催化技術,尤其是熱催化技術,是當今工業領域使用最廣泛的催化技術,在石油化工、精細化工、環境治理、下一代高性能新材料等當今世界最核心的議題中舉足輕重。無論是能源領域的石油裂解,脫硫脫硝;還是環境領域的汽車尾氣凈化,空氣凈化,水凈化;亦或是醫藥、農藥、顏料染料中間體的生產,以及汽車、光電、電池、高分子材料中間體的制造,都離不開熱催化技術。
那么,熱催化領域現在存在的關鍵問題有哪些?解決這些問題的方案有哪些?哪些熱催化技術是目前最有價值的技術,能夠首先突破,在實際工業生產和日常生活中廣泛應用?每天最新的新興前沿熱催化技術,是否真的像論文報道的那樣具有顛覆性突破,未來5-10年是否有希望改變一個行業?
有鑒于此,催化計編輯部開辟熱催化周刊欄目,從最基本的做起,通過簡報的形式,為大家提供每周最新的前沿技術。我們將以最短的時間,讓大家對最新的熱催化材料和技術有一個初步了解。
本期為熱催化周刊第2期,供大家學習交流。
(PS:點擊每張圖片,可查看詳細解讀)
前言:
用甲醇制備烯烴(methanol to olefins, MTO)具有重要的工業價值,小孔結構的硅酸鋁(SAPO)分子篩在該反應中體現出非常高的反應活性,但是如何高選擇性生成乙烯或者丙烯還具有挑戰,如何設計SAPO結構,提高MTO反應的選擇性呢?
合成氣轉化是近年來的研究熱點,通過鐵基費托合成經由多步催化將合成氣轉化為芳香烴化合物因為經濟高效性吸引了大量關注,該多步催化反應過程中的反應機理以及催化劑中各組成部分起到的作用是什么呢?此外,通過甲醇中間體將合成氣直接轉化為二甲醚(DME)可以高效地生產DME。盡管基于Cu/ZnO的多組分催化劑具有高的活性,但延長反應時間,由于Cu基催化劑容易出現燒結問題,這會降低催化性能。如何設計制備高活性和高穩定性的Cu/ZnO基DME催化劑?
此外,納米缺陷催化劑催化CO2轉化以及負載型單原子催化劑在催化加氫甲酰化反應中的潛力的研究也有了最新進展等。
參考文獻:
1. Miao Yang, et al.High Propylene Selectivity in Methanol Conversion over a Small-Pore SAPO Molecular Sieve with Ultra-Small Cage, ACS Catal. 2020,
DOI: 10.1021/acscatal.9b04703
https://pubs.acs.org/doi/abs/10.1021/acscatal.9b04703
2. Jonas Amsler, et al. Prospects of Heterogeneous Hydroformylation with Supported Single Atom Catalysts. J. Am. Chem. Soc., 2020.
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https://doi.org/10.1021/jacs.9b12171
3. Pieter Cnudde et al. Light Olefin Diffusion during the MTO Process on HSAPO-34: a Complex Interplay of Molecular Factors. JACS, 2020.
DOI: 10.1021/jacs.9b10249
https://pubs.acs.org/doi/10.1021/jacs.9b10249
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https://doi.org/10.1073/pnas.1917237117
5. Xiaoli Yang, et al.Exploring the Reaction Paths in the Consecutive Fe-Based FT Catalyst–Zeolite Process for Syngas Conversion. ACS Catal. 2020,
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https://pubs.acs.org/doi/abs/10.1021/acscatal.9b05449
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https://doi.org/10.1002/smll.201906276
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https://onlinelibrary.wiley.com/doi/abs/10.1002/anie.202002416
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