Exploring transition metal (Cr, Mn, Fe, Co, Ni) promoted copper-catalyst for carbon dioxide hydrogenation to methanol

6TH INTERNATIONAL CONFERENCE ON ENVIRONMENT (ICENV2018): Empowering Environment and Sustainable Engineering Nexus Through Green Technology Pub Date : 2019-07-24 DOI:10.1063/1.5117066

M. Koh, M. Zain, A. Mohamed

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引用次数: 8

Abstract

Methanol production from direct CO2 hydrogenation has been widely envisaged to have key role in promoting CO2 utilization. The approach is a serious option in alleviating global warming, thus, contributing to sustainable development. However, the efficiency of methanol production from direct CO2 hydrogenation is highly dependent on the reactivity of catalyst. In this study, the structure-activity relationships of transition metal (Cr, Mn, Fe, Co, Ni) promoted copper-catalyst in direct CO2 hydrogenation to methanol were established by a systematic comparison between the synthesized catalysts. The copper-catalyst used in the study was Cu/ZnO/SBA-15 (CZ/SBA-15). Catalytic performance of all the synthesized catalysts was evaluated in a continuous-flow fixed-bed micro-reactor under kinetic-controlled conditions. Overall, the manganese promoted copper-catalyst (Mn-CZ/SBA-15) was determined as the most active catalyst. The outstanding performance of Mn-CZ/SBA-15 was due to the jointly presence of small copper crystallites and strong interaction between copper oxide and other oxide species in the catalyst. At reaction temperature of 180°C, under reaction pressure of 4.0 MPa, WHSV of 60 L/gcat.h, and H2:CO2 mole ratio of 3:1, the catalyst presented the highest methanol yield of 10.4%. The CO2 conversion achieved was 10.5% and the methanol selectivity was 98.6%.Methanol production from direct CO2 hydrogenation has been widely envisaged to have key role in promoting CO2 utilization. The approach is a serious option in alleviating global warming, thus, contributing to sustainable development. However, the efficiency of methanol production from direct CO2 hydrogenation is highly dependent on the reactivity of catalyst. In this study, the structure-activity relationships of transition metal (Cr, Mn, Fe, Co, Ni) promoted copper-catalyst in direct CO2 hydrogenation to methanol were established by a systematic comparison between the synthesized catalysts. The copper-catalyst used in the study was Cu/ZnO/SBA-15 (CZ/SBA-15). Catalytic performance of all the synthesized catalysts was evaluated in a continuous-flow fixed-bed micro-reactor under kinetic-controlled conditions. Overall, the manganese promoted copper-catalyst (Mn-CZ/SBA-15) was determined as the most active catalyst. The outstanding performance of Mn-CZ/SBA-15 was due to the jointly presence of small copper cr...

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探索过渡金属(Cr, Mn, Fe, Co, Ni)对铜催化二氧化碳加氢制甲醇的促进作用

二氧化碳直接加氢制甲醇已被广泛认为在促进二氧化碳利用方面具有关键作用。这种办法是缓解全球变暖的一个严肃的选择，从而有助于可持续发展。然而，二氧化碳直接加氢制甲醇的效率高度依赖于催化剂的反应性。本研究通过对合成的催化剂进行系统比较，建立了过渡金属(Cr, Mn, Fe, Co, Ni)促进铜催化剂在CO2直接加氢制甲醇中的构效关系。研究中使用的铜催化剂为Cu/ZnO/SBA-15 (CZ/SBA-15)。在动力学控制条件下，在连续流固定床微反应器中对合成催化剂的催化性能进行了评价。总体而言，锰促进铜催化剂(Mn-CZ/SBA-15)是最具活性的催化剂。Mn-CZ/SBA-15的优异性能是由于催化剂中存在小的铜晶以及氧化铜与其他氧化物之间的强相互作用。在反应温度为180℃，反应压力为4.0 MPa, WHSV为60 L/gcat.h, H2:CO2摩尔比为3:1的条件下，该催化剂的甲醇收率最高，为10.4%。CO2转化率为10.5%，甲醇选择性为98.6%。二氧化碳直接加氢制甲醇已被广泛认为在促进二氧化碳利用方面具有关键作用。这种办法是缓解全球变暖的一个严肃的选择，从而有助于可持续发展。然而，二氧化碳直接加氢制甲醇的效率高度依赖于催化剂的反应性。本研究通过对合成的催化剂进行系统比较，建立了过渡金属(Cr, Mn, Fe, Co, Ni)促进铜催化剂在CO2直接加氢制甲醇中的构效关系。研究中使用的铜催化剂为Cu/ZnO/SBA-15 (CZ/SBA-15)。在动力学控制条件下，在连续流固定床微反应器中对合成催化剂的催化性能进行了评价。总体而言，锰促进铜催化剂(Mn-CZ/SBA-15)是最具活性的催化剂。Mn-CZ/SBA-15的优异性能是由于少量铜离子的共同存在。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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6TH INTERNATIONAL CONFERENCE ON ENVIRONMENT (ICENV2018): Empowering Environment and Sustainable Engineering Nexus Through Green Technology

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