Oxidative coupling of methane—comparisons of MnTiO3–Na2WO4 and MnOx–TiO2–Na2WO4 catalysts on different silica supports-Reference-Cited by-同舟云学术

Oxidative coupling of methane—comparisons of MnTiO3–Na2WO4 and MnOx–TiO2–Na2WO4 catalysts on different silica supports

Published:2022-02-16 Issue:1 Volume:12 Page:
ISSN:2045-2322
Container-title:Scientific Reports
language:en
Short-container-title:Sci Rep

Author:

Tiyatha Worapinit,Chukeaw Thanaphat,Sringam Sarannuch,Witoon Thongthai,Chareonpanich Metta,Rupprechter Günther,Seubsai Anusorn

Abstract

AbstractThe oxidative coupling of methane (OCM) converts CH4 to value-added chemicals (C2+), such as olefins and paraffin. For a series of MnTiO3-Na2WO4 (MnTiO3-NW) and MnOx-TiO2-Na2WO4 (Mn-Ti-NW), the effect of loading of MnTiO3 or MnOx-TiO2, respectively, on two different supports (sol–gel SiO2 (SG) and commercial fumed SiO2 (CS)) was examined. The catalyst with the highest C2+ yield (21.6% with 60.8% C2+ selectivity and 35.6% CH4 conversion) was 10 wt% MnTiO3-NW/SG with an olefins/paraffin ratio of 2.2. The catalyst surfaces with low oxygen-binding energies were associated with high CH4 conversion. Stability tests conducted for over 24 h revealed that SG-supported catalysts were more durable than those on CS because the active phase (especially Na2WO4) was more stable in SG than in CS. With the use of SG, the activity of MnTiO3-NW was not substantially different from that of Mn-Ti-NW, especially at high metal loading.

Funder

Office of the Ministry of Higher Education, Science, Research and Innovation

Thailand Science Research and Innovation through the Kasetsart University Reinventing University Program 2021

National Research Council of Thailand

Austrian Science Fund (FWF) via grant SFB TACO

Publisher

Springer Science and Business Media LLC

Subject

Multidisciplinary

Link

https://www.nature.com/articles/s41598-022-06598-6.pdf

Reference70 articles.

1. Holmen, A. Direct conversion of methane to fuels and chemicals. Catal. Today 142, 2–8 (2009).

2. IPCC. Climate Change 2013: The Physical Science Basis. (Geneva, Switzerland, 2013).

3. United States Environmental Protection Agency. Overview of Greenhouse Gases, https://www.epa.gov/ghgemissions/overview-greenhouse-gases#CH4-reference (2019).

4. Makaryan, B. I., Sedov, L. & Savchenko, V. Platinum group metal-catalysed carbonylation as the basis of alternative gas-to-liquids processes. Johnson Matthey Technol. Rev. 59, 14–25 (2015).

5. Sun, L., Wang, Y., Guan, N. & Li, L. Methane activation and utilization: Current status and future challenges. Energy Technol. 8, 201900826 (2019).

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