Investigation of the effect of thermal annealing of Ni-cobaltite nanoparticles on their structure, electronic properties and performance as catalysts for the total oxidation of dimethyl ether†

IF 4.4 3区 化学 Q2 CHEMISTRY, PHYSICAL Catalysis Science & Technology Pub Date : 2023-09-11 DOI:10.1039/D3CY00807J
Daniel Onana Mevoa, Stephane Kenmoe, Muhammad Waqas, Dick Hartmann Douma, Daniel Manhouli Daawe, Katia Nchimi Nono, Ralph Gebauer and Patrick Mountapmbeme Kouotou
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Abstract

Herein, we report the influence of thermal annealing on the structural and redox properties, optical band gap (EOptg) and electrical conductivity (σ) of Ni-doped Co3O4 nanoparticles (NPs). The influence of annealing on the catalytic performance is also studied. Coprecipitation technique was employed to prepare single oxides (Ni2O3 and Co3O4) and Ni-cobaltite oxides (NiCo2O4), which were annealed at different temperatures. The samples were characterized in terms of structure (XRD), surface specific area (SBET), morphology (SEM), chemical composition (EDS/XPS), redox properties (H2-TPR), optical band gap (EOptg) and conductivity σ. In addition, the conversion of dimethyl ether (DME) was achieved over all samples at low temperature. Overall, NiCo2O4 exhibits outstanding catalytic behaviour, surpassing single oxides. However, a notable difference in performance among NiCo2O4 samples was observed. The catalytic behaviour is discussed with respect to the quality of reducibility, the ratio of active species (OLat/OAds), the lowest EOptg and the good σ. H2-TPR, EOptg and σ analysis were used to gain a deeper insight into the reaction process occurring at the surface of each of the catalysts. NiCo2O4 samples annealed at 450 and 500 °C cannot be reduced in the reaction temperature range (150 to 225 °C), suggesting that the process occurs via a surface mechanism. However, NiCo2O4 annealed at 350 °C is reduced under the reaction conditions within the temperature range from 200 to 350 °C, attesting that DME oxidation proceeds through an intrafacial redox process in this case. Using density functional theory (DFT) calculations, the adsorption and dissociation of DME on the catalytically relevant NiCo2O4 (001) surface was investigated. DME adsorbs preferentially on top the Co3+ site in a degenerate state: intact and single dehydrogenated molecules have very similar binding energies (−0.76 eV and −0.77 eV, respectively). The presence of surface vacancies in the vicinity of the adsorption site leads to the most interesting catalytic pathway. The activation energy for the dehydrogenation of one DME carbonyl group, considered as the first step to the complete oxidation, shows a lower value on the half-metallic surface with vacancies (0.9 eV) compared to 1.5 eV on the vacancy-free metallic surface.

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镍钴酸盐纳米颗粒的热退火对其结构、电子性能和作为二甲醚全氧化催化剂性能的影响的研究†
在此,我们报道了热退火对Ni掺杂的Co3O4纳米颗粒(NP)的结构和氧化还原性能、光学带隙(EOptg)和电导率(σ)的影响。还研究了退火对催化剂性能的影响。采用共沉淀技术制备了单体氧化物(Ni2O3和Co3O4)和钴酸镍氧化物(NiCo2O4),并在不同温度下进行了退火处理。对样品的结构(XRD)、比表面积(SBET)、形貌(SEM)、化学成分(EDS/XPS)、氧化还原性能(H2-TPR)、光学带隙(EOptg)和电导率σ进行了表征。此外,在低温下,所有样品都实现了二甲醚(DME)的转化。总的来说,NiCo2O4表现出卓越的催化性能,超过了单一氧化物。然而,在NiCo2O4样品之间观察到显著的性能差异。从还原性的质量、活性物质的比例(OLat/OAds)、最低EOptg和良好的σ等方面讨论了催化行为。H2-TPR、EOptg和σ分析用于深入了解每种催化剂表面发生的反应过程。在450和500°C下退火的NiCo2O4样品在反应温度范围(150至225°C)内不能还原,这表明该过程是通过表面机制发生的。然而,在200至350°C的温度范围内的反应条件下,在350°C下退火的NiCo2O4被还原,证明DME氧化在这种情况下是通过面内氧化还原过程进行的。利用密度泛函理论(DFT)计算,研究了DME在催化相关的NiCo2O4(001)表面的吸附和离解。DME以简并态优先吸附在Co3+位点的顶部:完整和单个脱氢分子具有非常相似的结合能(分别为-0.76 eV和-0.77 eV)。吸附位点附近表面空位的存在导致了最有趣的催化途径。一个DME羰基脱氢的活化能被认为是完全氧化的第一步,在具有空位的半金属表面上(0.9eV)显示出比在无空位的金属表面上1.5eV更低的值。
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来源期刊
Catalysis Science & Technology
Catalysis Science & Technology CHEMISTRY, PHYSICAL-
CiteScore
8.70
自引率
6.00%
发文量
587
审稿时长
1.5 months
期刊介绍: A multidisciplinary journal focusing on cutting edge research across all fundamental science and technological aspects of catalysis. Editor-in-chief: Bert Weckhuysen Impact factor: 5.0 Time to first decision (peer reviewed only): 31 days
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