Carbon electrodes with ionophobic characteristics in organic electrolyte for high-performance electric double-layer capacitors

Shao H, Wu YC, Lin Z, et al. Nanoporous carbon for electrochemical capacitive energy storage. Chem Soc Rev, 2020, 49: 3005–3039

Yan J, Li S, Lan B, et al. Rational design of nanostructured electrode materials toward multifunctional supercapacitors. Adv Funct Mater, 2020, 30: 1902564

González A, Goikolea E, Barrena JA, et al. Review on supercapacitors: Technologies and materials. Renew Sustain Energy Rev, 2016, 58: 1189–1206

Raza W, Ali F, Raza N, et al. Recent advancements in supercapacitor technology. Nano Energy, 2018, 52: 441–473

Yang Z, Tian J, Yin Z, et al. Carbon nanotube- and graphene-based nanomaterials and applications in high-voltage supercapacitor: A review. Carbon, 2019, 141: 467–480

Xie L, Su F, Xie L, et al. Effect of pore structure and doping species on charge storage mechanisms in porous carbon-based supercapacitors. Mater Chem Front, 2020, 4: 2610–2634

Qi D, Liu Y, Liu Z, et al. Design of architectures and materials in inplane micro-supercapacitors: Current status and future challenges. Adv Mater, 2017, 29: 1602802

Simon P, Gogotsi Y. Perspectives for electrochemical capacitors and related devices. Nat Mater, 2020, 19: 1151–1163

Eliad L, Salitra G, Soffer A, et al. Ion sieving effects in the electrical double layer of porous carbon electrodes: Estimating effective ion size in electrolytic solutions. J Phys Chem B, 2001, 105: 6880–6887

Eliad L, Salitra G, Soffer A, et al. On the mechanism of selective electroadsorption of protons in the pores of carbon molecular sieves. Langmuir, 2005, 21: 3198–3202

Forse AC, Merlet C, Griffin JM, et al. New perspectives on the charging mechanisms of supercapacitors. J Am Chem Soc, 2016, 138: 5731–5744

Redondo E, Tsai WY, Daffos B, et al. Outstanding room-temperature capacitance of biomass-derived microporous carbons in ionic liquid electrolyte. Electrochem Commun, 2017, 79: 5–8

Griffin JM, Forse AC, Tsai WY, et al. In situ NMR and electrochemical quartz crystal microbalance techniques reveal the structure of the electrical double layer in supercapacitors. Nat Mater, 2015, 14: 812–819

Kondrat S, Kornyshev AA. Pressing a spring: What does it take to maximize the energy storage in nanoporous supercapacitors? Nanoscale Horiz, 2016, 1: 45–52

Kondrat S, Wu P, Qiao R, et al. Accelerating charging dynamics in subnanometre pores. Nat Mater, 2014, 13: 387–393

Qian C, Zhao J, Sun Y, et al. Electrolyte-phobic surface for the next-generation nanostructured battery electrodes. Nano Lett, 2020, 20: 7455–7462

Salanne M, Rotenberg B, Naoi K, et al. Efficient storage mechanisms for building better supercapacitors. Nat Energy, 2016, 1: 16070

Prehal C, Koczwara C, Jäckel N, et al. Quantification of ion confinement and desolvation in nanoporous carbon supercapacitors with modelling and in situ X-ray scattering. Nat Energy, 2017, 2: 16215

Lu M, He Q, Li Y, et al. The effects of radio-frequency CF4 plasma on adhesion properties of vertically aligned carbon nanotube arrays. Carbon, 2019, 142: 592–598

Bahuguna G, Chaudhary S, Sharma RK, et al. Electrophilic fluorination of graphitic carbon for enhancement in electric double-layer capacitance. Energy Technol, 2019, 7: 1900667

Na W, Jun J, Park JW, et al. Highly porous carbon nanofibers co-doped with fluorine and nitrogen for outstanding supercapacitor performance. J Mater Chem A, 2017, 5: 17379–17387

Zhao Y, Wei K, Wu H, et al. LiF splitting catalyzed by dual metal nanodomains for an efficient fluoride conversion cathode. ACS Nano, 2019, 13: acsnano.8b09453

Yin X, Utetiwabo W, Sun S, et al. Incorporation of CeF3 on single-atom dispersed Fe/N/C with oxophilic interface as highly durable electro-catalyst for proton exchange membrane fuel cell. J Catal, 2019, 374: 43–50

Fedoseeva YV, Bulusheva LG, Koroteev VO, et al. Preferred attachment of fluorine near oxygen-containing groups on the surface of doublewalled carbon nanotubes. Appl Surf Sci, 2020, 504: 144357

Bulusheva LG, Fedoseeva YV, Flahaut E, et al. Effect of the fluorination technique on the surface-fluorination patterning of double-walled carbon nanotubes. Beilstein J Nanotechnol, 2017, 8: 1688–1698

Struzzi C, Scardamaglia M, Colomer JF, et al. Fluorination of vertically aligned carbon nanotubes: From CF4 plasma chemistry to surface functionalization. Beilstein J Nanotechnol, 2017, 8: 1723–1733

Hemraj-Benny T, Banerjee S, Sambasivan S, et al. Near-edge X-ray absorption fine structure spectroscopy as a tool for investigating nanomaterials. Small, 2006, 2: 26–35

Prehal C, Weingarth D, Perre E, et al. Tracking the structural arrangement of ions in carbon supercapacitor nanopores using in situ small-angle X-ray scattering. Energy Environ Sci, 2015, 8: 1725–1735

Zhou J, Xu L, Li L, et al. Polytetrafluoroethylene-assisted N/F co-doped hierarchically porous carbon as a high performance electrode for supercapacitors. J Colloid Interface Sci, 2019, 545: 25–34

Vijayakumar M, Santhosh R, Adduru J, et al. Activated carbon fibres as high performance supercapacitor electrodes with commercial level mass loading. Carbon, 2018, 140: 465–476

Zhang S, Shi X, Wróbel R, et al. Low-cost nitrogen-doped activated carbon prepared by polyethylenimine (PEI) with a convenient method for supercapacitor application. Electrochim Acta, 2019, 294: 183–191

Wang D, Liu S, Jiao L, et al. Unconventional mesopore carbon nanomesh prepared through explosion-assisted activation approach: A robust electrode material for ultrafast organic electrolyte supercapacitors. Carbon, 2017, 119: 30–39

Yang V, Arumugam Senthil R, Pan J, et al. Hierarchical porous carbon derived from jujube fruits as sustainable and ultrahigh capacitance material for advanced supercapacitors. J Colloid Interface Sci, 2020, 579: 347–356

Kota M, Jana M, Park HS. Improving energy density of supercapacitors using heteroatom-incorporated three-dimensional macro-porous graphene electrodes and organic electrolytes. J Power Sources, 2018, 399: 83–88