Abstract
Electrocatalysts have a key role in the reactions of vanadium redox flow batteries (VRFB). A practical immersion-drying method is used to decorate graphene on graphite felt electrodes. Cyclic voltammograms illustrate that graphene plays an effective role in the formation and stability of redox peaks. Also, voltammograms show the rate capability of modified felts is enhanced remarkably, further confirmed by reduced charge transfer resistance obtained from electrochemical impedance spectroscopy. The results of cycling in a homemade battery show that the discharge capacity in the first cycle for the modified sample and the bare sample is equal to 1154 and 1244 mAh, respectively. The discharge energy density for the modified sample in the first cycle is about 1.17 Wh L−1 more than that of the bare one. The power of the battery containing the modified sample is 3.76 W, which is 0.12 W more than that of the battery containing the bare one, which is a result of the higher voltage of the battery with modified electrodes. The cycling stability of the modified electrodes has improved the voltage and energy efficiency of the battery containing them by 3% compared to the bare sample. Graphene has made these improvements by providing more surface area for redox reactions, creating a conductive network, and adding electrocatalytic properties to the graphite felt. The presented simple, inexpensive, and scalable method for decorating graphene on graphite felt is suitable for both positive and negative electrodes and can enhance high-rate charging and discharging capabilities of vanadium batteries.
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The supporting data regarding the findings of this study are accessible from the corresponding author upon reasonable request.
References
Loghavi MM, Zarei-Jelyani M, Niknam Z, Babaiee M, Eqra R (2022) Antimony-decorated graphite felt electrode of vanadium redox flow battery in mixed-acid electrolyte: promoting electrocatalytic and gas-evolution inhibitory properties. J Electroanal Chem 908:116090
Zarei-Jelyani M, Baktashian S, Babaiee M, Eqra R (2018) Improved mechanical and electrochemical properties of artificial graphite anode using water-based binders in lithium-ion batteries. J Renewable Energy Environ 5(4):34–39
Sarshar M, Zarei-Jelyani M, Babaiee M (2018) Application of semi empirical and multiphysics models in simulating lithium ion battery operation. Proc 10th Int Chem Eng Congress and Expo
Moghim MH, Eqra R, Babaiee M, Zarei-Jelyani M, Loghavi MM (2017) Role of reduced graphene oxide as nano-electrocatalyst in carbon felt electrode of vanadium redox flow battery. J Electroanal Chem 789:67–75
Zarei-Jelyani M, Loghavi MM, Babaiee M, Eqra R (2023) The significance of charge and discharge current densities in the performance of vanadium redox flow battery. Electrochim Acta 141922
Jelyani MZ, Rashid-Nadimi S, Asghari S (2017) Treated carbon felt as electrode material in vanadium redox flow batteries: a study of the use of carbon nanotubes as electrocatalyst. J Solid State Electrochem 21(1):69–79
Pezeshki AM, Clement JT, Veith GM, Zawodzinski TA, Mench MM (2015) High performance electrodes in vanadium redox flow batteries through oxygen-enriched thermal activation. J Power Sources 294:333–338
Sun B, Skyllas-Kazacos M (1992) Modification of graphite electrode materials for vanadium redox flow battery application—I. Thermal treatment Electrochim Acta 37(7):1253–1260
Sun B, Skyllas-Kazacos M (1992) Chemical modification of graphite electrode materials for vanadium redox flow battery application—part II. Acid treatments Electrochim Acta 37(13):2459–2465
