Electrochemical active surface area of Ti/IrO2+MnO2 electrodes in the acid solutions

doi:10.16085/j.issn.1000-6613.2018-2028

Abstract

Abstract:

Ti/IrO₂+MnO₂ coated electrodes with different compositions were prepared by the thermal decomposition method. The electrochemical surface of Ti/IrO₂+MnO₂ electrodes were studied by potentiostatic cyclic voltammetry in sulfuric acid solution, and the electrochemical active surface area of electrodes were evaluated quantitatively by a linear extrapolation. The results show that the voltammetric charge of Ti/(0.7)IrO₂+(0.3)MnO₂ is the highest, along with the largest electrochemical active surface area. With the increase of the potential scanning speed, the voltammetric current density increases continuously, while the voltammetric charge decreases gradually until a constant value is reached. For all the Ti/IrO₂+MnO₂ electrodes, the “inner” electrochemical active surface area is much larger than the “outer” electrochemical active surface area, by about two times. It means that there are a lot of micropores inside the electrodes with a very large real surface area, thus the Ir⁴⁺/Ir³⁺ valence state transition occurs at the ”inner” electrochemical active surface.

Key words: IrO₂+MnO₂, electrochemical active surface, electrochemistry, catalysis, interface

摘要：

采用涂覆热分解法制备不同成分的Ti/IrO₂+MnO₂电极，利用恒电位循环伏安法研究Ti/IrO₂-MnO₂电极在硫酸溶液中的电化学表面行为，并用直线外推法定量地评价电极的电化学活性表面积。结果表明，Ti/(0.7)IrO₂+(0.3)MnO₂的伏安电荷达到最高，为电化学活性表面积最大；随着电位扫描速率增大，伏安电流密度不断增加，而伏安电荷容量逐渐减少，直到维持恒定；所有Ti/IrO₂+MnO₂电极的“内部”电化学活性表面积远大于“外部”电化学活性表面积，约为“外部”电化学活性表面积的2倍，说明电极内部存在丰富的多孔结构，真实表面积巨大，因此Ir⁴⁺/Ir³⁺转化反应多发生于内电化学活性表面区域。

关键词: IrO₂+MnO₂, 电化学活性表面, 电化学, 催化, 界面

CLC Number:

TQ138

Jian ZHOU,Wenxue GUAN,Sanfan WANG,Xueming ZHANG. Electrochemical active surface area of Ti/IrO₂+MnO₂ electrodes in the acid solutions[J]. Chemical Industry and Engineering Progress, 2019, 38(08): 3782-3787.

周键,关文学,王三反,张学敏. Ti/IrO₂+MnO₂电极在酸性溶液中的电化学活性表面积[J]. 化工进展, 2019, 38(08): 3782-3787.

