Controllable Phase Transformation by Van der Waals Encapsulation in Electrochemically Exfoliated PdSe<sub>2</sub> Nanosheets
Qiaoyan Hao, Jiarui Huang, Jidong Liu, Junzi Li, Haibo Gan, Yudi Tu, Zixuan Wang, Haohui Ou, Zhiwei Li, Yutao Hu, Wenjing Zhang
Abstract
Abstract 2D orthorhombic palladium diselenide is attracting rapidly increased interest by virtue of its fascinating physical properties and feasibility of phase transformation. However, it remains a major challenge to produce ultrathin PdSe 2 through a facile chemical route and control phase transformation because of its anisotropic structure with strong interlayer coupling. Here, the efficient synthesis of few‐layer PdSe 2 nanosheets with large sizes using an electrochemical exfoliation approach is reported. Upon thermal annealing at 300–350 °C, the as‐exfoliated PdSe 2 nanosheets transform into metallic phase PdSe 2‐ x , as verified by scanning transmission electron microscopy, Raman spectroscopy, and electrical characterizations. Simple encapsulation using hexagonal boron nitride (h‐BN) can effectively suppress the Se‐loss triggered phase transformation, so that a metal‐semiconductor junction is formed by local phase modification. The fabricated PdSe 2 field‐effect transistors exhibit p‐type transport property, which is in stark contrast to electron‐dominated ambipolar transport of pristine PdSe 2 devices. The combination of high‐resolution X‐ray photoelectron spectroscopy and cross‐sectional transmission electron microscopy analysis reveals that the modulation of carrier polarity in h‐BN encapsulated PdSe 2 should arise from the p‐doping effect associated with the impact of interfacial condition. The study opens up a new route for future phase‐engineered electronics in PdSe 2 and other 2D noble metal dichalcogenides materials.