High conductivity of novel Ti0.9Ir0.1O2 support for Pt as a promising catalyst for low-temperature fuel cell applications

Huynh, Tai Thien; Pham, Hau Quoc; Nguyen, At Van; Phan, Vi Thuy Thi; Ngoc, Anh Tram; Trinh, Nguyen Duy; Vo, Dai‐Viet N.; Ho, Van Thi Thanh

doi:10.1016/j.ijhydene.2018.09.174

Cited by 16 publications

(12 citation statements)

References 39 publications

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“…[ 30,31 ] The conductivity of the rutile TiO 2 phase was higher than that of the anatase TiO 2 phase due to the difference in the bandgap [ 32,33 ] that was also considered as the reason for the high electrical conductivity of the as‐prepared rutile Ti 0.9 Ir 0.1 O 2 nanosupport versus that anatase Ti 0.9 Ir 0.1 O 2 nanoparticles (1.6 × 10 −2 S cm −1 ). [ 21 ]…”

Section: Resultsmentioning

confidence: 99%

“…[ 4,14,16,17 ] In addition to the complicated multistep preparation, the low electrical conductivity of the rutile TiO 2 nanostructures is a primary challenge for fuel cells that could be solved by the incorporation of transition metals into TiO 2 lattice. [ 18–21 ] Iridium is the platinum‐group metals that show high conductivity and similar properties to Pt. [ 22 ] In addition, iridium has a high affinity for oxygenated species at low overpotential that facilitate the oxidation of CO and other carbonaceous species at the Pt active sites during the alcohol oxidation.…”

Section: Introductionmentioning

confidence: 99%

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Rutile Ti_0.9Ir_0.1O₂‐Supported Low Pt Loading: An Efficient Electrocatalyst for Ethanol Electrochemical Oxidation in Acidic Media

Pham

Huynh

2020

Energy Tech

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Developing a cost‐effective electrocatalyst toward ethanol electrochemical oxidation plays a vital role in large‐scale applications of direct ethanol fuel cells (DEFCs). Herein, a rutile Ti0.9Ir0.1O2‐supported low Pt‐loading catalyst is fabricated using a surfactant‐free one‐pot chemical reduction route at room temperature that not only reduces the amount of the Pt loading but also significantly enhances the CO antipoisoning and electrochemical stability toward ethanol electrochemical oxidation compared with the conventional carbon‐supported Pt electrocatalyst. The rutile Ti0.9Ir0.1O2 nanosupport with rod‐like morphology is first prepared via a one‐pot hydrothermal route, and then 15.5 wt% Pt nanoparticles with small size (≈3 nm) are anchored on it by the surfactant‐free chemical reduction process. For ethanol electrochemical oxidation, the rutile Ti0.9Ir0.1O2‐supported Pt catalyst shows a moderate current density (≈13.74 mA cm−2), which is comparable with the 20 wt% Pt/C electrocatalyst, despite its low loading (15.5 wt%). In addition, the rutile Ti0.9Ir0.1O2‐supported low Pt‐loading electrocatalyst demonstrates low onset potential (0.45 V vs normal hydrogen electrode [NHE]), superior CO‐tolerance, and impressive electrochemical stability compared with the carbon‐supported Pt catalyst. These enhancements are ascribable to the inherent durability of the rutile TiO2 nanostructure and the synergistic effect between Pt and Ti0.9Ir0.1O2 nanosupport.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Rutile Ti_0.9Ir_0.1O₂‐Supported Low Pt Loading: An Efficient Electrocatalyst for Ethanol Electrochemical Oxidation in Acidic Media

Pham

Huynh

2020

Energy Tech

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“…To highlight the distinction, we used mass activities (mA mg ‐1 ) and specific activity (mA cm ‐2 ) as illustrated in Figure 13 to give a standard evaluation by normalizing the current for the Pt mass loading and the ECSA, respectively as to make a comparison for all. It demonstrate that the biosynthesized Pt NPs is performed, comparable and exhibit superior electrocatalytic than that of the Pt‐based catalyst prepared by other conventional techniques, including wet‐chemical reduction with various morphologies, including a bimetallic PtAg, 70 PtRu icosahedra, 71 and Pt.ZSM‐5‐C 72 ; and as well as other conventional techniques, such as laser beam irradiation of bimetallic PtPd 73 and PtAg nanourchains, 74 hydrothermal method of Pt/Ti 0.9 Ir 0.1 O 2 , 75 layer‐by‐layer (LbL) deposition approach of a bimetallic Pt ‐ MoS 2 , 76 wet chemical etching technique of 3D PtAu nanoframe, 77 and electrodeposition techniques of Pt/MCM ‐ 41/C 78 and Pt/GO ‐ ZSM ‐ 5 79 . Thus, CH 3 OH in contact with Pt NPs synthesized using SC bagasse extract, demonstrated a superior electron transport efficiency during MOR.…”