Figures/Tables 7

References 21

1	YE Z G , HUANG G B , LIU G W , et al . Influence of preparation process on electrocatalytic activity of Ti/IrO₂+MnO₂ anodes for oxygen evolution in 0.5M Na₂SO₄ solution[J]. Materials Research Innovations, 2014, 18(s2): 440-446.
2	高洁, 朱玉婵, 任占冬, 等 . Ir_0.5Pt_0.5O₂阳极的电催化活性及氧化电解水制备[J]. 化工学报, 2015, 66(3): 992-1000.
	GAO Jie , ZHU Yuchan , REN Zhandong , et al . Electrocatalytic performance of Ir_0.5Pt_0.5O₂ anode and preparation of electrolyzed oxidizing water[J]. Journal of Chemical Industry and Engineering, 2014, 24(10): 2553-2558.
3	ZHANG J J , HU J M , ZHANG J Q , CAO C N . IrO₂-SiO₂ binary oxide films: geometric or kinetic interpretation of the improved electrocatalytic activity for the oxygen evolution reaction[J]. International Journal of Hydrogen Energy, 2011, 36(9): 5218-5226.
4	MARSHALL A , BORRESEN B , HAGEN G , et al . Electrochemical characterisation of Ir _x Sn_1- _x O₂ powders as oxygen evolution electrocatalysts[J]. Electrochimica Acta, 2006, 51(15): 3161-3167.
5	KATO Z , KASHIMA R , TATSUMI K , et al . The influence of coating solution and calcination condition on the durability of Ir_1- _x Sn _x O₂/Ti anodes for oxygen evolution[J]. Applied Surface Science, 2016, 388:640-644.
6	孔德生, 吕文华, 冯媛媛, 等 . DSA电极电催化性能研究及尚待深入探究的几个问题[J]. 化学进展, 2009, 21(6): 1107-1117.
	KONG Desheng , Wenhua LǛ , FENG Yuanyuan , et al . Advances and some problems in electrocatalysis of DSA electrodes[J]. Progress in Chemistry, 2009, 21(6): 1107-1117.
7	HU W , CHEN S , XIA Q . IrO₂/Nb-TiO₂ electrocatalyst for oxygen evolution reaction in acidic medium[J]. International Journal of Hydrogen Energy, 2014, 39(13): 6967-6976.
8	朱学军, 邓俊, 张毅 . Ti/MnO₂电极制备及对甲醇催化氧化[J]. 化工进展, 2016, 35(s2): 244-247.
	ZHU Xuejun , DENG Jun , ZHANG Yi . Preparation of Ti/MnO₂ electrode for the catalytic oxidation of methanol[J]. Chemical Industry and Engineering Progress, 2016, 35(s2): 244-247.
9	TRASATTI S . Physical electrochemistry of ceramic oxides[J]. Electrochimica Acta, 1991, 36(2): 225-241.
10	KIM K W , LEE E H, KIM J S , et al . Study on the electro-activity and non-stochiometry of a Ru-based mixed oxide electrode[J]. Electrochimica Acta, 2002, 46(6): 915-921.
11	WANG X M , HU J M , ZHANG J Q . IrO₂-SiO₂ binary oxide films: preparation, physiochemical characterization and their electrochemical properties[J]. Electrochimica Acta, 2010, 55(15): 4587-4593
12	WANG Y Q , TONG H Y , XU W L . Electrocatalytic activity of Ti/TiO₂ electrodes in H₂SO₄ solution[J]. Journal of Process Engineering, 2003, 3(4): 356-360.
13	COMNINELLIS C H , VERCESI G P . Characterization of DSA®-type oxygen evolving electrodes: choice of a coating[J]. Journal of Applied Electrochemistry, 1991, 21(4): 335-345.
14	XU J , LIU G , LI J . The electrocatalytic properties of an IrO₂/SnO₂ catalyst using SnO₂ as a support and an assisting reagent for the oxygen evolution reaction[J]. Electrochimica Acta, 2012, 59:105-112.
15	GRUPIONI A A F , ARASHIRO E , LASSAIL T A F . Voltammetric characterization of an iridium oxide-based system: the pseudocapacitive nature of the Ir_0.3Mn_0.7O₂ electrode[J]. Electrochimica Acta, 2003, 48(4): 407-418.
16	SPIOLO G , ARDIZZONE S , TRASATTI S . Surface characterization of Co₃O₄ electrodes prepared by the sol-gel method[J]. Journal of Electroanalytical Chemistry, 1997, 423(1): 49-57.
17	VOGT H . Note on a method to interrelate inner and outer electrode areas[J]. Electrochimica Acta, 1994, 39(13): 1981-1983.
18	ARDIZZONE S , FREGONARA G , TRASATTI S . Inner and outer active surface of RuO₂ electrodes[J]. Electrochimica Acta, 1990, 35(1): 263-267.
19	PAULI C P DE , TRASATTI S . Electrochemical surface characterization of IrO₂+SnO₂ mixed oxide electrocatalysts[J]. Journal of Electroanalytical Chemistry, 1995, 396(1): 161-168.
20	LOCATELLI C , MINGUZZI A , VERTOVA A . IrO₂-SnO₂mixtures as electrocatalysts for the oxygen reduction reaction in alkaline media[J]. Journal of Applied Electrochemistry, 2013, 43(2): 171-179.
21	SILVA L M DA , FARIA L A DE , BOODTS J F C . Electrochemical impedance spectroscopic (EIS) investigation of the deactivation mechanism, surface and electrocatalytic properties of Ti/RuO₂(x)+Co₃O₄(1-x) electrodes[J]. Journal of Electroanalytical Chemistry, 2002, 532(1): 141-150.

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Electrochemical active surface area of Ti/IrO₂+MnO₂ electrodes in the acid solutions

Ti/IrO₂+MnO₂电极在酸性溶液中的电化学活性表面积

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