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超热流动化学助力有机合成的新机遇

New Opportunities for Organic Synthesis with Superheated Flow Chemistry.

作者信息

Bianchi Pauline, Monbaliu Jean-Christophe M

机构信息

Center for Integrated Technology and Organic Synthesis, MolSys Research Unit, University of Liège, Allée du Six Août 13, 4000 Liège (Sart Tilman), Belgium.

WEL Research Institute, Avenue Pasteur 6, 1300 Wavre, Belgium.

出版信息

Acc Chem Res. 2024 Aug 6;57(15):2207-2218. doi: 10.1021/acs.accounts.4c00340. Epub 2024 Jul 23.

DOI:10.1021/acs.accounts.4c00340
PMID:39043368
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11308364/
Abstract

ConspectusFlow chemistry has brought a fresh breeze with great promises for chemical manufacturing, yet critical deterrents persist. To remain economically viable at production scales, flow processes demand quick reactions, which are actually not that common. Superheated flow technology stands out as a promising alternative poised to confront modern chemistry challenges. While continuous micro- and mesofluidic reactors offer uniform heating and rapid cooling across different scales, operating above solvent boiling points (i.e., operating under superheated conditions) significantly enhances reaction rates. Despite the energy costs associated with high temperatures, superheated flow chemistry aligns with sustainability goals by improving productivity (process intensification), offering solvent flexibility, and enhancing safety.However, navigating the unconventional chemical space of superheated flow chemistry can be cumbersome, particularly for neophytes. Expanding the temperature/pressure process window beyond the conventional boiling point under the atmospheric pressure limit vastly increases the optimization space. When associated with conventional trial-and-error approaches, this can become exceedingly wasteful, resource-intensive, and discouraging. Over the years, flow chemists have developed various tools to mitigate these challenges, with an increased reliance on statistical models, artificial intelligence, and experimental (kinetics, preliminary test reactions under microwave irradiation) or theoretical (quantum mechanics) knowledge. Yet, the rationale for using superheated conditions has been slow to emerge, despite the growing emphasis on predictive methodologies.To fill this gap, this Account provides a concise yet comprehensive overview of superheated flow chemistry. Key concepts are illustrated with examples from our laboratory's research, as well as other relevant examples from the literature. These examples have been thoroughly studied to answer the main questions The answers we provide will encourage educated and widespread adoption. The discussion begins with a demonstration of the various advantages arising from superheated flow chemistry. Different reactor alternatives suitable for high temperatures and pressures are then presented. Next, a clear workflow toward strategic adoption of superheated conditions is resorted either using Design of Experiments (DoE), microwave test chemistry, kinetics data, or Quantum Mechanics (QM). We provide rationalization for chemistries that are well suited for superheated conditions (e.g., additions to carbonyl functions, aromatic substitutions, as well as C-Y [Y = N, O, S, C, Br, Cl] heterolytic cleavages). Lastly, we bring the reader to a rational decision analysis toward superheated flow conditions. We believe this Account will become a reference guide for exploring extended chemical spaces, accelerating organic synthesis, and advancing molecular sciences.

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摘要

概述

流动化学为化学制造带来了一股充满巨大潜力的新风,但关键的阻碍依然存在。为了在生产规模上保持经济可行性,流动过程需要快速反应,而实际上这种反应并不常见。过热流动技术作为一种有前途的替代方案,有望应对现代化学挑战。虽然连续微流控和中流控反应器能在不同尺度上实现均匀加热和快速冷却,但在高于溶剂沸点的条件下运行(即在过热条件下运行)能显著提高反应速率。尽管高温会带来能源成本,但过热流动化学通过提高生产率(过程强化)、提供溶剂灵活性和增强安全性,符合可持续发展目标。

然而,在过热流动化学这种非常规的化学领域中摸索可能会很麻烦,尤其是对于新手而言。在大气压限制下将温度/压力过程窗口扩展到传统沸点以上,会极大地增加优化空间。当与传统的试错方法结合时,这可能会变得极其浪费、资源密集且令人沮丧。多年来,流动化学家们开发了各种工具来应对这些挑战,越来越依赖统计模型、人工智能以及实验(动力学、微波辐射下的初步测试反应)或理论(量子力学)知识。然而,尽管对预测方法的重视日益增加,但使用过热条件的基本原理却迟迟未出现。

