Microstructure and Isothermal Oxidation of Ir–Rh Spark Plug Electrodes

Zhao, Shifang; Xia, Jun; Xia, Yiming; Chen, Jianming; Du, Dekui; Yang, Huimu; Liu, Jie

doi:10.3390/ma12193226

Cited by 5 publications

(2 citation statements)

References 28 publications

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“…Notably, the materials contain Ir species with two different valences, namely, metallic Ir (Ir 0 ) and oxidized Ir (Ir 4+ ). It suggests that some Ir particles were oxidized to hypervalent oxides (IrO x ) or bonded to hydroxyl groups (Ir(OH) x ), and the production of these components may alter the catalytic process of the materials . By calculating the relative intensity area of Ir 0 and Ir 4+ orbital peaks, the content proportions of high-valence Ir in the two materials were compared.…”

Section: Resultsmentioning

confidence: 99%

Preparation of Ir/TiO₂ Composite Oxygen Evolution Catalyst and Load Analysis as Anode Catalyst Layer of Proton Exchange Membrane Water Electrolyzer

Huang,

Xu,

Hao

et al. 2024

ACS Omega

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Electrochemical water splitting is regarded as an emerging green and sustainable hydrogen production technology because of its zerocarbon process. However, the overall cost of anode materials in a proton exchange membrane water electrolyzer (PEMWE) is high due to the use of noble metal Ir. It has been proved that introducing carrier materials to reduce the content of Ir element is a feasible cost-reduction program. Here, the Ir/ TiO 2 composite material was prepared by the polyol method and used to catalyze the oxygen evolution reaction, which could effectively reduce the load amount of Ir in the membrane electrode assembly (MEA). In addition, the theoretical load of Ir was obtained by model calculation and the polarization curve test and electrochemical impedance spectroscopy (EIS) were used to discuss the relationship between Ir load in MEA and voltage loss and conductivity. The results show that MEA has lower voltage loss and better conductivity as the Ir load is in the range of 0.204−0.304 mg Ir /cm 2 . Altogether, an effective method to reduce the Ir load of PEMWE anode was proposed under the premise comprehensive consideration of both catalyst design and MEA preparation in this work.

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Section: Resultsmentioning

confidence: 99%

Preparation of Ir/TiO₂ Composite Oxygen Evolution Catalyst and Load Analysis as Anode Catalyst Layer of Proton Exchange Membrane Water Electrolyzer

Huang,

Xu,

Hao

et al. 2024

ACS Omega

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“…In recent years, rhodium oxide (RhOx) has been widely applied as an electrocatalyst due to its high stability and electrocatalytic activity for oxygen evolution. − Alibek prepared Ti/IrO 2 –RhOx-ZrO 2 electrodes with different proportions of RhOx and found that increasing the content of RhOx led to improved service lifetime of the electrode. Swette reported that RhO 2 -coated electrodes with an oxide load of 10 g m –2 are highly stable against oxygen evolution in acidic electrolytes.…”

Section: Introductionmentioning

confidence: 99%

High-Performance Ti/IrO₂–RhOx–Ta₂O₅Electrodes for Polarity Reversal Applications

Jin

Zhang

et al. 2021

Ind. Eng. Chem. Res.

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Electrode polarity reversal has been widely employed to inhibit membrane fouling and induce scale detachment during electrodialysis and electrochemical precipitation, respectively. However, frequent polarity reversal shortens the lifetime of traditional dimensionally stable anodes. In this study, a novel titanium electrode that employed a ternary iridium, tantalum, and rhodium oxide mixture (IrO 2 −RhOx−Ta 2 O 5 ) as an active electrocatalyst film was investigated for polarity reversal applications. It was found that the Ti/IrO 2 −RhOx−Ta 2 O 5 electrode with an Ir/Rh/Ta molar ratio of 3:3:4 had a service lifetime of 1030 h in a 20 g L −1 Na 2 SO 4 solution at a current density of 2000 A m −2 and a polarity reversal frequency of 12 h −1 . In contrast, a Ti/IrO 2 −Ta 2 O 5 electrode with an Ir/Ta molar ratio of 6:4 under the same conditions exhibited a service lifetime of only 275 h. Physicochemical characterization revealed that the IrO 2 −RhOx−Ta 2 O 5 film has a compact microstructure, solid solution characteristics, and contains both Rh 3+ and Rh 4+ which contributes to the stability during polarity reversal. Moreover, the Ti/IrO 2 −RhOx−Ta 2 O 5 electrode showed better chlorine evolution performance than the Ti/IrO 2 −Ta 2 O 5 electrode.

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Wear Behavior of Bovine and Porcine Bone Versus Biocompatible Synthetic Materials, Case of Knee Prosthesis

Sánchez

Lara

Vázquez

et al. 2022

Lecture Notes in Mechanical Engineering

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Microstructure and Isothermal Oxidation of Ir–Rh Spark Plug Electrodes

Cited by 5 publications

References 28 publications

Preparation of Ir/TiO₂ Composite Oxygen Evolution Catalyst and Load Analysis as Anode Catalyst Layer of Proton Exchange Membrane Water Electrolyzer

Preparation of Ir/TiO₂ Composite Oxygen Evolution Catalyst and Load Analysis as Anode Catalyst Layer of Proton Exchange Membrane Water Electrolyzer

High-Performance Ti/IrO₂–RhOx–Ta₂O₅Electrodes for Polarity Reversal Applications

Wear Behavior of Bovine and Porcine Bone Versus Biocompatible Synthetic Materials, Case of Knee Prosthesis

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Microstructure and Isothermal Oxidation of Ir–Rh Spark Plug Electrodes

Cited by 5 publications

References 28 publications

Preparation of Ir/TiO2 Composite Oxygen Evolution Catalyst and Load Analysis as Anode Catalyst Layer of Proton Exchange Membrane Water Electrolyzer

Preparation of Ir/TiO2 Composite Oxygen Evolution Catalyst and Load Analysis as Anode Catalyst Layer of Proton Exchange Membrane Water Electrolyzer

High-Performance Ti/IrO2–RhOx–Ta2O5Electrodes for Polarity Reversal Applications

Wear Behavior of Bovine and Porcine Bone Versus Biocompatible Synthetic Materials, Case of Knee Prosthesis

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Product

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Preparation of Ir/TiO₂ Composite Oxygen Evolution Catalyst and Load Analysis as Anode Catalyst Layer of Proton Exchange Membrane Water Electrolyzer

Preparation of Ir/TiO₂ Composite Oxygen Evolution Catalyst and Load Analysis as Anode Catalyst Layer of Proton Exchange Membrane Water Electrolyzer

High-Performance Ti/IrO₂–RhOx–Ta₂O₅Electrodes for Polarity Reversal Applications