sources 2015; 274, 951-956.

X Zhang, K Li, Y Li, J Liu, J Dai, Y Li and F Ai. Facile fabrication of SiO2 nanotubes coated with nitrogen-doped carbon layers as high-performance anodes for lithium-ion batteries. Ceramics International 2021; 47(1), 1373-1380.

H Mi, X Yang, Y Li, P Zhang and L Sun. A self-sacrifice template strategy to fabricate yolk-shell structured silicon@void@carbon composites for high-performance lithium-ion batteries. Chemical Engineering Journal 2018; 351, 103-109.

WS Chang, CM Park, JH Kim, YU Kim, G Jeong and HJ Sohn. Quartz (SiO2): A new energy storage anode material for Li-ion batteries. Energy and Environmental Science 2012; 5(5), 6895.

B Gao, S Sinha, L Fleming and O Zhou. Alloy formation in nanostructured silicon. Advanced Materials 2001; 13(11), 816-819.

Y Wang, K Xie, X Guo, W Zhou, G Song and S Cheng. Mesoporous silica nanoparticles as high performance anode materials for lithium-ion batteries. New Journal of Chemistry 2016; 40(10), 8202-8205.

M Khan, S Yan, M Ali, F Mahmood, Y Zheng, G Li, J Liu, X Song and Y Wang. Innovative solutions for high-performance silicon anodes in lithium-ion batteries: Overcoming challenges and real-world applications. Nano-Micro Letters 2024; 16(1), 179.

M Saleem, U Lassi, V Srivastava and S Tuomikoski. A review of silicon-carbon anode materials: The role of precursor and its effect on lithium-ion battery performance. Journal of Power Sources 2025; 641, 236879.

Y Zhao, Z Liu, Y Zhang, A Mentbayeva, X Wang, MY Maximov, B Liu, Z Bakenov and F Yin. Facile synthesis of SiO2@C nanoparticles anchored on MWNT as high-performance anode materials for Li-ion batteries. Nanoscale Research Letters 2017; 12(1), 459.

N Yan, F Wang, H Zhong, Y Li, Y Wang, L Hu and Q Chen. Hollow porous SiO2 nanocubes towards high-performance anodes for lithium-ion batteries. Scientific Reports 2013; 3(1), 1568.

L Cao, J Huang, Z Lin, X Yu, X Wu, B Zhang, Y Zhan, F Xie, W Zhang, J Chen and H Meng. Amorphous SiO2/C composite as anode material for lithium-ion batteries. Journal of Materials Research 2018; 33(9), 1219-1225.

J Tu, Y Yuan, P Zhan, H Jiao, X Wang, H Zhu and S Jiao. Straightforward approach toward SiO2 nanospheres and their superior lithium storage performance. Journal of Physical Chemistry C 2014; 118(14), 7357-7362.

CO Tuck, E Pérez, IT Horváth, RA Sheldon and M Poliakoff. Valorization of biomass: Deriving more value from waste. Science 2012; 337(6095), 695-699.

J Cui, F Cheng, J Lin, J Yang, K Jiang, Z Wen and J Sun. High surface area C/SiO2 composites from rice husks as a high-performance anode for lithium ion batteries. Powder Technology 2017; 311, 1-8.

A Su, J Li, J Dong, D Yang, G Chen and Y Wei. An amorphous/crystalline incorporated Si/SiOx anode material derived from biomass corn leaves for lithium‐ion batteries. Small 2020; 16(24), 2001714.

H Xu, S Zhang, W He, X Zhang, G Yang, J Zhang, X Shi and L Wang. SiO2-carbon nanocomposite anodes with a 3D interconnected network and porous structure from bamboo leaves. RSC Advances 2016; 6(3), 1930-1937.

A Daulay, Andriayani, Marpongahtun and S Gea. Synthesis and application of silicon nanoparticles prepared from rice husk for lithium-ion batteries. Case Studies in Chemical and Environmental Engineering 2022; 6, 100256.

