AI Article Synopsis
- Researchers developed stable and active low-temperature CO oxidation catalysts using cobalt oxide nanoparticles without noble metals, aiming for sustainability.
- The study produced 100 nm raspberry-shaped Co₃O₄ nanoparticles with high surface area and oxygen vacancies by treating cobalt glycolate with sodium sulfate, successfully controlling their complex structure.
- The resulting Co₃O₄ nano-raspberry demonstrated remarkable stability and nearly 100% CO conversion at room temperature, highlighting the effectiveness of bridging ligands in nanoscale synthesis.
Article Abstract
Highly stable and active low-temperature CO oxidation catalysts without noble metals are desirable to achieve a sustainable society. While zero-dimensional to three-dimensional Co₃O₄ nanoparticles show high catalytic activity, simple-structured nanocrystals easily self-aggregate and become sintered during catalytic reaction. Thus, complex three-dimensional nanostructures with high stability are of considerable interest. However, the controlled synthesis of complex nanoscale shapes remains a great challenge as no synthesis theory has been established. In this study, 100 nm raspberry-shaped nanoparticles composed of 7⁻8 nm Co₃O₄ nanoparticles were synthesized by hydrothermally treating cobalt glycolate solution with sodium sulfate. Surface single nanometer-scale structures with large surface areas of 89 m²·g and abundant oxygen vacancies were produced. The sulfate ions functioned as bridging ligands to promote self-assembly and suppress particle growth. The Co₃O₄ nano-raspberry was highly stable under catalytic tests at 350 °C and achieved nearly 100% CO conversion at room temperature. The addition of bridging ligands is an effective method to control the formation of complex but ordered three-dimensional nanostructures that possessed extreme thermal and chemical stability and exhibited high performance.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC6164048 | PMC |
| http://dx.doi.org/10.3390/nano8090662 | DOI Listing |
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