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具有玉米状结构的堆叠式 NiO 纳米颗粒多孔纳米棒,用于可持续环境和能源应用。

Porous nanorods by stacked NiO nanoparticulate exhibiting corn-like structure for sustainable environmental and energy applications.

作者信息

Manjunath Vishesh, Bimli Santosh, Singh Diwakar, Biswas Rathindranath, Didwal Pravin N, Haldar Krishna Kanta, Deshpande Nishad G, Bhobe Preeti A, Devan Rupesh S

机构信息

Department of Metallurgical Engineering and Materials Science, Indian Institute of Technology Indore Khandwa Road, Simrol Indore 453552 India

Department of Chemistry, Central University of Punjab Bathinda 151001 India.

出版信息

RSC Adv. 2023 Jul 20;13(32):21962-21970. doi: 10.1039/d3ra03209d. eCollection 2023 Jul 19.

DOI:10.1039/d3ra03209d
PMID:37483671
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10357413/
Abstract

A porous 1D nanostructure provides much shorter electron transport pathways, thereby helping to improve the life cycle of the device and overcome poor ionic and electronic conductivity, interfacial impedance between electrode-electrolyte interface, and low volumetric energy density. In view of this, we report on the feasibility of 1D porous NiO nanorods comprising interlocked NiO nanoparticles as an active electrode for capturing greenhouse CO, effective supercapacitors, and efficient electrocatalytic water-splitting applications. The nanorods with a size less than 100 nm were formed by stacking cubic crystalline NiO nanoparticles with dimensions less than 10 nm, providing the necessary porosity. The existence of Ni and its octahedral coordination with O is corroborated by XPS and EXAFS. The SAXS profile and BET analysis showed 84.731 m g surface area for the porous NiO nanorods. The NiO nanorods provided significant surface-area and the active-surface-sites thus yielded a CO uptake of 63 mmol g at 273 K physisorption, a specific-capacitance () of 368 F g, along with a retention of 76.84% after 2500 cycles, and worthy electrocatalytic water splitting with an overpotential of 345 and 441 mV for HER and OER activities, respectively. Therefore, the porous 1D NiO as an active electrode shows multifunctionality toward sustainable environmental and energy applications.

摘要

一维多孔纳米结构提供了更短的电子传输路径,从而有助于改善器件的生命周期,并克服离子和电子导电性差、电极 - 电解质界面间的界面阻抗以及低体积能量密度等问题。鉴于此,我们报道了由互锁的NiO纳米颗粒组成的一维多孔NiO纳米棒作为用于捕获温室气体CO₂、高效超级电容器和高效电催化水分解应用的活性电极的可行性。尺寸小于100 nm的纳米棒是通过堆叠尺寸小于10 nm的立方晶型NiO纳米颗粒形成的,从而提供了所需的孔隙率。XPS和EXAFS证实了Ni的存在及其与O的八面体配位。SAXS图谱和BET分析表明,多孔NiO纳米棒的表面积为84.731 m²/g。NiO纳米棒具有显著的表面积和活性表面位点,因此在273 K下通过物理吸附的CO₂吸收量为63 mmol/g,比电容()为368 F/g,在2500次循环后保留率为76.84%,并且在HER和OER活性方面分别具有345和441 mV的过电位,具有值得关注的电催化水分解性能。因此,作为活性电极的一维多孔NiO对可持续环境和能源应用具有多功能性。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/b074/10357413/e61be050a983/d3ra03209d-f9.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/b074/10357413/e61be050a983/d3ra03209d-f9.jpg
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