Vertical porous Ti3CNTx/rGO hybrid aerogels with enhanced capacitive performance

Xu，Shuaikai1; Yan，Surong1; Chen，Xue1; Huang，Haifu1; Liang，Xianqing1; Wang，Yuanhao3; Hu，Qing3; Wei，Guodong4; Yang，Ya1,2

2023-03-01

10.1016/j.cej.2023.141528

CHEMICAL ENGINEERING JOURNAL   影响因子和分区

1385-8947

1873-3212

Two-dimensional MXenes have shown great application potential in high-performance supercapacitors due to their high conductivity and excellent intercalation pseudocapacitance. Thereinto, compared with previously reported TiCT, TiCNT MXene with unique C and N atom-layer structure was predicted to achieve higher capacitive performance. However, the nanosheet restacking and complex ion-diffusion paths often limit the capacitance and rate performance of MXene-based electrodes. At this point, we proposed to construct vertical porous TiCNT/rGO hybrid aerogel electrodes through a unidirectional bottom-up freezing process. The vertical porous structure would greatly shorten the ion diffusion paths. Furthermore, the introduced rGO nanosheets would impede the restacking of TiCNT nanosheets, improving the accessibility of electrolyte ions. As a result, the TiCNT/rGO hybrid aerogels delivered significantly improved gravimetric capacitance of 390 F g, high-rate performance (205 F g at 1000 mV s) and great cycling stability (98 % capacitance retention after 10,000 cycles). This work not only proved the great superiority of vertical porous TiCNT/rGO hybrid aerogels but also opened a new door for TiCNT and other MXenes to be used for high-performance supercapacitors.

Hybrid aerogels MXenes Pseudocapacitance Supercapacitors Vertical Ti3CNTx

SCI ; EI

英语

其他

National Natural Science Foundation of China["52202224","52072041"] ; Natural Science Foundation of Guangxi Province[2020JJB120060] ; Specific Research Project of Guangxi for Research Bases and Talents[2021AC19174] ; National Key R & D Project from Minister of Science and Technology in China[2021YFA1201604]

Engineering

Engineering, Environmental ; Engineering, Chemical

WOS:000964861000001

ELSEVIER SCIENCE SA

20230513466034

Aerogels ; Capacitance ; Electrodes ; Electrolytes ; Ions ; Nanosheets ; Titanium compounds

Electricity: Basic Concepts and Phenomena:701.1 ; Electric Batteries and Fuel Cells:702 ; Electric Components:704.1 ; Nanotechnology:761 ; Colloid Chemistry:801.3 ; Chemical Agents and Basic Industrial Chemicals:803 ; Chemical Products Generally:804 ; Solid State Physics:933

ENGINEERING

2-s2.0-85146922420

Scopus

1.Guangxi Key Laboratory of Electrochemical Energy Materials,Guangxi Novel Battery Materials Research Center of Engineering Technology,Center on Nanoenergy Research,College of Physics Science and Technology,Guangxi University,Nanning,530004,China
2.CAS Center for Excellence in Nanoscience,Beijing Key Laboratory of Micro-nano Energy and Sensor,Beijing Institute of Nanoenergy and Nanosystems,Chinese Academy of Sciences,Beijing,101400,China
3.SUSTech Engineering Innovation Center,School of Environmental Science and Engineering,Southern University of Science and Technology,Shenzhen,Guangdong,518055,China
4.Materials Institute of Atomic and Molecular Science,School of Physics and Energy,Shaanxi University of Science and Technology,Xi'an,Shaanxi,710021,China

Xu，Shuaikai,Yan，Surong,Chen，Xue,et al. Vertical porous Ti3CNTx/rGO hybrid aerogels with enhanced capacitive performance[J]. CHEMICAL ENGINEERING JOURNAL,2023,459.

Xu，Shuaikai.,Yan，Surong.,Chen，Xue.,Huang，Haifu.,Liang，Xianqing.,...&Yang，Ya.(2023).Vertical porous Ti3CNTx/rGO hybrid aerogels with enhanced capacitive performance.CHEMICAL ENGINEERING JOURNAL,459.

Xu，Shuaikai,et al."Vertical porous Ti3CNTx/rGO hybrid aerogels with enhanced capacitive performance".CHEMICAL ENGINEERING JOURNAL 459(2023).