5A 分子筛上用于按尺寸区分小有机分子的连续可调分子筛分“门”

Continuously Adjustable, Molecular-Sieving "Gate" on 5A Zeolite for Distinguishing Small Organic Molecules by Size.

作者信息

Song Zhuonan, Huang Yi, Xu Weiwei L, Wang Lei, Bao Yu, Li Shiguang, Yu Miao

机构信息

Department of Chemical Engineering, University of South Carolina, Columbia, SC 29208.

SmartState Center of Catalysis for Renewable Fuels, University of South Carolina, Columbia, SC 29208.

出版信息

Sci Rep. 2015 Sep 11;5:13981. doi: 10.1038/srep13981.

DOI:10.1038/srep13981

PMID:26358480

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4650327/

Abstract

Zeolites/molecular sieves with uniform, molecular-sized pores are important for many adsorption-based separation processes. Pore size gaps, however, exist in the current zeolite family. This leads to a great challenge of separating molecules with size differences at ~0.01 nm level. Here, we report a novel concept, pore misalignment, to form a continuously adjustable, molecular-sieving "gate" at the 5A zeolite pore entrance without sacrificing the internal capacity. Misalignment of the micropores of the alumina coating with the 5A zeolite pores was related with and facilely adjusted by the coating thickness. For the first time, organic molecules with sub-0.01 nm size differences were effectively distinguished via appropriate misalignment. This novel concept may have great potential to fill the pore size gaps of the zeolite family and realize size-selective adsorption separation.

摘要

具有均匀分子尺寸孔隙的沸石/分子筛对许多基于吸附的分离过程至关重要。然而，目前的沸石家族存在孔径间隙。这给分离尺寸差异在约0.01纳米水平的分子带来了巨大挑战。在此，我们报告了一个新颖的概念——孔错位，即在不牺牲内部容量的情况下，在5A沸石孔口处形成一个可连续调节的分子筛“门”。氧化铝涂层的微孔与5A沸石孔的错位与涂层厚度相关且易于通过涂层厚度进行调节。首次通过适当的错位有效地区分了尺寸差异小于0.01纳米的有机分子。这一新颖概念可能具有填补沸石家族孔径间隙并实现尺寸选择性吸附分离的巨大潜力。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/8a1d/4650327/7157e4f3283b/srep13981-f1.jpg

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5A 分子筛上用于按尺寸区分小有机分子的连续可调分子筛分“门”

Continuously Adjustable, Molecular-Sieving "Gate" on 5A Zeolite for Distinguishing Small Organic Molecules by Size.

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