为了填补这一空白,本综述对过热流动化学进行了简洁而全面的概述。通过我们实验室研究的实例以及文献中的其他相关实例来说明关键概念。对这些实例进行了深入研究,以回答主要问题。我们提供的答案将鼓励有见识且广泛地采用过热流动化学。讨论首先展示了过热流动化学带来的各种优势。接着介绍了适用于高温高压的不同反应器替代方案。然后,借助实验设计(DoE)、微波测试化学、动力学数据或量子力学(QM),给出了一个明确的采用过热条件的战略工作流程。我们为非常适合过热条件的化学反应(例如羰基官能团的加成、芳基取代以及C - Y [Y = N、O、S、C、Br、Cl]异裂)提供了理论依据。最后,我们引导读者对过热流动条件进行合理的决策分析。我们相信本综述将成为探索扩展化学空间、加速有机合成以及推动分子科学发展的参考指南。

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本文引用的文献

1
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Org Process Res Dev. 2024 Apr 25;28(5):1946-1963. doi: 10.1021/acs.oprd.3c00498. eCollection 2024 May 17.
2
Continuous flow synthesis enabling reaction discovery.连续流动合成助力反应发现。
Chem Sci. 2024 Feb 28;15(13):4618-4630. doi: 10.1039/d3sc06808k. eCollection 2024 Mar 27.
3
Intensified Continuous Flow Process for the Scalable Production of Bio-Based Glycerol Carbonate.用于生物基碳酸甘油酯规模化生产的强化连续流工艺
Angew Chem Int Ed Engl. 2024 Mar 4;63(10):e202319060. doi: 10.1002/anie.202319060. Epub 2024 Jan 24.
4
Revisiting the Paradigm of Reaction Optimization in Flow with a Priori Computational Reaction Intelligence.借助先验计算反应智能重新审视流动反应优化范式。
Angew Chem Int Ed Engl. 2024 Jan 25;63(5):e202311526. doi: 10.1002/anie.202311526. Epub 2023 Dec 22.
5
A field guide to flow chemistry for synthetic organic chemists.合成有机化学家的流动化学实地指南。
Chem Sci. 2023 Mar 15;14(16):4230-4247. doi: 10.1039/d3sc00992k. eCollection 2023 Apr 26.
6
A Brief Introduction to Chemical Reaction Optimization.化学反应优化简介。
Chem Rev. 2023 Mar 22;123(6):3089-3126. doi: 10.1021/acs.chemrev.2c00798. Epub 2023 Feb 23.
7
Will the next generation of chemical plants be in miniaturized flow reactors?下一代化工厂会采用微型化的流动反应器吗?
Lab Chip. 2023 Mar 1;23(5):1349-1357. doi: 10.1039/d2lc00796g.
8
On Demand Flow Platform for the Generation of Anhydrous Dinitrogen Trioxide and Its Further Use in N-Nitrosative Reactions.按需流动平台生成无水三氧化二氮及其在 N-亚硝化反应中的进一步应用。
Angew Chem Int Ed Engl. 2022 Oct 10;61(41):e202210146. doi: 10.1002/anie.202210146. Epub 2022 Sep 2.
9
The Chapman rearrangement in a continuous-flow microreactor.连续流微反应器中的查普曼重排反应。
RSC Adv. 2019 Mar 21;9(16):9270-9280. doi: 10.1039/c9ra01347d. eCollection 2019 Mar 15.
10
Combining Machine Learning and Computational Chemistry for Predictive Insights Into Chemical Systems.结合机器学习和计算化学,对化学系统进行预测性洞察。
Chem Rev. 2021 Aug 25;121(16):9816-9872. doi: 10.1021/acs.chemrev.1c00107. Epub 2021 Jul 7.