One-pot CO2-to-olefins via methanol over In2O3-ZrO2/SAPO-34 catalysts mixtures with different spatial arrangements

IF 4.7 2区化学 Q2 CHEMISTRY, PHYSICAL

Applied Catalysis A: General Pub Date : 2024-05-15 DOI:10.1016/j.apcata.2024.119799

Alessandro Porta , Chiara Coffano , Mattia Piacentini , Francesca Rabino , Barbara Picutti , Luca Lietti , Carlo Giorgio Visconti

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引用次数: 0

Abstract

The one-pot CO₂ hydrogenation to lower olefins involves the integration of two catalytic reactions in a single reactor: the conversion of CO₂ into methanol (CTM) and its subsequent conversion into lower olefins (MTO). This approach requires two catalysts cooperating in the same reactor, posing different challenges in terms of synergies and interactions between the two active phases. In this work, we investigate the effect of process conditions and arrangements between In₂O₃-ZrO₂ (CTM catalyst) and SAPO-34 (MTO catalyst) on the lower olefins yield. We show that the distance between CTM and MTO active sites, studied by assessing different catalyst arrangements spanning from an intimate mixture obtained through mortar mixing to a complete segregation of the catalysts (i.e., consecutive beds), plays a key role in driving the products distribution. However, the thermodynamic equilibrium of the reverse water gas shift limits CO₂ conversion in the investigated conditions. Finally, we discuss the stability of the catalytic performances: the characterization of the spent samples after ∼400 h on stream indicated the deactivation of the catalytic materials in all investigated cases, with In sintering on the methanol catalyst, and SAPO-34 losing both P and Al due to hydrothermal aging; indications of In migration on SAPO-34 were also observed when the two catalyst are in contact.

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在具有不同空间排列的 In2O3-ZrO2/SAPO-34 催化剂混合物上通过甲醇进行二氧化碳制烯烃的一锅反应

一锅二氧化碳加氢制取低级烯烃涉及在一个反应器中整合两个催化反应：将二氧化碳转化为甲醇（CTM），然后再将甲醇转化为低级烯烃（MTO）。这种方法需要在同一反应器中使用两种催化剂，这对两种活性相之间的协同作用和相互作用提出了不同的挑战。在这项工作中，我们研究了 In2O3-ZrO2（CTM 催化剂）和 SAPO-34（MTO 催化剂）之间的工艺条件和排列对低烯烃产量的影响。我们通过评估不同的催化剂排列方式（从砂浆混合得到的亲密混合物到催化剂的完全分离（即连续床层）），发现 CTM 和 MTO 活性位点之间的距离在驱动产物分布方面起着关键作用。然而，在所研究的条件下，反向水气变换的热力学平衡限制了二氧化碳的转化。最后，我们讨论了催化性能的稳定性：在流式催化 400 小时后，对废样品进行的表征表明，在所有调查案例中，催化材料都发生了失活，甲醇催化剂上的铟发生了烧结，SAPO-34 因水热老化而失去了 P 和 Al；当两种催化剂接触时，还观察到 SAPO-34 上的铟迁移迹象。

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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来源期刊

Applied Catalysis A: General 化学-环境科学

CiteScore

9.00

自引率

5.50%

发文量

415

审稿时长

24 days

期刊介绍： Applied Catalysis A: General publishes original papers on all aspects of catalysis of basic and practical interest to chemical scientists in both industrial and academic fields, with an emphasis onnew understanding of catalysts and catalytic reactions, new catalytic materials, new techniques, and new processes, especially those that have potential practical implications. Papers that report results of a thorough study or optimization of systems or processes that are well understood, widely studied, or minor variations of known ones are discouraged. Authors should include statements in a separate section "Justification for Publication" of how the manuscript fits the scope of the journal in the cover letter to the editors. Submissions without such justification will be rejected without review.

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