Double redox-active quinone molecules functionalized a three-dimensional graphene network for high-performance supercapacitor

“…24−28 However, the electrical conductivity of redoxactive organic compounds has been limited by the degree of doping, resulting in the inability to utilize those advantages fully. Therefore, researchers have primarily focused on attaching organic materials to highly conductive carbonbased materials, such as activated carbon, 29 tubes, 30,31 and graphene 32,33 via π−π stacking, hydrogen bonding, and other noncovalent interactions. 34,35 To further increase the energy density, these composite electrode materials are utilized in the assembly of asymmetric devices.…”

“…If appropriate organic electrode materials with different types of doping are selected to assemble asymmetric devices, one electrode is p-doping while the other is n-doping, which could provide high energy density. − However, the electrical conductivity of redox-active organic compounds has been limited by the degree of doping, resulting in the inability to utilize those advantages fully. Therefore, researchers have primarily focused on attaching organic materials to highly conductive carbon-based materials, such as activated carbon, carbon nanotubes, , and graphene , via π–π stacking, hydrogen bonding, and other noncovalent interactions. , To further increase the energy density, these composite electrode materials are utilized in the assembly of asymmetric devices. − For example, Jiao et al assembled asymmetric supercapacitors by fabricating redox-active PPA/rGO and GH-DN for the positive and negative electrodes, respectively. Kandambeth et al synthesized redox COFs structures for the negative electrode and assembled asymmetric supercapacitors using RuO 2 as the positive electrode.…”

Preparation of Positive and Negative Composite Electrode Materials for High-Performance Aqueous Asymmetric Supercapacitor by a Sequential Two-Step Reaction

“…24−28 However, the electrical conductivity of redoxactive organic compounds has been limited by the degree of doping, resulting in the inability to utilize those advantages fully. Therefore, researchers have primarily focused on attaching organic materials to highly conductive carbonbased materials, such as activated carbon, 29 tubes, 30,31 and graphene 32,33 via π−π stacking, hydrogen bonding, and other noncovalent interactions. 34,35 To further increase the energy density, these composite electrode materials are utilized in the assembly of asymmetric devices.…”

“…If appropriate organic electrode materials with different types of doping are selected to assemble asymmetric devices, one electrode is p-doping while the other is n-doping, which could provide high energy density. − However, the electrical conductivity of redox-active organic compounds has been limited by the degree of doping, resulting in the inability to utilize those advantages fully. Therefore, researchers have primarily focused on attaching organic materials to highly conductive carbon-based materials, such as activated carbon, carbon nanotubes, , and graphene , via π–π stacking, hydrogen bonding, and other noncovalent interactions. , To further increase the energy density, these composite electrode materials are utilized in the assembly of asymmetric devices. − For example, Jiao et al assembled asymmetric supercapacitors by fabricating redox-active PPA/rGO and GH-DN for the positive and negative electrodes, respectively. Kandambeth et al synthesized redox COFs structures for the negative electrode and assembled asymmetric supercapacitors using RuO 2 as the positive electrode.…”

Preparation of Positive and Negative Composite Electrode Materials for High-Performance Aqueous Asymmetric Supercapacitor by a Sequential Two-Step Reaction

Quinone Quest: Unraveling electrochemical performance in quinone-anchored 3D graphene architectures for high-energy supercapacitors

Heterogeneous polymer of aniline and benzoquinone enabled high energy density of graphene-based supercapacitors