金属有机框架材料中的氨存储:设计和表征方面的最新进展

IF 14 Q1 CHEMISTRY, MULTIDISCIPLINARY
Wanpeng Lu, Dukula De Alwis Jayasinghe, Martin Schröder, Sihai Yang
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引用次数: 0

摘要

自 1910 年哈伯-博施工艺问世以来,由于氨气(NH3)在农业、制药和能源领域的应用,全球对氨气(NH3)的需求激增。目前的 NH3 储存方法,包括高压储存和运输,都因其腐蚀性和毒性而面临巨大挑战。因此,由于金属有机框架(MOF)材料具有潜在的高吸附能力和结构可调性,研究人员将其作为储存 NH3 的潜在候选材料。MOF 是由金属节点和有机连接体组成的配位网络,具有前所未有的孔隙率和表面积,并允许加入各种功能基团和金属位点,从而增强对 NH3 的吸附。然而,MOFs 在 NH3 存在下的稳定性是一个重大问题,因为许多 MOFs 在接触 NH3 后会发生降解,主要原因是配体置换和框架崩溃。为了解决这个问题,最近的研究主要集中在 MOFs 的合成和合成后修饰,以提高其吸收 NH3 的能力和稳定性。在本篇开户绑定手机领体验金中,我们将总结用于储存 NH3 的 MOFs 的设计和表征方面的最新进展。MOF 中金属中心的选择对于稳定性和性能至关重要。AlIII 和 TiIV 等高价金属可形成牢固的金属-连接键,增强框架对 NH3 的稳定性。由高价位 3+ 和 4+ 金属离子和羧基连接体组成的 MFM-300 系列材料具有高稳定性和高 NH3 吸收能力。配体官能化是提高 NH3 吸附能力的另一种有效策略。极性官能团(如 -NH2、-OH 和 -COOH)可增强框架与 NH3 之间的相互作用,尤其是在低分压下。例如,含有游离羧酸基团的 MFM-303(Al)具有与固体 NH3 相当的高 NH3 堆积密度。通过去除连接体或添加金属离子来创建缺陷位点,可增加可用于吸附 NH3 的活性位点数量,从而有望提高吸附能力。UiO-66 是一种稳定的 MOF 框架,可以对其进行修饰,使其包含缺陷位点,从而显著提高吸收 NH3 的水平。MOFs 的全面表征,特别是它们与 NH3 的相互作用,对于了解和改进其性能至关重要。中子粉末衍射 (NPD)、非弹性中子散射 (INS)、漫反射红外傅立叶变换光谱 (DRIFTS)、电子顺磁共振 (EPR) 光谱和固态核磁共振 (ssNMR) 光谱等技术可以阐明 NH3 与框架结构之间的主客体相互作用和结合动力学,为未来设计和合理开发新型吸附剂提供重要信息。本篇开户绑定手机领体验金重点介绍了我们目前用于捕获 NH3 的 MOFs 的合成和表征策略,为这一快速发展的领域提供了一个概览。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Ammonia Storage in Metal–Organic Framework Materials: Recent Developments in Design and Characterization

Ammonia Storage in Metal–Organic Framework Materials: Recent Developments in Design and Characterization
Since the advent of the Haber–Bosch process in 1910, the global demand for ammonia (NH3) has surged, driven by its applications in agriculture, pharmaceuticals, and energy. Current methods of NH3 storage, including high-pressure storage and transportation, present significant challenges due to their corrosive and toxic nature. Consequently, research has turned towards metal–organic framework (MOF) materials as potential candidates for NH3 storage due to their potential high adsorption capacities and structural tunability. MOFs are coordination networks composed of metal nodes and organic linkers, offering unprecedented porosity and surface area, and allowing incorporation of various functional groups and metal sites that can enhance NH3 adsorption. However, the stability of MOFs in the presence of NH3 is a significant concern since many degrade upon exposure to NH3, primarily due to ligand displacement and framework collapse. To address this, recent studies have focused on the synthesis and postsynthetic modification of MOFs to enhance both NH3 uptake and stability. In this Account, we summarize recent developments in the design and characterization of MOFs for NH3 storage. The choice of metal centers in MOFs is crucial for stability and performance. High-valence metals such as AlIII and TiIV form strong metal–linker bonds, enhancing the stability of the framework to NH3. The MFM-300 series of materials composed of high-valence 3+ and 4+ metal ions and carboxylic linkers demonstrates high stability and high NH3 uptake capacities. Ligand functionalization is another effective strategy for improving the NH3 adsorption. Polar functional groups such as –NH2, –OH, and –COOH enhance the interaction between the framework and NH3, particularly at low partial pressures, while postsynthetic modification allows fine-tuning of these functionalities to optimize the framework for higher adsorption capacities and stability. For example, MFM-303(Al), incorporating free carboxylic acid groups, exhibits a high NH3 packing density comparable to that of solid NH3. Creating defect sites by removing linkers or adding metal ions increases the number of active sites available for NH3 adsorption and shows promise for enhancing uptake. UiO-66, a stable MOF framework, can be modified to include defect sites, significantly enhancing the level of NH3 uptake. The full characterization of MOFs and especially their interactions with NH3 are vital for understanding and improving their performance. Techniques such as neutron powder diffraction (NPD), inelastic neutron scattering (INS), diffuse reflectance infrared Fourier transform spectroscopy (DRIFTS), electron paramagnetic resonance (EPR) spectroscopy, and solid-state nuclear magnetic resonance (ssNMR) spectroscopy can elucidate host–guest interactions and binding dynamics between NH3 and the framework structure and afford crucial information for the future design and rational development of new sorbents. This Account highlights our current strategies for the synthesis and characterization of MOFs for NH3 capture, providing an overview of this rapidly evolving field.
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