L Zhang, K Shen, W He, Y Liu and S Guo. SiO2@graphite composite generated from sewage sludge as anode material for lithium ion batteries. International Journal of Electrochemical Science 2017; 12(11), 10221-10229.

A Jumari, CS Yudha, H Widiyandari, AP Lestari, RA Rosada, SP Santosa and A Purwanto. SiO2/C composite as a high capacity anode material of LiNi0.8Co0.15Al0.05O2 battery derived from coal combustion fly ash. Applied Sciences 2020; 10(23), 8428.

A Prasath and P Elumalai. Extraction of nanostructured SiO2 from glass waste: A potential anode source for lithium-ion batteries. ChemistrySelect 2016; 1(12), 3363-3366.

H Widiyandari, AS Wijareni, R Ardiansyah, B Purnama and A Purwanto. Preparation of anode active material by utilizing of silica from geothermal sludge for li-ion battery application, Available at: https://ecommons.cornell.edu/server/api/core/bitstreams/bf6a3e9f-a204-4afb-819a-c472fbd2ff10/content

K Thangaian, A Gaarud, IE Nylund and MV Blanco. Self-driven SiO2/C nanocomposites from cultured diatom microalgae for sustainable Li-ion battery anodes: The role of impurities. ACS Sustainable Resource Management 2024; 1(10), 2284-2293.

H Huang, E Kelder, L Chen and J Schoonman. Electrochemical characteristics of Sn1−xSixO2 as anode for lithium-ion batteries. Journal of Power Sources 1999; 81-82, 362-367.

C Ban, BB Kappes, Q Xu, C Engtrakul, CV Ciobanu, AC Dillon and Y Zhao. Lithiation of silica through partial reduction. Applied Physics Letters 2012; 100(24), 243905.

CY Chou and GS Hwang. Lithiation behavior of silicon-rich oxide (SiO1/3): A first-principles study. Chemistry of Materials 2024; 25(17), 3435-3440.

Y Zhang, Y Li, Z Wang and K Zhao. Lithiation of SiO2 in Li-ion batteries: In situ transmission electron microscopy experiments and theoretical studies. Nano Letters 2014; 14(12), 7161-7170.

A Ostadhossein, SY Kim, ED Cubuk, Y Qi and ACT Van Duin. Atomic insight into the lithium storage and diffusion mechanism of SiO2/Al2O3 electrodes of lithium ion batteries: ReaxFF reactive force field modeling. Journal of Physical Chemistry A 2016; 120(13), 2114-2127.

II Abate, CJ Jia, B Moritz and TP Devereaux. Ab initio molecular dynamics study of SiO2 lithiation. Chemical Physics Letters 2020; 739, 136933.

Y Jiang, F Zhao, X Wu, L Zeng, L Yang, L Guan, Y Ren, X Zhou and Z Liu. Elucidation on abnormal capacity increase in SiO2@C core-shell nanospheres anode for lithium-ion battery. Langmuir 2024; 40(38), 20261-20272.

MR Babaa, A Moldabayeva, M Karim, A Zhexembekova, Y Zhang, Z Bakenov, A Molkenova and I Taniguchi. Development of a novel SiO2 based composite anode material for Li-ion batteries. Materials Today: Proceedings 2017; 4(3), 4542-4547.

C Zhao, Z Yang, X Zhou, Z Hao, J Chen, Z Wang, X Chen, X Wu, L Li, L Li, L Jiao and S Chou. Recent progress on electrolyte boosting initial coulombic efficiency in lithium‐ion batteries. Advanced Functional Materials 2024; 34(5), 2303457.

X Li, X Sun, X Hu, F Fan, S Cai, C Zheng and GD Stucky. Review on comprehending and enhancing the initial Coulombic efficiency of anode materials in lithium-ion/sodium-ion batteries. Nano Energy 2020; 77, 105143.

