Investigation of molecular motion of Cl-adamantane in the nanoprous zeolite by 13C NMR dipolar dephasing and variable contact time measurements

IF 1.2 Q4 NANOSCIENCE & NANOTECHNOLOGY
A. Samadi‐Maybodi
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引用次数: 0

Abstract

Dipolar-dephasing method provides some information about the strength of dipolar coupling in solids. Dipolar dephasing technique measures the time for a polarized carbon nucleus to lose its magnetization once the proton locking field is terminated. The dynamics of guest molecules adsorbed within the cavities and channels of nonporouszeolite strongly depend on the structure and chemical composition of the nonporouszeolite. In this work solid-state 13C NMR spectroscopy and dipolar dephasing technique were applied to determine the extent of motion 1-Chloroadamantaneloaded in nonporouszeolite-Y. Loading of 1-Chloroadamantane into the supercages of the zeolite-Y (with R=100 and R=2.35, R=Si/Al) was carried out by a vapor phase impregnationand solution impregnation methods. The accuracy of dipolar dephasing method was first investigated with the aid of pure 1-Chloroadamantaneto determine the degree of motion in the nonporousof zeolite-Y. Results indicated that the Cd signal of the 1-Chloroadamantanein the nonporous zeolite-Y decays faster than that the Cb and Cg, demonstrating that dipolar interaction for this carbon (Cd) is stronger. However, the rate of signal decay Cd for the 1-Chloroadamantaneloaded in zeolite -Y (R=2.35) is less than that loaded in zeolite-Y (R=100).
利用13C核磁共振偶极脱相和变接触时间测量研究纳米沸石中氯金刚烷的分子运动
偶极减相法提供了固体中偶极耦合强度的一些信息。偶极脱相技术测量极化碳核在质子锁定场终止后失去磁化的时间。吸附在非多孔沸石孔洞和孔道内的客体分子动力学在很大程度上取决于非多孔沸石的结构和化学组成。本文采用固态13C核磁共振波谱和偶极脱相技术测定了1-氯金刚烷在非多孔沸石y中的运动程度。采用气相浸渍法和溶液浸渍法,将1-氯金刚烷装入沸石- y (R=100和R=2.35, R=Si/Al)的超笼中。本文首先考察了偶极脱相法在纯1-氯金刚烷的辅助下测定无孔沸石y中运动度的准确性。结果表明,1-氯金刚烷素在无孔沸石y上的Cd信号衰减速度快于Cb和Cg,表明该碳(Cd)的偶极相互作用更强。然而,1-氯金刚烷在沸石-Y中负载的信号衰减率Cd (R=2.35)小于在沸石-Y中负载的(R=100)。
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来源期刊
international journal of nano dimension
international journal of nano dimension NANOSCIENCE & NANOTECHNOLOGY-
CiteScore
2.80
自引率
20.00%
发文量
0
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