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Tiny Ni Nanoparticles Embedded in Boron- and Nitrogen-Codoped Porous Carbon Nanowires for High-Efficiency Water Splitting

Fei Guo, Zhuo Liu, Yiyong Zhang, Yiyong Zhang, Jie Xiao, Xiaoyuan Zeng, Chengxu Zhang, Peng Dong, Tingting Liu, Yingjie Zhang, Yingjie Zhang, Mian Li

2022ACS Applied Materials & Interfaces44 citationsDOI

Abstract

The integration of nickel (Ni) nanoparticle (NP)-embedded carbon layers (Ni@C) into the three-dimensional (3D) hierarchically porous carbon architectures, where ultrahigh boron (B) and nitrogen (N) doping is a potential methodology for boosting Ni catalysts’ water splitting performances, was achieved. In this study, the novel 3D ultrafine Ni NP-embedded and B- and N-codoped hierarchically porous carbon nanowires (denoted as Ni@BNPCFs) were successfully synthesized via pyrolysis of the corresponding 3D nickel acetate [Ni(AC)2·4H2O]-hydroxybenzeneboronic acid–polyvinylpyrrolidone precursor networks woven by electrospinning. After optimizing the pyrolysis temperatures, various structural and morphological characterization analyses indicate that the optimal Ni@BNPCFs-900 networks own a large surface area, abundant micro/mesopores, and vast carbon edges/defects, which boost doping a large amount of B (5.81 atom %) and N (5.84 atom %) dopants into carbon frameworks with 6.36 atom % of BC3, pyridinic-N (pyridinic-N–Ni), and graphitic-N active sites. Electrochemical measurements demonstrate that Ni@BNPCFs-900 reveals the best hydrogen evolution reaction (HER) and oxygen reduction reaction catalytic activities in an alkaline solution. The HER potential at 10 mA cm–2 [E10 = −164.2 mV vs reversible hydrogen electrode (RHE)] of the optimal Ni@BNPCFs-900 is just 96.2 mV more negative than that of the state-of-the-art 20 wt % Pt/C (E10 = −68 mV vs RHE). In particular, the OER E10 and Tafel slope of the optimal Ni@BNPCFs-900 (1.517 V vs RHE and 19.31 mV dec–1) are much smaller than those of RuO2 (1.557 V vs RHE and 64.03 mV dec–1). For full water splitting, the catalytic current density achieves 10 mA cm–2 at a low cell voltage of 1.584 V for the (−) Ni@BNPCFs-900||Ni@BNPCFs-900 (+) electrolysis cell, which is 10 mV smaller than that of the (−) 20 wt % Pt/C||RuO2 (+) benchmark (1.594 V) under the same conditions. The synergistic effects of 3D hierarchically porous structures, advanced charge transport ability, and abundant active centers [such as Ni@BNC, BC3, pyridinic-N (pyridinic-N–Ni), and graphitic-N] are responsible for the excellent water-splitting catalytic activity of the Ni@BNPCFs-900 networks. Especially, because of the remarkable structural and chemical stabilities of 3D hierarchically porous Ni@BNPCFs-900 networks, the (−) Ni@BNPCFs-900||Ni@BNPCFs-900 (+) water electrolysis cell displays an excellent stability.

Topics & Concepts

Materials scienceNickelWater splittingTafel equationChemical engineeringNanoparticleCatalysisReversible hydrogen electrodeCarbon fibersNanowireMesoporous materialBoronPyrolysisDopantElectrochemistryNanotechnologyInorganic chemistryDopingElectrodePhysical chemistryMetallurgyComposite materialOrganic chemistryWorking electrodePhotocatalysisChemistryComposite numberOptoelectronicsEngineeringElectrocatalysts for Energy ConversionAdvanced battery technologies researchAdvancements in Battery Materials
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