L Zhang, H Guo, R Rajagopalan, X Hu, Y Huang, SX Dou and HK Liu. One-step synthesis of a silicon/hematite@carbon hybrid nanosheet/silicon sandwich-like composite as an anode material for Li-ion batteries. Journal of Materials Chemistry A 2016; 4(11), 4056-4061.

H Xia, Z Yin, F Zheng and Y Zhang. Facile synthesis of SiO2/C composites as anode materials for lithium-ion batteries. Materials Letters 2017; 205, 83-86.

Y Wu, M Li, B Liu, Y Ren and X Ding. Silica gel combing with zinc nanoparticles as high-rate and long-cycle anodes for lithium-ion batteries. Journal of Physics and Chemistry of Solids 2025; 199, 112538.

S Ozen, O Eroglu and N Karatepe. Electrochemically pre-lithiated SiO2@C nanocomposite anodes for improved performance in lithium-ion batteries. Nanotechnology 2023; 34(48), 485403.

K Xu, X Liu, K Guan, Y Yu, W Lei, S Zhang, Q Jia and H Zhang. Research progress on coating structure of silicon anode materials for lithium‐ion batteries. ChemSusChem 2021; 14(23), 5135-5160.

MS Al Ja’farawy, DN Hikmah, U Riyadi, A Purwanto and H Widiyandari. A review: The development of SiO2/C anode materials for lithium-ion batteries. Journal of Electronic Materials 2021; 50(12), 6667-6687.

R Tian, N Alcala, SJK O'Neill, DV Horvath, J Coelho, AJ Griffin, Y Zhang, V Nicolosi, C O'Dwyer and JN Coleman. Quantifying the Effect of Electronic Conductivity on the Rate Performance of Nanocomposite Battery Electrodes. ACS Applied Energy Materials 2020; 3(2), 2966–2974.

R Scipioni, L Stixrude and MP Desjarlais. Electrical conductivity of SiO2 at extreme conditions and planetary dynamos. Proceedings of the National Academy of Sciences 2017; 114(34), 9009-9013.

X Ma, Z Wei, H Han, X Wang, K Cui and L Yang. Tunable construction of multi-shell hollow SiO2 microspheres with hierarchically porous structure as high-performance anodes for lithium-ion batteries. Chemical Engineering Journal 2017; 323, 252-259.

Z Yuan, N Zhao, C Shi, E Liu, C He and F He. Synthesis of SiO2/3D porous carbon composite as anode material with enhanced lithium storage performance. Chemical Physics Letters 2016; 651, 19-23.

HH Li, XL Wu, HZ Sun, K Wang, CY Fan, LL Zhang, FM Yang and JP Zhang. Dual-porosity SiO2/C nanocomposite with enhanced lithium storage performance. Journal of Physical Chemistry C 2015; 119(7), 3495-3501.

MB Naikwade, PK Katkar and SW Lee. Understanding the impact of porosity on Li-ion diffusion enhancement in micro-sized silicon particles for advanced batteries. Ceramics International 2024; 50(24), 54778-54790.

J Grill and J Popovic-Neuber. Long term porosity of solid electrolyte interphase on model silicon anodes with liquid battery electrolytes. Communications Chemistry 2024; 7(1), 1-8.

S Suh, S Han, H Yoon, H Kim, J Kang, C Pak and HJ Kim. Facile one-step fabrication of 3-dimensional SiO2-C electrodes for lithium-ion batteries using a highly porous SBA-15 template and pore-forming agent. Electronic Materials Letters 2022; 18(2), 187-196.

S Huang, D Yang, W Zhang, X Qiu, Q Li and C Li. Dual-templated synthesis of mesoporous lignin-derived honeycomb-like porous carbon/SiO2 composites for high-performance Li-ion battery. Microporous and Mesoporous Materials 2021; 317, 111004.

X Wu, Z Shi, C Wang and J Jin. Nanostructured SiO2/C composites prepared via electrospinning and their electrochemical properties for lithium ion batteries. Journal of Electroanalytical Chemistry 2015; 746, 62-67.

