2018
DOI: 10.1002/adma.201804740
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Applications of Metal–Organic‐Framework‐Derived Carbon Materials

Abstract: production, especially for hydroelectricity, sunlight, and wind energy, which cannot be gathered or released when they are needed. [5][6][7][8] Electrochemical energy storage devices provide a promising approach for the storage of electric energy from these sources. [9][10][11] Currently, carbonaceous materials have attracted much interest for their extensive applications including adsorption, [12] catalysis, [13] batteries, [14] fuel cells, [15,16] supercapacitors, [17,18] and drug delivery and imaging. [19] … Show more

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Cited by 420 publications
(233 citation statements)
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References 244 publications
(266 reference statements)
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“…It is well known that the electrochemical properties of electrochemical energy storage devices mainly depend on the electrode materials. According to the working mechanism of supercapacitors, electrode materials are classified into carbon materials (electric‐double‐layer capacitors) and pseudocapacitor electrode materials including metal sulfide, metal oxides, metal selenide, metal hydroxide, conductive polymers, and so on, which mainly store energy by reversible redox reactions. Recently, rapidly growing MOF materials have achieved extensive specific surface area, large pore volume, and uniform pore dispersions, which can provide potential electrode candidates for SCs .…”
Section: Introductionmentioning
confidence: 99%
“…It is well known that the electrochemical properties of electrochemical energy storage devices mainly depend on the electrode materials. According to the working mechanism of supercapacitors, electrode materials are classified into carbon materials (electric‐double‐layer capacitors) and pseudocapacitor electrode materials including metal sulfide, metal oxides, metal selenide, metal hydroxide, conductive polymers, and so on, which mainly store energy by reversible redox reactions. Recently, rapidly growing MOF materials have achieved extensive specific surface area, large pore volume, and uniform pore dispersions, which can provide potential electrode candidates for SCs .…”
Section: Introductionmentioning
confidence: 99%
“…The peaks at 163.28 and 162.08 eV for S 2p are related to the metal‐S bonds (Figure e) . The peaks at 168.7 and 168.6 eV for S 2p are the intimations of SO bonds, suggesting the efficient filling of S in the vacancies f), which can be classified as lattice oxygen (O I , ≈531.1 eV), oxygen vacancies (O II , ≈531.8 eV), and chemisorbed or dissociated oxygen or OH species (O III , ≈533.4 eV) .…”
mentioning
confidence: 96%
“…MOFs are crystalline porous materials, which consist of metallic cation centers and bridging ligands. Thanks to their well‐developed porous structures and tunable chemical properties, MOFs and their derivatives have been widely used as catalysts for all kinds of environmental and energy applications . Pan et al presented ZIF‐67‐derived (ZIF = Zeolitic Imidazolate Framework) hollow polyhedron frames, which are doped with another transition metal element, including Ni, Mn, and Fe (Figure e) .…”
Section: Urea Electrolysis For Hydrogen Productionmentioning
confidence: 99%