π–π Electron Conjugation-Assisted Synthesis of a Robust Heterostructured CoO-MoO2 Catalyst: Accelerated Ammonia Borane Hydrolysis for Hydrogen Evolution

IF 5.1 3区材料科学 Q1 CHEMISTRY, MULTIDISCIPLINARY

Nanoscale Pub Date : 2025-10-09 DOI:10.1039/d5nr03458b

junrui Zhang, Nuo Lei, Yunqi Jia, Sheng-Rong Guo, Liuzhang Ouyang, Xuezhang Xiao

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引用次数: 0

Abstract

Heterostructured multicomponent catalysts can be developed to exploit their unique interfacial effects for enhancing their catalytic activities by optimizing their electronic structures. However, precisely fabricating heterostructures remains challenging owing to the complex interfacial properties and compatibility problems between the different materials. To address these challenges, the carbothermal shock (CTS) method was employed to produce robust heterostructured CoO-MoO2 catalysts supported on C (CoO-MoO2@C) with the aid of the extensive π–π electron conjugation of organic components. Co-based ZIF-67, which is a typical metal-organic framework, and molybdenum acetylacetonate were used as Co and Mo sources, respectively. The strong coupling between the π-electrons of the organic ligands and ultrafast Joule heating during CTS improved the interfacial compatibility between the Co and Mo oxides, leading to a significantly enhanced catalytic activity. The heterostructured CoO-MoO2@C catalyst exhibited a turnover frequency of 55.4 min⁻¹ in NH3BH3 hydrolysis for H2 production, displaying an improvement of 85.9% over that of the single-component CoO catalyst produced under equivalent conditions. Notably, the activation energy of CoO-MoO2@C was 29.3 kJ·mol–1. In addition, we proposed a novel descriptor, i.e., the “activity-activation energy quotient,” to comprehensively evaluate the energy efficiencies of catalysts in designing a low-energy-consumption catalyst. CoO-MoO2@C exhibited an activity-activation energy quotient of 1.89 min⁻¹·kJ⁻¹·mol, surpassing those of most reported Co-Mo-based catalysts. In summary, this study offers an advanced strategy for use in the structural design and precise fabrication of efficient non-noble-metal catalysts.

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π -π电子共轭辅助合成坚固异质结构CoO-MoO2催化剂：加速氨硼烷水解析氢

异质结构多组分催化剂可以利用其独特的界面效应，通过优化其电子结构来提高其催化活性。然而，由于不同材料之间复杂的界面性质和相容性问题，精确制造异质结构仍然具有挑战性。为了解决这些问题，利用有机组分广泛的π -π电子共轭作用，采用碳热冲击（CTS）方法制备了负载在C （CoO-MoO2@C）上的异质结构CoO-MoO2催化剂。以典型的金属有机骨架——Co基ZIF-67为Co源，以乙酰丙酮钼为Mo源。在CTS过程中，有机配体π电子之间的强耦合和超快焦耳加热改善了Co和Mo氧化物之间的界面相容性，导致催化活性显著增强。异质结构CoO-MoO2@C催化剂在NH3BH3水解制H2时的周转频率为55.4 min⁻¹，比同等条件下生产的单组分CoO催化剂提高了85.9%。值得注意的是，CoO-MoO2@C的活化能为29.3 kJ·mol-1。此外，我们提出了一个新的描述符，即“活性-活化能商”，以综合评估催化剂的能源效率，以设计低能耗催化剂。CoO-MoO2@C的活化能商为1.89 min⁻¹·kJ⁻¹·mol，超过了大多数报道的co - mo基催化剂。总之，本研究为高效非贵金属催化剂的结构设计和精确制造提供了一种先进的策略。

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来源期刊

Nanoscale CHEMISTRY, MULTIDISCIPLINARY-NANOSCIENCE & NANOTECHNOLOGY

CiteScore

12.10

自引率

3.00%

发文量

1628

审稿时长

1.6 months

期刊介绍： Nanoscale is a high-impact international journal, publishing high-quality research across nanoscience and nanotechnology. Nanoscale publishes a full mix of research articles on experimental and theoretical work, including reviews, communications, and full papers.Highly interdisciplinary, this journal appeals to scientists, researchers and professionals interested in nanoscience and nanotechnology, quantum materials and quantum technology, including the areas of physics, chemistry, biology, medicine, materials, energy/environment, information technology, detection science, healthcare and drug discovery, and electronics.