Hassan A, Tzedakis T (2019) Enhancement of the electrochemical activity of a commercial graphite felt for vanadium redox flow battery (VRFB), by chemical treatment with acidic solution of K2Cr2O7. J Energy Storage 26:100967
Zarei-Jelyani M, Babaiee M, Ghasemi A, Eqra R (2016) Investigation of hydroxylated carbon felt electrode in vanadium redox flow battery by using optimized supporting electrolyte. J Renewable Energy Environ 3(4):54–59
Hu G, Jing M, Wang D-W, Sun Z, Xu C, Ren W et al (2018) A gradient bi-functional graphene-based modified electrode for vanadium redox flow batteries. Energy Storage Mater 13:66–71
Opar DO, Nankya R, Lee J, Jung H (2020) Assessment of three-dimensional nitrogen-doped mesoporous graphene functionalized carbon felt electrodes for high-performance all vanadium redox flow batteries. Appl Surf Sci 531:147391
Shi L, Liu S, He Z, Shen J (2014) Nitrogen-doped graphene: effects of nitrogen species on the properties of the vanadium redox flow battery. Electrochim Acta 138:93–100
Gürsu H, Gençten M, Şahin Y (2018) Preparation of N-doped graphene-based electrode via electrochemical method and its application in vanadium redox flow battery. Int J Energy Res 42(12):3851–3860
Daugherty MC, Gu S, Aaron DS, Kelly RE, Gandomi YA, Hsieh C-T (2020) Graphene quantum dot-decorated carbon electrodes for energy storage in vanadium redox flow batteries. Nanoscale 12(14):7834–7842
Gursu H, Gencten M, Sahin Y (2018) Preparation of sulphur-doped graphene-based electrodes by cyclic voltammetry: a potential application for vanadium redox flow battery. Int J Electrochem Sci 13:875–885
Daugherty MC, Gu S, Aaron DS, Mallick BC, Gandomi YA, Hsieh C-T (2020) Decorating sulfur and nitrogen co-doped graphene quantum dots on graphite felt as high-performance electrodes for vanadium redox flow batteries. J Power Sources 477:228709
Li Q, Bai A, Xue Z, Zheng Y, Sun H (2020) Nitrogen and sulfur co-doped graphene composite electrode with high electrocatalytic activity for vanadium redox flow battery application. Electrochim Acta 362:137223
Park M, Jeon I-Y, Ryu J, Jang H, Back J-B, Cho J (2016) Edge-halogenated graphene nanoplatelets with F, Cl, or Br as electrocatalysts for all-vanadium redox flow batteries. Nano Energy 26:233–240
Gürsu H, Gençten M, Şahin Y (2018) Cyclic voltammetric preparation of graphene-coated electrodes for positive electrode materials of vanadium redox flow battery. Ionics 24(11):3641–3654
Nia PM, Abouzari-Lotf E, Woi PM, Alias Y, Ting TM, Ahmad A et al (2019) Electrodeposited reduced graphene oxide as a highly efficient and low-cost electrocatalyst for vanadium redox flow batteries. Electrochim Acta 297:31–39
Jing M, Zhang C, Qi X, Yang Y, Liu J, Fan X et al (2020) Gradient-microstructural porous graphene gelatum/flexible graphite plate integrated electrode for vanadium redox flow batteries. Int J Hydrogen Energy 45(1):916–923
Sankar A, Michos I, Dutta I, Dong J, Angelopoulos AP (2018) Enhanced vanadium redox flow battery performance using graphene nanoplatelets to decorate carbon electrodes. J Power Sources 387:91–100
Xia L, Zhang Q, Wu C, Liu Y, Ding M, Ye J et al (2019) Graphene coated carbon felt as a high-performance electrode for all vanadium redox flow batteries. Surf Coat Technol 358:153–158
Li W, Zhang Z, Tang Y, Bian H, Ng TW, Zhang W et al (2016) Graphene-nanowall-decorated carbon felt with excellent electrochemical activity toward VO2+/VO2+ couple for all vanadium redox flow battery. Adv Sci 3(4):1500276
Opar DO, Nankya R, Lee J, Jung H (2020) Three-dimensional mesoporous graphene-modified carbon felt for high-performance vanadium redox flow batteries. Electrochim Acta 330:135276
González Z, Botas C, Blanco C, Santamaría R, Granda M, Álvarez P et al (2013) Graphite oxide-based graphene materials as positive electrodes in vanadium redox flow batteries. J Power Sources 241:349–354
