Chemical Exfoliation toward Magnetic 2D VOCl MonolayersClick to copy article linkArticle link copied!
- Graciela VillalpandoGraciela VillalpandoDepartment of Chemistry, Princeton University, Princeton, New Jersey 08544, United StatesMore by Graciela Villalpando
- Austin M. FerrentiAustin M. FerrentiDepartment of Chemistry, Princeton University, Princeton, New Jersey 08544, United StatesMore by Austin M. Ferrenti
- Ratnadwip SinghaRatnadwip SinghaDepartment of Chemistry, Princeton University, Princeton, New Jersey 08544, United StatesMore by Ratnadwip Singha
- Xiaoyu SongXiaoyu SongDepartment of Chemistry, Princeton University, Princeton, New Jersey 08544, United StatesMore by Xiaoyu Song
- Guangming ChengGuangming ChengPrinceton Institute for Science and Technology of Materials, Princeton, New Jersey 08544, United StatesMore by Guangming Cheng
- Nan YaoNan YaoPrinceton Institute for Science and Technology of Materials, Princeton, New Jersey 08544, United StatesMore by Nan Yao
- Leslie M. Schoop*Leslie M. Schoop*Email for L.M.S.: [email protected]Department of Chemistry, Princeton University, Princeton, New Jersey 08544, United StatesMore by Leslie M. Schoop
Abstract
The diversification of magnetic two-dimensional (2D) materials holds the key to the further development of advanced technologies, such as spintronic devices and efficient data storage. However, the search for intrinsic magnetism down to the 2D limit is severely limited by the ability to reliably exfoliate large, air-stable nanosheets. Chemical exfoliation, a relatively underutilized method for delamination, offers many advantages, including a high degree of adaptability and higher yields of uniformly exfoliated materials. van der Waals (vdW) materials, in particular the family of transition-metal oxyhalides, are ideal candidates for chemical exfoliation due to their large interlayer spacing and the wide variety of interesting magnetic properties they exhibit. In this study, we employ a chemical exfoliation method to delaminate the layered antiferromagnet vanadium oxychloride (VOCl) down to the monolayer limit. The resulting nansoheets have lateral sizes of up to 20 μm, are air-stable, and can be easily isolated. Magnetic characterization was performed throughout the exfoliation process, tracking the changes in magnetic behavior among bulk VOCl, its lithiated intercalate, and the restacked nanosheet pellet. The results from this work demonstrate the potential of chemical exfoliation, along with illustrating the effects of low dimensionality on magnetic properties.
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This article is cited by 4 publications.
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