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通过金属有机框架将部分还原的氧化石墨烯焊接成微介孔杂化物用于高性能吸油

Welding partially reduced graphene oxides by MOFs into micro-mesoporous hybrids for high-performance oil absorption.

作者信息

Sun Lu, Tang Jun

机构信息

Department of Polymer Science, Jilin University Changchun 130012 China

出版信息

RSC Adv. 2021 Sep 20;11(49):30980-30989. doi: 10.1039/d1ra05644a. eCollection 2021 Sep 14.

DOI:10.1039/d1ra05644a
PMID:35498948
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9041363/
Abstract

Partially reduced graphene oxides (PRGOs) with a small number of COOH groups remaining at the edges were interlocked by UiO-66-NH nanoparticles into hierarchical porous hybrids (PRGO@UiO-66-NH) during the synthesis of UiO-66-NH in the presence of PRGOs, in which the UiO-66-NH nanoparticles provide micropores and the interlocked PRGO skeletons provide mesopores. The peak intensity of the functional groups on the PRGO@UiO-66-NH hybrids decrease greatly when compared with the GO@UiO-66-NH hybrids and the UiO-66-NH nanoparticles, and the number of -COOH at the edge of the PRGOs are approximately 6.3% after reduction, which is confirmed by the FT-IR and XPS results. When the PRGO@UiO-66-NH hybrids were embedded in their macropores hydrogen bonding, melamine foams (MFs) were able to effectively absorb a variety of water-immiscible organic solvents from oil/water biphasic mixtures and, at the same time, suppress water infusion due to Cassie-state surface superhydrophobicity with a water contact angle of 154.2° in air. After 10 cycles, the PRGO@UiO-66-NH-laden MFs exhibited water contact angles of 148.3°, which indicated that the composite MFs had excellent stability and recycling ability after 10 cycles. The PRGO@UiO-66-NH-laden MFs had an oil absorption capacity of >10 000 wt% of the dry mass of absorbents and water absorption capacity of ≈1.76 wt% of the adsorbate, thus highlighting the high absorption selectivity of oil over water.

摘要

在存在部分还原氧化石墨烯(PRGOs)的情况下合成UiO-66-NH的过程中,边缘残留少量羧基的部分还原氧化石墨烯被UiO-66-NH纳米颗粒互锁形成分级多孔杂化材料(PRGO@UiO-66-NH),其中UiO-66-NH纳米颗粒提供微孔,互锁的PRGO骨架提供介孔。与GO@UiO-66-NH杂化材料和UiO-66-NH纳米颗粒相比,PRGO@UiO-66-NH杂化材料上官能团的峰强度大幅降低,FT-IR和XPS结果证实,还原后PRGOs边缘的-COOH数量约为6.3%。当PRGO@UiO-66-NH杂化材料通过氢键嵌入其大孔中时,三聚氰胺泡沫(MFs)能够有效地从油/水两相混合物中吸收各种与水不混溶的有机溶剂,同时,由于在空气中水接触角为154.2°的Cassie态表面超疏水性,抑制了水的注入。经过10个循环后,负载PRGO@UiO-66-NH的MFs的水接触角为148.3°,这表明复合MFs在10个循环后具有优异的稳定性和循环利用能力。负载PRGO@UiO-66-NH的MFs的吸油能力大于吸收剂干质量的10000 wt%,吸水能力约为被吸附物的1.76 wt%,从而突出了对油相对于水的高吸收选择性。

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