可宏量制备的层叠配位聚合物用于CH4/N2分离

doi:10.6023/A26020042

摘要/Abstract

煤层气中甲烷/氮气的高效分离是提升清洁能源利用率、减少温室气体排放的关键举措. 本研究筛选出一例一维层叠配位聚合物吸附剂材料 (Mn-DHBQ),在298 K和1 bar下有较高的CH₄吸附量 (1.10 mmol/g) 和CH₄/N₂选择性 (5.82). 在动态穿透实验中,可以实现CH₄/N₂的高效分离. 此外,该材料可由廉价商品化原料在水溶液中高效规模化合成,结构与分离性能与小规模合成的材料保持一致,具有良好的应用前景.

关键词: 金属有机框架, 配位聚合物, CH₄/N₂分离, 规模化制备

Efficient separation of CH₄/N₂ mixtures is important for the upgrading and utilization of coalbed methane, because the high N₂ content in raw gas markedly lowers its calorific value and restricts its direct use as a fuel or chemical feedstock. Adsorptive separation under mild conditions is considered a promising alternative to energy-intensive cryogenic distillation; however, the development of adsorbents that combine competitive CH₄/N₂ separation performance with scalable, low-cost, and green synthesis remains challenging. Herein, we report a layered manganese-based coordination polymer, Mn-DHBQ, as a promising adsorbent for CH₄/N₂ separation. Mn-DHBQ was synthesized from manganese acetate tetrahydrate and 2,5-dihydroxy-p-benzoquinone in pure water at room temperature using inexpensive and commercially available precursors. Structurally, Mn-DHBQ is composed of one-dimensional coordination chains that are further stacked through intermolecular hydrogen bonding to form a quasi-three-dimensional supramolecular microporous network. Powder X-ray diffraction confirmed the phase purity and crystallinity of the as-synthesized material, while N₂ sorption at 77 K gave a BET surface area of 428.7 m²/g. Gas adsorption measurements showed that Mn-DHBQ adsorbs CH₄ much more strongly than N₂. At 298 K and 1 bar, the CH₄ uptake reaches 1.10 mmol/g, whereas the N₂ uptake is only 0.27 mmol/g. The corresponding IAST CH₄/N₂ (50/50) selectivity is 5.82 at 298 K. Virial analysis further revealed a higher isosteric heat of adsorption for CH₄ (28.85 kJ/mol) than for N₂ (10.59 kJ/mol), indicating a substantially stronger affinity of the framework toward CH₄. Dynamic breakthrough experiments using an equimolar CH₄/N₂ mixture at 298 K and 1 bar demonstrated clear separation behavior, with N₂ eluting rapidly and CH₄ breaking through at 10.2 min/g; the dynamic CH₄ uptake reached 0.46 mmol/g, close to the equilibrium uptake at the corresponding partial pressure. In a single adsorption-desorption cycle, the CH₄ concentration could be enriched to above 98.9%, and stable separation performance was maintained over three cycles. Importantly, Mn-DHBQ was further synthesized on a 1000-fold larger scale in water within 8 h, affording about 0.21 kg product with a space-time yield of 63 kg/m³/d. The scaled-up sample retained comparable crystallinity, porosity, morphology, and CH₄/N₂ breakthrough performance to the laboratory-scale material. These results indicate that Mn-DHBQ is a promising and practically relevant adsorbent for CH₄ enrichment and coalbed methane upgrading.

Key words: Metal-organic frameworks, Coordination Polymer, CH₄/N₂ separation, Swelling effect, Scale-up synthesis

引用此文

刘璐, 赵砚珑, 白薛峰, 张鑫, 李建荣. 可宏量制备的层叠配位聚合物用于CH₄/N₂分离[J]. 化学学报, doi: 10.6023/A26020042.

Lu Liu, Yan-Long Zhao, Xuefeng Bai, Xin Zhang, Jian-Rong Li. Efficient CH₄/N₂ Separation in a Scalable Stacked Coordination Polymer[J]. Acta Chimica Sinica, doi: 10.6023/A26020042.

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可宏量制备的层叠配位聚合物用于CH₄/N₂分离

Efficient CH₄/N₂ Separation in a Scalable Stacked Coordination Polymer

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