Journal of Inorganic Materials, Volume. 35, Issue 7, 769(2020)
Figures & Tables(9)
![Representation of possible modes of charge transport in MOFs: (a) hopping charge transport, (b) through-space charge transport, and (c) through-bond charge transport[22]](/Images/icon/loading.gif){kind=icon}
1. Representation of possible modes of charge transport in MOFs: (a) hopping charge transport, (b) through-space charge transport, and (c) through-bond charge transport[22]
2. Control strategy of conductive MOFs in supercapacitors From microstructure, active site, surface interface and nanocomposite of conductive MOFs to energy storage applications
3. (a) Crystal structure of Cu-CAT viewed along the c -axis; (b) Structure of the solid-state supercapacitor (left) and photograph of a red light-emitting-diode powered by the three supercapacitors connected in series (right); (c, d) SEM and photographic images (inset in (d)) of the Cu-CAT NWAs growing on carbon fiber paper; Performance comparison of (e)Cu-CAT NWAs and (f) MOF materials, and carbon materials based symmetric solid-state supercapacitors[29]
4. (a) Molecular structure of Ni3(HITP)2; (b) Relative size of pores, electrolyte Et4N+ and BF4- ions, and acetonitrile solvent molecules showing in a space-filling diagram of idealized Ni3(HITP)2; (c) Comparison of areal capacitance for various materials normalized relative to their BET surface areas[30]
6. Cycle performance for all Ni-DMOFs-based asymmetric supercapacitor at a current density of 10 A∙g-1[41]
8. (a) Illustration of the synthesis methodology for polyaniline-ZIF-67 on carbon cloth; (b) Areal capacitances of the PANI-ZIF-67-CC and other electrode materials; (c-f) Schematic illustrations of PANI-ZIF-67-CC flexible solid-state SC device; (g) Photograph of a red light-emitting-diode (LED) powered by the three SCs connected in series[52]
Table 1. MOFs with different center metal atoms for SCs
View tableView in ArticleTable 1. MOFs with different center metal atoms for SCs
Metal Organic ligand MOFs Conductivity /(S∙m-1) S BET/(m2·g-1) Specific capacitance Energy density Power density Ref. Fe 1,3,5-Benzenetricarboxylic acid (H3BT)C MIL-100 - - 39 F·g-1 - - [ 35 ]Co Polyethylene glycol (PEG) Co-MOF-71 - - 206.76 F·g-1 7.18 Wh·kg-1 - [ 36 ]Co Benzendicarboxylic (BDC) acid Co-BDC - 9.09 131.8 F·g-1 20.7 Wh·kg-1 3880 W·kg-1 [ 25 ]Co 2,6-Naphthalenedicarboxylic (NDC) acid Co-NDC - 20.29 147.3 F·g-1 23.1 Wh·kg-1 5490 W·kg-1 [ 25 ]Co 4,4-Biphenyldicarboxylic (BPDC) acid Co-BPDC - 138.35 179.2 F·g-1 31.4 Wh·kg-1 5640 W·kg-1 [ 25 ]Ni Isonicotinic acid Ni-MOF - 148 634 F·g-1 - - [ 37 ]Ni Salicylate ion 1D Ni-MOF - 186.8 1698 F·g-1 - - [ 38 ]Ni p -Benzenedicarboxylic acid (PTA)Ni-MOF-24 - - 1127 F·g-1 19.17 Wh·kg-1 1750 W·kg-1 [ 39 ]Ni 1,3,5-Benzenetricarboxylic (btc) acid (H3BT)C Ni3(btc)2·12H2O - - 726 F·g-1 16.5 Wh·kg-1 2078 W·kg-1 [ 40 ]Ni 9,10-Anthracenedicarboxylic acid (ADC) Ni-DMOF-ADC - 783 552 F·g-1 - - [ 41 ]Ni 2,3,6,7,10,11-Hexaiminotriphenylene (HITP) Ni3(HITP)2 >5000 630 111 F·g-1 - - [ 30 ]Zn 4,4’-Biphenyldicarboxylic acid (H2BPC) Zn6(BPC)6(L)3· 9DMF - - 23 F·g-1 1.9 Wh·kg-1 3 W·kg-1 [ 42 ]Zn p -Phenylenediamine (pPDA)Zn-(pPDA)MOF 0.1~1.05 200.86 F·g-1 62.8 Wh·kg-1 4500 W·kg-1 [ 43 ]Cd 2,5-Thiophenedicarboxylic acid (H2TDC) Cd2(TDC)2(L)2· 2H2O - - 22 F·g-1 2.1 Wh·kg-1 3.3 W·kg-1 [ 42 ]Zr 2,2’-Bipyridine-5,5’-dicarboxylate (BPYDC) nMOF-867 - - 5.085 mF·cm-2 6.04× 10-4 Wh·cm-3stack 1.097 W·cm-3stack [ 44 ]Zn, Ni p -Benzenedicarboxylic acid (PTA)Zn-doped Ni-MOF - - 1620 F·g-1 27.56 Wh·kg-1 1750 W·kg-1 [ 45 ]Co, Zn Benzendicarboxylic acid Co8-MOF-5 - 2900 0.49 F·g-1 - - [ 46 ]Zn, Zr Terephthalic acid HP-UiO-66 - - 849 F·g-1 32 Wh·kg-1 240 W·kg-1 [ 47 ]
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Zehui LI, Meijuan TAN, Yuanhao ZHENG, Yuyang LUO, Qiushi JING, Jingkun JIANG, Mingjie LI.
Paper Information
Category: REVIEW
Received: Aug. 16, 2019
Accepted: --
Published Online: Mar. 3, 2021
The Author Email: LI Mingjie (limj@qibebt.ac.cn)
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