一维和二维功能材料的磁性:氧分子封装在单壁碳纳米管中,铜离子嵌入在酞菁片中

Q2 Pharmacology, Toxicology and Pharmaceutics Open Medicinal Chemistry Journal Pub Date : 2018-06-29 DOI:10.2174/1877944108666180629112859
M. Hagiwara, T. Kida, K. Matsuda, Haruka Kyakuno, Yutaka Mniwa, Zentaro Hondad, Yuya Sakaguchi, M. Tashiro, M. Sakai, T. Fukuda, N. Kamata, K. Okunishi
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引用次数: 2

摘要

在本文中,我们报告了一维(1D)和二维(2D)功能材料的主题。单壁碳纳米管(SWCNTs)是由六边形晶格石墨片制成的无缝空心圆柱体。由于其封闭的纳米空间在工程中的适用性,SWCNTs引起了相当大的关注,许多类型的客体材料被封装在其一维空间中,期望具有不同寻常的性能。聚过渡金属(TM)酞菁,其中酞菁单元通过共享苯环在二维上扩展,是TM含二碳材料的一个例子。由于TM原子中的定域d电子与聚酞菁框架上的离域π电子之间存在很强的相关性,因此可以预期自旋极化导电,这将有助于自旋电子的应用。第一项工作的目的是合成包裹自旋为1的氧分子的SWCNTs,其O-O键方向与SWCNTs的纵向对齐。第二项工作的目的是以铜酞菁为主体,通过自下而上的方法合成聚铜酞菁(PCuPc),并阐明其晶体结构和磁性能。采用CoMoCAT法制备了内径约为0.8 nm的SWCNTs,并与氧分子(~400 Torr)一起包封在高纯度石英管中。为了去除SWCNTs和石英管的背景信号,我们在排出氧分子后制备了相同的SWCNTs诱导He气体。这些SWCNTs样品的磁化测量是通过SQUID磁强计和脉冲磁体进行的。以八氰眼青碱、四氰苯和CuCl2·2H2O为原料,在密封后的玻璃安瓿中固相反应合成PCuPc。采用XRD分析和TEM显微镜对合成的样品进行了表征。用SQUID磁力计对样品进行磁化测量。SWCNTs内部氧分子的本征磁化数据(温度和磁场依赖性)显示了自旋为一的海森堡反铁磁体的典型磁性,称为霍尔丹磁体。采用固相反应法制备了半填充型PCuPc和半填充型PCuPc。PCuPc的磁化率和磁化强度均大于半填充PCuPc,但前者的磁化率和磁化强度约为后者的1.5倍,从几何超晶格结构来看,前者的磁化率和磁化强度是后者的两倍。我们研究了包裹在直径约0.8 nm的单壁碳纳米管(SWCNTs)中的氧分子的磁性能(磁化率和磁化率),作为一维功能磁性材料,以及聚酞菁铜(PCuPc)和聚半填充酞菁铜(半填充PCuPc)作为二维功能磁性材料。
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Magnetic Properties of One- and Two-Dimensional Functional Materials: Oxygen Molecules Encapsulated in Single-Walled Carbon Nanotubes and Copper Ions Embedded into Phthalocyanine Sheets
In this paper, we report on the topics of one-dimensional (1D) and two-dimensional (2D) functional materials. Single-Walled Carbon Nanotubes (SWCNTs) are seamless hollow cylinders made of hexagonal lattice graphite sheets. The SWCNTs have attracted considerable attention due to the applicability of their enclosed nanospaces to engineering, and many types of guest materials are encapsulated inside their 1D space, expecting unusual properties. The poly Transition Metal (TM) phthalocyanine, in which phthalocyanine units are extended in two dimensions by sharing benzene rings, is one of the examples of the TM containing 2D carbon materials. Because of strong correlation between localized d-electrons in the TM atom and delocalized π-electrons on the poly phthalocyanine frame, it is expected that spin-polarized conduction, which is useful for the spintronic applications. The objective of the first work is to synthesize SWCNTs encapsulating oxygen molecules having spin one, whose O-O bond directions are aligned to the longitudinal direction of the SWCNTs. The objective of the second work is to synthesize Poly Cu Phthalocyanine (PCuPc) through a bottom-up method by using copper octacyanophthalocyanine as a building block and to elucidate its crystal structure and magnetic properties. SWCNTs with inner diameter of ca 0.8 nm were prepared by the CoMoCAT method, and encapsulated together with oxygen molecules (~400 Torr) into a high-purity quartz tube. To subtract the background signals of the SWCNTs and the quartz tube, we prepared the same SWCNTs inducing He gas after evacuating oxygen molecules. Magnetization measurements of these SWCNTs samples were conducted by means of a SQUID magnetometer and a pulse magnet using an induction method. PCuPc were synthesized by a solid state reaction of octacyanophthalocyanine, tetracyanobenzene, and CuCl2·2H2O in glass ampoules sealed after evacuation. The as-synthesized samples were characterized using XRD analysis and TEM microscopy. Magnetization measurement of the samples were done by using a SQUID magnetometer. The intrinsic magnetization data from oxygen molecules inside the SWCNTs (temperature and magnetic field dependence) show magnetic properties typical of the spin-one Heisenberg antiferromagnet named a Haldane magnet. PCuPc and its half-filling counterpart were obtained by solid state reaction. Both magnetic susceptibility and magnetization of PCuPc are larger than those of half-filling PCuPc, but the magnitudes of the former sample are about 1.5 times larger than those of the latter one, which is expected to be twice from the geometric superlattice structure. We have studied magnetic properties (magnetic susceptibility and magnetization) of oxygen molecules encapsulated into Single Walled Carbon Nanotubes (SWCNTs) with diameters of about 0.8 nm, regarded as a 1D functional magnetic material, and Poly Copper Phthalocyanine (PCuPc) and poly half-filling copper phthalocyanine (half-filling PCuPc), regarded as 2D functional magnetic materials.
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来源期刊
Open Medicinal Chemistry Journal
Open Medicinal Chemistry Journal Pharmacology, Toxicology and Pharmaceutics-Pharmaceutical Science
CiteScore
4.40
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发文量
4
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