Architecting 3D carbon networks: A binder-free route to high-performance energy storage
Oluşturanlar
- 1. Tarsus Univ, Fac Engn, Dept Engn Fundamental Sci, TR-33400 Tarsus, Turkiye
- 2. Tarsus Univ, Dept Chem & Chem Proc Technol, Vocat Sch Tech Sci Mersin Tarsus Organized Ind Zon, TR-33400 Mersin, Turkiye
- 3. Mersin Univ, Adv Technol Educ Res & Applicat Ctr, Mersin, Turkiye
Açıklama
Achieving high capacitance, fast charge-discharge capability, and cycle stability simultaneously in supercapacitor electrodes remains a critical challenge for next-generation energy storage. Here, we present a threedimensional (3D) reduced graphene hydrogel (RGH) architecture directly bonded to nickel foam (NF) via an optimized simple reduction process without the use of a binder. The resulting RGH/NF electrode exhibits the highest specific surface area (2424.5 m2 g- 1) reported to date for graphene-based systems, forming interconnected ion channels and a continuous conductive network at the RGH-NF interface. This unique structure provides a record-breaking specific capacitance of 1.208 F/g at 5 mV s- 1, significantly outperforming conventional graphene electrodes. It demonstrates exceptional durability with a capacitance retention rate of 94.6 % after 10.000 cycles at 3 A g- 1. When configured as a symmetric supercapacitor, the device achieves an unprecedented combination of energy density (145 Wh kg- 1) and power density (1.09 kW/kg), outperforming most reported carbon-based systems. These results position 3D RGH, which grows directly on metal frameworks, as a scalable and highly effective strategy for high-performance energy storage technologies.
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Dosyalar
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