A review of carbon-based and non-carbon-based catalyst supports for the selective catalytic reduction of nitric oxide

Anthonysamy, Shahreen Binti Izwan; Afandi, Syahidah Binti; Khavarian, Mehrnoush; Mohamed, Abdul Rahman

doi:10.3762/bjnano.9.68

Cited by 33 publications

(11 citation statements)

References 156 publications

(195 reference statements)

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“…However, few studies have examined AC-supported transition metal oxides during HC-SCR reactions [7]. Because MnOx has exhibited promising low-temperature HC-SCR reactivity and AC supports have excellent stability and low rates of ammonium salts accumulation [25,50,57,58], this study aimed to investigate the low-temperature catalytic performance of manganese/AC catalysts while using C 2 H 4 as a reductant. Besides the reaction testing, deactivation mechanisms were also examined using SEM/EDS, X-ray diffraction (XRD), Raman spectroscopy, transmission electron microscope and selected area electron diffraction (TEM-SAED), and X-ray photoelectron spectrometer (XPS).…”

Section: Introductionmentioning

confidence: 99%

Performance of C2H4 Reductant in Activated-Carbon- Supported MnOx-based SCR Catalyst at Low Temperatures

et al. 2018

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Hydrocarbons as reductants show promising results for replacing NH3 in SCR technology. Therefore, considerable interest exists for developing low-temperature (<200 °C) and environmentally friendly HC-SCR catalysts. Hence, C2H4 was examined as a reductant using activated-carbon-supported MnOx-based catalyst in low-temperature SCR operation. Its sensitivity to Mn concentration and operating temperature was parametrically studied, the results of which showed that the catalyst activity followed the order of 130 °C > 150 °C > 180 °C with an optimized Mn concentration near 3.0 wt.%. However, rapid deactivation of catalytic activity also occurred when using C2H4 as the reductant. The mechanism of deactivation was explored and is discussed herein in which deactivation is attributed to two factors. The manganese oxide was reduced to Mn3O4 during reaction testing, which contained relatively low activity compared to Mn2O3. Also, increased crystallinity of the reduced manganese and the formation of carbon black occurred during SCR reaction testing, and these constituents on the catalyst’s surface blocked pores and active sites from participating in catalytic activity.

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Section: Introductionmentioning

confidence: 99%

Performance of C2H4 Reductant in Activated-Carbon- Supported MnOx-based SCR Catalyst at Low Temperatures

et al. 2018

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“…Type of catalyst supports play important roles in both activity and mechanical strength of catalysts, since they influence not only the morphology and dispersion of catalyst particles but also the activity of catalysts. [44][45][46] Many studies of graphene oxide (GO) as catalyst support, which is prepared by chemical oxidation of natural graphite followed by exfoliation, seems to be more fascinating due to its abundant functional groups, including COOH and OH, as well as its unique 2D structure. [47][48][49] Zhang et al reported that GO can probably provide efficient nucleation sites and enhance the MOFs growth, while offered higher dispersive forces of MOFs.…”

Section: Introductionmentioning

confidence: 99%

Fabrication of Graphene Oxide Supported Acid–Base Bifunctional Metal–Organic Frameworks as Efficient Catalyst for Glucose to 5‐Hydroxymethylfurfural Conversion

Wei

Zhang

et al. 2020

Energy Tech

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Developing a supported‐type metal–organic frameworks (MOFs) catalyst with multifunctional active sites is essential to broaden its application as a heterogeneous catalyst. Herein, polydopamine (PDA)‐modified graphene oxide (PDA@GO) is used as a support to prepare an acid–base bifunctional UiO‐66‐type MOFs catalyst in green solution (aqueous solution) through a one‐pot method. By adjusting the amount between GO, PDA, UiO‐66‐NH2, and UiO‐66‐SO3H, the heterogeneous solid catalyst UiO‐66‐SO3H‐NH2/PDA@GO with uniform distribution of MOFs can be obtained. The morphology and various properties of the catalyst are characterized and the catalytic performance of the catalyst for the conversion of glucose to 5‐hydroxymethylfurfural (5‐HMF) is demonstrated and discussed. Herein, the supported‐type MOFs catalyst offers an alternative way to promote current acid–base catalytic systems for achieving efficient production of 5‐HMF from sustainable biomass.

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“…Recently, carbon materials such as graphene, graphene oxide, carbon quantum dots, graphene quantum dots, carbon nanotubes, and graphitic carbon nitride have emerged as a new class of materials for energy conversion and storage devices such as supercapacitors [27,28], batteries [29,30], catalysts [31,32], and photovoltaic devices [33,34]. Because of their tunable optical and electrical properties, carbon materials have been thoroughly investigated as either hole transport layers or electron transport layers in solar cells [35].…”

Section: Introductionmentioning

confidence: 99%

Recent Progress in Carbon-Based Buffer Layers for Polymer Solar Cells

Nguyen

et al. 2019

Polymers

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Carbon-based materials are promising candidates as charge transport layers in various optoelectronic devices and have been applied to enhance the performance and stability of such devices. In this paper, we provide an overview of the most contemporary strategies that use carbon-based materials including graphene, graphene oxide, carbon nanotubes, carbon quantum dots, and graphitic carbon nitride as buffer layers in polymer solar cells (PSCs). The crucial parameters that regulate the performance of carbon-based buffer layers are highlighted and discussed in detail. Furthermore, the performances of recently developed carbon-based materials as hole and electron transport layers in PSCs compared with those of commercially available hole/electron transport layers are evaluated. Finally, we elaborate on the remaining challenges and future directions for the development of carbon-based buffer layers to achieve high-efficiency and high-stability PSCs.

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A review of carbon-based and non-carbon-based catalyst supports for the selective catalytic reduction of nitric oxide

Cited by 33 publications

References 156 publications

Performance of C2H4 Reductant in Activated-Carbon- Supported MnOx-based SCR Catalyst at Low Temperatures

Performance of C2H4 Reductant in Activated-Carbon- Supported MnOx-based SCR Catalyst at Low Temperatures

Fabrication of Graphene Oxide Supported Acid–Base Bifunctional Metal–Organic Frameworks as Efficient Catalyst for Glucose to 5‐Hydroxymethylfurfural Conversion

Recent Progress in Carbon-Based Buffer Layers for Polymer Solar Cells

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