Self-assembled Platinum-iridium Alloy Aerogels and Their Efficient Electrocatalytic Ammonia Oxidation Performance

Xiangsong ZHANG; Yetong LIU; Yongying WANG; Zirui WU; Zhenzhong LIU; Yi LI; Juan YANG

doi:10.15541/jim20220684

[1] Y LI, H H WANG, C PRIEST et al. Advanced electrocatalysis for energy and environmental sustainability via water and nitrogen reactions. Adv. Mater., 2000(2020).

[2] H JIN, S LEE, Y SOHN. Capping agent-free synthesis of surface engineered Pt nanocube for direct ammonia fuel cell. Int. J. Energy Res., 18281(2021).

[3] Y LI, H S PILLAI, T WANG et al. High-performance ammonia oxidation catalysts for anion-exchange membrane direct ammonia fuel cells. Energy Environ. Sci., 1449(2021).

[4] Y LI, X LI, H S PILLAI et al. Ternary PtIrNi catalysts for efficient electrochemical ammonia oxidation. ACS Catal., 3945(2020).

[5] Y ZHAO, B P SETZLER, J H WANG et al. An efficient direct ammonia fuel cell for affordable carbon-neutral transportation. Joule, 2472(2019).

[6] H S PILLAI, H XIN. New insights into electrochemical ammonia oxidation on Pt(100) from first principles. Ind. Eng. Chem. Res., 10819(2019).

[7] Y M KANG, W WANG, J M LI et al. High performance Pt_xEu alloys as effective electrocatalysts for ammonia electro-oxidation. Int. J. Hydrogen. Energy, 18959(2017).

[8] Q XUE, Y ZHAO, J Y ZHU et al. PtRu nanocubes as bifunctional electrocatalysts for ammonia electrolysis. J. Mater. Chem. A, 8444(2021).

[9] R Y CHEN, S S ZHENG, Y D YAO et al. Performance of direct ammonia fuel cell with PtIr/C, PtRu/C, and Pt/C as anode electrocatalysts under mild conditions. Int. J. Hydrogen. Energy, 27749(2021).

[10] S GOTTESFELD. The direct ammonia fuel cell and a common pattern of electrocatalytic processes. J. Electrochem. Soc., J3405(2018).

[11] L SONG, Z X LIANG, Z MA et al. Temperature-dependent kinetics and reaction mechanism of ammonia oxidation on Pt, Ir, and PtIr alloy catalysts. J. Electrochem. Soc., 3095(2018).

[12] N SACRE, M DUCA, S GARBARION et al. Tuning Pt-Ir interactions for NH₃ electrocatalysis. ACS Catal., 2508(2018).

[13] A ESTEJAB, G BOTTE. Ammonia oxidation kinetics on bimetallic clusters of platinum and iridium: a theoretical approach. Mol. Catal., 279(2018).

[14] A S DOUK, H SARAVANI. Porous 3D inorganic superstructure of Pd-Ir aerogel as advanced support-less anode electrocatalyst toward ethanol oxidation. ACS Omega, 22031(2020).

[15] C ZHU, D DU, A EYCHMULLER. Engineering ordered and nonordered porous noble metal nanostructures: synthesis, assembly, and their applications in electrochemistry. Chem. Rev., 8896(2015).

[16] C Z ZHU, S J GUO, S J DONG. PdM (M= Pt, Au) bimetallic alloy nanowires with enhanced electrocatalytic activity for electro- oxidation of small molecules. Adv. Mater., 2326(2012).

[17] B CAI, A DIANAT, R HUBNER et al. Multimetallic hierarchical aerogels: shape engineering of the building blocks for efficient electrocatalysis. Adv. Mater., 160(2017).

[18] FEI HE, YA LI, JIN LUO et al. Development of SiO₂/C and SiC/C composites featuring aerogel structures. J. Inorg. Mater., 449(2017).

[19] W LIU, A K HERRMAANN, N C BIGALL et al. Noble metal aerogels-synthesis, characterization, and application as electrocatalysts. Acc. Chem. Res., 154(2015).

[20] S RAJIB, A F AHMED, U A INDIKA. Oxidative self-assembly of Au/Ag/Pt alloy nanoparticles into high-surface area, mesoporous, and conductive aerogels for methanol electro-oxidation. Chem. Mater., 5874(2022).

[21] W LIU, D HAUBOLD, B RUTKOWSKI et al. Self-supporting hierarchical porous PtAg alloy nanotubular aerogels as highly active and durable electrocatalysts. Chem. Mater., 6477(2016).

[22] A S DOUK, H SARAVANI, M NOROOZIFAR. Three-dimensional assembly of building blocks for the fabrication of Pd aerogel as a high performance electrocatalyst toward ethanol oxidation. Electrochim. Acta, 182(2018).

[23] ZI YE LYU, YI PING TANG, HUA ZHEN CAO et al. Effect of V doping on electrocatalytic performance of Ni-Co-S on bacterial cellulose-derived carbon aerogel. J. Inorg. Mater., 1142(2020).

[24] B CAI, V SAYEVICH, N GAPONIK et al. Emerging hierarchical aerogels: self-assembly of metal and semiconductor nanocrystals. Adv. Mater., 17075(2018).

[25] F J BURPO, E A NAGELLI, L A MORRIS et al. Direct solution-based reduction synthesis of Au, Pd, and Pt aerogels. J. Mater. Res., 4153(2017).

[26] B Q MIAO, Y C LIU, Y DING et al. Rhodium nanodendrites catalyzed alkaline methanol oxidation reaction in direct methanol fuel cells. SM&T, e00379(2022).

[27] J MIAO, X J ZHAO, H Y HU et al. Porous palladium phosphide nanotubes for formic acid electrooxidation. Carbon Energy, 283(2022).

[28] Z QIAO, S WANG, X LI et al. 3D porous graphitic nanocarbon for enhancing the performance and durability of Pt catalysts: a balance between graphitization and hierarchical porosity. Energy Environ. Sci., 2830(2019).

[29] Q T LIU, Y C LI, L R ZHENG et al. Sequential synthesis and active-site coordination principle of precious metal single-atom catalysts for oxygen reduction reaction and PEM fuel cells. Adv. Energy Mater., 2000689(2020).

[30] N ALMANA, S P PHIVILAY, P LAVEILLE et al. Design of a core-shell Pt-SiO₂ catalyst in a reverse microemulsion system: distinctive kinetics on CO oxidation at low temperature. J. Catal., 368(2016).

[31] K SIDDHARTH, Y M HONG, X P QIN et al. Surface engineering in improving activity of Pt nanocubes for ammonia electrooxidation reaction. Appl. Catal. B, 118821(2020).

[32] A ESTEJAB, G G. BOTTE. DFT calculations of ammonia oxidation reactions on bimetallic clusters of platinum and iridium. Comput. Theor. Chem., 31(2016).

[33] Y T CHAN, K SIDDHARTH, M H SHAO. Investigation of cubic Pt alloys for ammonia oxidation reaction. Nano Res., 1920(2020).

[34] Z Z LIU, Y LI, X S ZHANG et al. Surface structure engineering of PtPd nanoparticles for boosting ammonia oxidation electrocatalysis. ACS Appl. Mater. Interfaces, 28816(2022).