D Wang, M Gao, H Pan, J Wang and Y Liu. High performance amorphous-Si@SiO/C composite anode materials for Li-ion batteries derived from ball-milling and in situ carbonization. Journal of Power Sources 2014; 256, 190-199.

Y Yao, J Zhang, L Xue, T Huang and A Yu. Carbon-coated SiO2 nanoparticles as anode material for lithium ion batteries. Journal of Power Sources 2011; 196(23), 10240-10243.

X Lan, X Zhou, Jiao Z, H Zong, P Zhang, B Xu and Y Wang. SiO2 nanoparticles anchored on hollow porous carbon shells for high stability lithium-ion battery anodes. Journal of Alloys and Compounds 2024; 972, 172783.

X Zhang, J Weng, C Ye, M Liu, C Wang, S Wu, Q Tong, M Zhu and F Gao. Strategies for controlling or releasing the influence due to the volume expansion of silicon inside Si−C composite anode for high-performance lithium-ion batteries. Materials 2022; 15(12), 4264.

SJ Kim, SJ Ha, JU Lee, YP Jeon and JY Hong. Preparation of silicon oxide-carbon composite with tailored electrochemical properties for anode in lithium-ion batteries. C 2023; 9(4), 114.

MR Buga, AA Spinu-Zaulet, CG Ungureanu, RA Mitran, E Vasile, M Florea and F Neatu. Carbon-coated SiO2 composites as promising anode material for Li-ion batteries. Molecules 2021; 26(15), 4531.

X Dong, C Woo, S Oh, Y Kim, X Zhang, KI Kim, KH Choi, J Kang, J Jeon, HS Bang, HS Oh, HK Yu, J Mun and JY Choi. Effect of carbonization temperature on the electrochemical performance of monodisperse Carbon/SiO2 nanocomposites as lithium-ion batteries anode. Journal of Power Sources 2025; 631, 236291.

S Butcha, P Paiplod, C Srisomwat, A Saengsrichan, S Youngjan, J Phanthasri, T Butburee and P Khemthong. Facile synthesis of SiO2/C composites derived from rice straw as high-performance anodes for lithium-ion batteries. Diamond and Related Materials 2025; 152, 112000.

L Chu, C Yun, X Haohui, X Yang, H Xianhua, G Yongping, M Xiaochun, T Xinyong, H Hui, J Zhang, W Han and W Zhang. Embedding submicron SiO2 into porous carbon as advanced lithium-ion batteries anode with ultralong cycle life and excellent rate capability. Journal of the Taiwan Institute of Chemical Engineers 2019; 95, 227-233.

S Ali, S Jaffer, I Maitlo, FK Shehzad, Q Wang, S Ali, MY Akram, Y He and J Nie. Photo cured 3D porous silica-carbon (SiO2-C) membrane as anode material for high performance rechargeable Li-ion batteries. Journal of Alloys and Compounds 2020; 812, 152127.

Y Ren, H Wei, X Huang and J Ding. A facile synthesis of SiO2@C@graphene composites as anode material for lithium ion batteries. International Journal of Electrochemical Science 2014; 9(12), 7784-7794.

L Wang, X Zhu, K Tu, D Liu, H Tang, J Li, X Li, Z Xie and D Qu. Synthesis of carbon-SiO2 hybrid layer @ SiO2 @ CNT coaxial nanotube and its application in lithium storage. Electrochimica Acta 2020; 354, 136726.

Y Hyun, JY Choi, HK Park, JY Bae and CS Lee. Synthesis and electrochemical performance of mesoporous SiO2-carbon nanofibers composite as anode materials for lithium secondary batteries. Materials Research Bulletin 2016; 82, 92-101.

A Belgibayeva and I Taniguchi. Synthesis and characterization of SiO2/C composite nanofibers as free-standing anode materials for Li-ion batteries. Electrochimica Acta 2019; 328, 135101.