González Z, Flox C, Blanco C, Granda M, Morante JR, Menéndez R et al (2017) Outstanding electrochemical performance of a graphene-modified graphite felt for vanadium redox flow battery application. J Power Sources 338:155–162
Etesami M, Abouzari-Lotf E, Ripin A, Nasef MM, Ting TM, Saharkhiz A et al (2018) Phosphonated graphene oxide with high electrocatalytic performance for vanadium redox flow battery. Int J Hydrogen Energy 43(1):189–197
Tsai HM, Yang SY, Ma CCM, Xie X (2011) Preparation and electrochemical properties of graphene-modified electrodes for all-vanadium redox flow batteries. Electroanalysis 23(9):2139–2143
Poh HL, Šaněk F, Ambrosi A, Zhao G, Sofer Z, Pumera M (2012) Graphenes prepared by Staudenmaier, Hofmann and Hummers methods with consequent thermal exfoliation exhibit very different electrochemical properties. Nanoscale 4(11):3515–3522
Eqra R, Moghim MH (2016) Effect of strain rate on the fracture behaviour of epoxy–graphene nanocomposite. Bull Mater Sci 39(5):1197–1204
Wang G, Shen X, Yao J, Park J (2009) Graphene nanosheets for enhanced lithium storage in lithium ion batteries. Carbon 47(8):2049–2053
Kaniyoor A, Ramaprabhu S (2012) A Raman spectroscopic investigation of graphite oxide derived graphene. AIP Adv 2(3):032183
Eqra R, Janghorban K, Daneshmanesh H (2015) Mechanical properties and toughening mechanisms of epoxy/graphene nanocomposites. J Polym Eng 35(3):257–266
Dehghan F, Mohammadi-Manesh H, Loghavi MM (2019) Investigation of lithium-ion diffusion in LiCoPO4 cathode material by molecular dynamics simulation. J Struct Chem 60(5):727–735
Loghavi MM, Babaiee M, Eqra R (2022) Al2O3-coated LiNi0.8Co0.15Al0.05O2/ graphene composite as a high-performance cathode material for lithium-ion battery. Main Group Chem Preprint 1–11. https://doi.org/10.3233/MGC-220025
Gholami M, Zarei-jelyani M, Babaiee M, Baktashian S, Eqra R (2020) Physical vapor deposition of TiO2 nanoparticles on artificial graphite: an excellent anode for high rate and long cycle life lithium-ion batteries. Ionics 26(9):4391–4399
Yao C, Zhang H, Liu T, Li X, Liu Z (2012) Carbon paper coated with supported tungsten trioxide as novel electrode for all-vanadium flow battery. J Power Sources 218:455–461
Yue L, Li W, Sun F, Zhao L, Xing L (2010) Highly hydroxylated carbon fibres as electrode materials of all-vanadium redox flow battery. Carbon 48(11):3079–3090
Babaiee M, Zarei-Jelyani M, Baktashian S, Eqra R (2022) Surface modification of copper current collector to improve the mechanical and electrochemical properties of graphite anode in lithium-ion battery. J Renewable Energy Environ 9(1):63–69
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This work received financial support from Institute of Mechanics.
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Mohammad Mohsen Loghavi: Conceptualization, Methodology, Software, Validation, Formal analysis, Investigation, Resources, Data curation, Writing – original draft, Writing – review & editing, Visualization, Supervision. Mohammad Zarei-Jelyani: Conceptualization, Methodology, Software, Validation, Formal analysis, Investigation, Data curation, Writing – review & editing, Visualization, Supervision. Mohsen Babaiee: Writing – review & editing. Zeinab Niknam: Electrochemical, Data collection. Rahim Eqra: Writing – review & editing.
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Loghavi, M.M., Zarei-Jelyani, M., Babaiee, M. et al. Graphene/Nafion ink-impregnated graphite felt for both positive and negative sides of enhanced vanadium redox flow battery. J Solid State Electrochem 27, 2237–2250 (2023). https://doi.org/10.1007/s10008-023-05476-z
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DOI: https://doi.org/10.1007/s10008-023-05476-z