Application of Conductive Metal Organic Frameworks in Supercapacitors

Zehui LI; Meijuan TAN; Yuanhao ZHENG; Yuyang LUO; Qiushi JING; Jingkun JIANG; Mingjie LI

doi:10.15541/jim20190433

Journals >Journal of Inorganic Materials >Volume 35 >Issue 7 >Page 769 > Article

Journal of Inorganic Materials
Vol. 35, Issue 7, 769 (2020)

Application of Conductive Metal Organic Frameworks in Supercapacitors

Zehui LI¹, Meijuan TAN², Yuanhao ZHENG³, Yuyang LUO³, Qiushi JING³, Jingkun JIANG¹, and Mingjie LI^4、*

Author Affiliations

¹State Key Joint Laboratory of Environment Simulation and Pollution Control, School of Environment, Tsinghua University, Beijing 100084, China

²Nanjing University of Information Science and Technology, Nanjing 210044, China

³School of Environmental Science and Engineering, School of Materials Science and Engineering, Tsinghua University, Beijing 100084, China

⁴CAS Key Laboratory of Bio-based Materials, Qingdao Institute of Biomass Energy and Bioprocess Technology, Chinese Academy of Sciences, Qingdao 266101, China

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DOI: 10.15541/jim20190433 Cite this Article

Zehui LI, Meijuan TAN, Yuanhao ZHENG, Yuyang LUO, Qiushi JING, Jingkun JIANG, Mingjie LI. Application of Conductive Metal Organic Frameworks in Supercapacitors[J]. Journal of Inorganic Materials, 2020, 35(7): 769 Copy Citation Text

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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]

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]

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Control strategy of conductive MOFs in supercapacitors From microstructure, active site, surface interface and nanocomposite of conductive MOFs to energy storage applications

2. Control strategy of conductive MOFs in supercapacitors From microstructure, active site, surface interface and nanocomposite of conductive MOFs to energy storage applications

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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]

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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]

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5. Structure of MOF‐867 and performance of the nMOF SCs^[44]

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6. Cycle performance for all Ni-DMOFs-based asymmetric supercapacitor at a current density of 10 A∙g^-1[41]

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7. Schematic diagram for coin-type supercapacitors^[44]

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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]

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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^-3_stack	1.097 W·cm^-3_stack	[44]
Zn, Ni	p-Benzenedicarboxylic acid (PTA)	Zn-dopedNi-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]

Table 1. MOFs with different center metal atoms for SCs

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