L Li, P Liu, K Zhu, J Wang, G Tai and J Liu. Flexible and robust N-doped carbon nanofiber film encapsulating uniformly silica nanoparticles: Free-standing long-life and low-cost electrodes for Li- and Na-Ion batteries. Electrochimica Acta 2017; 235, 79-87.

N Sun, X Wang, X Dong, H Huang and M Qi. PVP-grafted synthesis for uniform electrospinning silica@carbon nanofibers as flexible free-standing anode for Li-ion batteries. Solid State Ionics 2022; 374, 115817.

JF Ma, K Tamai, N Yamaji, N Mitani, S Konishi, M Katsuhara, M Ishiguro, Y Murata, M Yano. A silicon transporter in rice. Nature 2006; 440(7084), 688-691.

L Wang, J Xue, B Gao, P Gao, C Mou and J Li. Rice husk derived carbon-silica composites as anodes for lithium ion batteries. RSC Advances 2014; 4(110), 64744-64746.

H Chu, Q Wu and J Huang. Rice husk derived silicon/carbon and silica/carbon nanocomposites as anodic materials for lithium-ion batteries. Colloids and Surfaces A: Physicochemical and Engineering Aspects 2018; 558, 495-503.

L Zhang, Z Wang, L Wang, Y Xing, X Li and Y Zhang. Electrochemical performance of ZnWO4/CNTs composite as anode materials for lithium-ion battery. Applied Surface Science 2014; 305, 179-185.

D Shen, C Huang, L Gan, J Liu, Z Gong and M Long. Rational design of Si@SiO2/C composites using sustainable cellulose as a carbon resource for anodes in lithium-ion batteries. ACS Applied Materials and Interfaces 2018; 10(9), 7946-7954.

JW Jung, CL Lee, S Yu and ID Kim. Electrospun nanofibers as a platform for advanced secondary batteries: A comprehensive review. Journal of Materials Chemistry A 2016; 4(3), 703-750.

X Wang, N Sun, X Dong, M Qi and H Huang. Preparation of a SiO2@Carbon Sphere/SiO2−CNF multilayer self-standing anode prepared via an alternate electrospraying – electrospinning technique. Chemistry - An Asian Journal 2023; 18(6), e202201198.

G Mu, D Mu, B Wu, C Ma, J Bi, L Zhang, H Yang and F Wu. Microsphere-like SiO2/MXene hybrid material enabling high performance anode for lithium ion batteries. Small 2020; 16(3), 1905430.

C Tang, Y Liu, C Xu, J Zhu, X Wei, L Zhou, L He, W Yang and L Mai. Ultrafine nickel‐nanoparticle‐enabled SiO2 hierarchical hollow spheres for high‐performance lithium storage. Advanced Functional Materials 2018; 28(3), 1704561.

H Wang, X Yang, Q Wu, Q Zhang, H Chen, H Jing, J Wang, SB Mi, AL Rogach and C Niu. Encapsulating silica/antimony into porous electrospun carbon nanofibers with robust structure stability for high-efficiency lithium storage. ACS Nano 2018; 12(4), 3406-3416.

Q Li, J Zhao, W Yao, C Yu and X Ding. A SiO2@Al as stable and long-cycle anode for lithium-ion batteries. Materials Chemistry and Physics 2023; 305, 128015.

Q Zhong, X Yang, Z Miao, L Liu, Y Xu, YX Meng, Z Yang and J Yu. SiO2/Co encapsulated in N-doped carbon nanofibers as anode materials for lithium-ion batteries. Materials Today Chemistry 2024; 35, 101919.

Q Zhong, K Zhou, Z Yang and J Yu. ZIF-67-derived Co/N-C hollow nanocubes@SiO2 composite for high performance lithium-ion batteries. Journal of Energy Storage 2024; 97, 112784.