Section: Resultsmentioning

confidence: 99%

Enhanced performance of methanol oxidation reaction via green synthesis of platinum electro‐catalyst from sugar cane bagasse

et al. 2021

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Summary Platinum‐based catalysts are regarded as premier anodic electrocatalysts in direct methanol fuel cells due to their great catalytic activities but hampered by its non‐benign conventional synthesis, and high production expenses. This study exploited a new sustainable pathway of a biosynthesis route using the biomass plant extract of sugarcane bagasse in a facile single‐step process guided by the principle of green chemistry performing enhanced functionalized bio‐platinum nanoparticles. The physiochemical characterization, along with the bio‐reductive mechanism were comprehensively discussed. The electrochemical activity was performed by cyclic voltammetry, chronoamperometry, and electrochemical impedance spectroscopy measurements. The novel nano‐spheroid biosynthesized Pt NPs manifested a high ECSA of approximately 95 m2/g with an enhanced current density of 400 mA/mgcatalyst−1, which were 3 to 4 times higher than those of Pt black commercial. The discovery of bioactive compounds from the dominant group of polyphenolics, flavonoids, carboxylic acids, and proteins suggested that they were accountable for the bio‐reductive mechanism.

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“…Therefore, designing robust support is necessary for the next-generation development of renewable and sustainable energy-related conversion technologies. Recently, our group successfully fabricated Ir-doped TiO 2 material via a green hydrothermal method that served as efficient catalyst support for Pt nanoparticles (NPs) for the alcohol electro-oxidation process [16,17]. The Pt NPs/Irdoped TiO 2 catalyst exhibited high CO-tolerance and great electrochemical durability compared to the commercially available C-supported Pt (NPs) catalyst, which was attributable to the synergistic effects and SMSI between Ir-doped TiO 2 and Pt NPs.…”

Section: Introductionmentioning

confidence: 99%

Synthesis and characterization of Ti_0.9Ir_0.1O₂-activated carbon composite as a promising support for catalysts in electrochemical energy conversion

Pham¹,

Pham²,

Huynh³

et al. 2023

Adv. Nat. Sci: Nanosci. Nanotechnol.

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Constructing robust support plays a key role in governing the overall catalytic efficiency of metal-based catalysts for electrochemical reactions in sustainable energy-related conversion systems. We herein use a solvothermal method to assemble Ti0.9Ir0.1O2-Activated C composites, exhibiting high surface area and electrical conductivity compared to the pure TiO2 material. The material characterisations and electrochemical behaviours of the as-obtained composites are systemically studied by XRD, FE-SEM-EDX mapping, FT-IR, XPS, BET, four-point technique, cyclic voltammetry, etc Notably, the effect of composition on the physical and electrochemical properties of the as-made composites is also explored, which indicated the significant improvement in surface area and electrical conductivity with increasing carbon content, while a reverse trend is observed in the electrochemical durability. Among all studied composites, the Ti0.9Ir0.1O2-Activated C (50:50 wt%) composite can be a suitable support for metal-based catalysts due to its balance in physical properties (electrical conductivity of 1.5 S cm−1 and surface area of 152.12 m2 g−1) and electrochemical corrosion resistance (high durability after 2000-cycling ADT). This study can open up an efficient strategy to enhance the catalytic performance of electrochemical processes.

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High conductivity of novel Ti0.9Ir0.1O2 support for Pt as a promising catalyst for low-temperature fuel cell applications

Cited by 16 publications

References 39 publications

Rutile Ti_0.9Ir_0.1O₂‐Supported Low Pt Loading: An Efficient Electrocatalyst for Ethanol Electrochemical Oxidation in Acidic Media

Rutile Ti_0.9Ir_0.1O₂‐Supported Low Pt Loading: An Efficient Electrocatalyst for Ethanol Electrochemical Oxidation in Acidic Media

Enhanced performance of methanol oxidation reaction via green synthesis of platinum electro‐catalyst from sugar cane bagasse

Synthesis and characterization of Ti_0.9Ir_0.1O₂-activated carbon composite as a promising support for catalysts in electrochemical energy conversion

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High conductivity of novel Ti0.9Ir0.1O2 support for Pt as a promising catalyst for low-temperature fuel cell applications

Cited by 16 publications

References 39 publications

Rutile Ti0.9Ir0.1O2‐Supported Low Pt Loading: An Efficient Electrocatalyst for Ethanol Electrochemical Oxidation in Acidic Media

Rutile Ti0.9Ir0.1O2‐Supported Low Pt Loading: An Efficient Electrocatalyst for Ethanol Electrochemical Oxidation in Acidic Media

Enhanced performance of methanol oxidation reaction via green synthesis of platinum electro‐catalyst from sugar cane bagasse

Synthesis and characterization of Ti0.9Ir0.1O2-activated carbon composite as a promising support for catalysts in electrochemical energy conversion

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Rutile Ti_0.9Ir_0.1O₂‐Supported Low Pt Loading: An Efficient Electrocatalyst for Ethanol Electrochemical Oxidation in Acidic Media

Rutile Ti_0.9Ir_0.1O₂‐Supported Low Pt Loading: An Efficient Electrocatalyst for Ethanol Electrochemical Oxidation in Acidic Media

Synthesis and characterization of Ti_0.9Ir_0.1O₂-activated carbon composite as a promising support for catalysts in electrochemical energy conversion