Pluralistic Electronic Structure Modulation of Ruthenium Oxide for Enhanced Acidic Water Electrolysis

Xiaotong Wu, Chao Lin, Weibo Hu, Chao Fu, Lei Tan, Haifeng Wang, Faiza Meharban, Xiangxiang Pan, Pan Fu, Han-Don Um, Qi Xiao, Xiaopeng Li, Miho Yamauchi, Wei Luo
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Abstract

Proton exchange membrane water electrolysis (PEMWE) with high-purity H2 and O2 products and swift response to electricity fluctuation is of great interest for renewable energy, chemical and pharmaceutical industries. Ruthenium oxide shows promise as an alternative to iridium oxide catalysts in PEMWE but suffers from severe anodic corrosion. Herein, a pluralistic electronic structure modulation approach is presented to address the instability issue of Ru, by in situ growing MnxRu1−xO2 solid solution on MnO2, coated carbon fibers (MnxRu1−xO2/MnO2/CFs). Due to higher ion electronegativity, Mn dopants in the MnxRu1−xO2 solid solution accept electrons, activating the Ru site. Simultaneously, the MnO2 support donates electrons to prevent Ru site overoxidation and dissolution due to its lower work function than the MnxRu1−xO2 solid solution. As a result, the MnxRu1−xO2/MnO2/CFs catalyst exhibits a low overpotential of 161 mV at 10 mA cm−2 and a remarkable stability exceeding 600 h. Profiting by its improved oxygen evolution reaction (OER) kinetic activity, the MnxRu1−xO2/MnO2/CF-based PEMWE shows a low cell voltage of 1.9 V at 2 A cm−2, and stably operate at current density of 500 mA cm−2 for 24 h. This work shows the potential of the pluralistic electronic structure modulation to boost activity and stability of Ru-based acidic OER electrocatalysts.

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用于增强酸性水电解的氧化钌多元电子结构调制
质子交换膜水电解法(PEMWE)可产生高纯度的 H2 和 O2 产物,并能对电力波动做出快速反应,这引起了可再生能源、化工和制药行业的极大兴趣。在 PEMWE 中,氧化钌有望成为氧化铱催化剂的替代品,但存在严重的阳极腐蚀问题。本文提出了一种多元电子结构调制方法,通过在涂有碳纤维的二氧化锰上原位生长 MnxRu1-xO2 固溶体(MnxRu1-xO2/MnO2/CFs)来解决 Ru 的不稳定性问题。由于离子电负性较高,MnxRu1-xO2 固溶体中的锰掺杂物会接受电子,从而激活 Ru 位点。与此同时,由于 MnxRu1-xO2 固溶体的功函数比 MnO2 支持物低,因此 MnO2 支持物会捐献电子以防止 Ru 位点过氧化和溶解。因此,MnxRu1-xO2/MnO2/CFs 催化剂在 10 mA cm-2 电流条件下的过电位低至 161 mV,并且具有超过 600 小时的卓越稳定性。这项工作显示了多元电子结构调制在提高 Ru 基酸性 OER 电催化剂的活性和稳定性方面的潜力。
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