J Lin, C Xu, M Lu, X Lin, Z Ali, C Zeng, X Xu and Y Luo. Trimetallic metal-organic framework nanoframe superstructures: A stress-buffering architecture engineering of anode material toward boosted lithium storage performance. Energy and Environmental Materials 2023; 6(1), e12284.

M Wen, L Yu, S Nie and W Xiao. Improved electrochemical performance of Cu-Sn/nano-SiO2 composite anode materials for lithium-ion batteries fabricated by controlled electrodeposition. Electrochimica Acta 2024; 496, 144548.

X Chen, Z Chen, H Xiao, H Wang, W Chen, C Chen and D Sun. Enhancing long-term cycling stability of lithium-ion batteries with prelithiated MXene@SiO2 anodes. International Journal of Electrochemical Science 2023; 18(9), 100232.

M Zhang, L Li, X Jian, S Zhang, Y Shang, T Xu, S Dai, J Xu, D Kong, Y Wang and X Wang. Free-standing and flexible CNT/(Fe@Si@SiO2) composite anodes with kernel-pulp-skin nanostructure for high-performance lithium-ion batteries. Journal of Alloys and Compounds 2021; 878, 160396.

Q Tian, Y Chen, F Chen, W Zhang, J Chen and L Yang. Etching-free template synthesis of double-shelled hollow SiO2@SnO2@C composite as high performance lithium-ion battery anode. Journal of Alloys and Compounds 2019; 809, 151793.

Z Zhang, H Zhao, Z Zeng, C Gao, J Wang and Q Xia. Hierarchical architectured NiS@SiO2 nanoparticles enveloped in graphene sheets as anode material for lithium ion batteries. Electrochimica Acta 2015; 155, 85-92.

P Lu, Z Zhang, M Yang, J Wu, L Chen and W Xue. Efficient synthesis and lithium storage performance of SiO2/TiO2 composite film anode by plasma electrolytic oxidation. Materials Letters 2024; 371, 136902.

M Ding, X Miao, L Cao, C Zhang and Y Ping. Core-shell nanostructured SiO2@a-TiO2@Ag composite with high capacity and safety for Li-ion battery anode. Materials Letters 2022; 308, 131276.

Y Li, H Shao, Z Lin, J Lu, L Liu, B Duployer, POÅ Persson, P Eklund, L Hultman, M Li, K Chen, XH Zha, S Du, P Rozier, Z Chai, E Raymundo-Piñero, PL Taberna, P Simon and Q Huang. A general Lewis acidic etching route for preparing MXenes with enhanced electrochemical performance in non-aqueous electrolyte. Nature Materials 2020; 19(8), 894-899.

Y Yan, X Zhao, H Dou, J Wei, Z Sun, YS He, Q Dong, H Xu and X Yang. MXene frameworks promote the growth and stability of LiF-rich solid - electrolyte interphases on silicon nanoparticle bundles. ACS Applied Materials and Interfaces 2020; 12(16), 18541-18550.

D Wang, Q Ma, X Li, Y Yu, Z Wang, Y Liu and C Liu. Coupling ultrafine SiO2 nanoparticles with three-dimensional porous Ti3C2Tx MXene as anode materials for high-performance lithium-ion batteries. Diamond and Related Materials 2023; 139, 110379.

S Zhao, R Nivetha, Y Qiu and X Guo. Two-dimensional hybrid nanomaterials derived from MXenes (Ti3C2T) as advanced energy storage and conversion applications. Chinese Chemical Letters 2020; 31(4), 947-952.

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2026-04-25

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Astuti, Y., Sefia, Y. C., & Nurhasanah, I. (2026). SiO2 Based Composites For Lithium Ion Battery Anodes: A Review. Trends in Sciences, 23(9), 13129. https://doi.org/10.48048/tis.2026.13129

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Vol. 23 No. 9 (2026): Trends in Sciences, Volume 23, Number 9, September 2026 (Upcoming Issue)

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Review Articles

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