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Cheng-Tai Kuo,Karuppannan Balamurugan,Hung Wei Shiu,Hyun Ju Park,Soobin Sinn,Michael Neumann,한문섭,장영준,Chia-Hao Chen,Hyeong-Do Kim,박제근,Tae Won Noh 한국물리학회 2016 Current Applied Physics Vol.16 No.3
We have studied the electronic structure and interfacial properties of mechanically exfoliated few-layer NiPS3 van der Waals crystals on ZnO/Nb:SrTiO3 substrates using scanning photoelectron microscopy and spectroscopy. The conducting ZnO layer enhances the visibility of few-layer NiPS3 on Nb:SrTiO3 and prevents charging effects in photoemission. We experimentally determined a type-II band alignment at the NiPS3/ZnO interface. The valence band offset (VBO) of few-layer NiPS3/ZnO is 2.8 ± 0.09 eV, and the conduction band offset is 1.0 ± 0.09 eV. Moreover, we found an increase of ~0.3 eV in VBO as decreasing NiPS3 thickness, suggesting electronic coupling or charge transfer at the NiPS3/ZnO interface.
Electrical control of nanoscale functionalization in graphene by the scanning probe technique
Byun, Ik-Su,Kim, Wondong,Boukhvalov, Danil W.,Hwang, Inrok,Son, Jong Wan,Oh, Gwangtaek,Choi, Jin Sik,Yoon, Duhee,Cheong, Hyeonsik,Baik, Jaeyoon,Shin, Hyun-Joon,Shiu, Hung Wei,Chen, Chia-Hao,Son, Young Nature Publishing Group (NPG) ; Tokyo Institute of 2014 NPG Asia Materials Vol.6 No.-
Functionalized graphene is a versatile material that has well-known physical and chemical properties depending on functional groups and their coverage. However, selective control of functional groups on the nanoscale is hardly achievable by conventional methods utilizing chemical modifications. We demonstrate electrical control of nanoscale functionalization of graphene with the desired chemical coverage of a selective functional group by atomic force microscopy (AFM) lithography and their full recovery through moderate thermal treatments. Surprisingly, our controlled coverage of functional groups can reach 94.9% for oxygen and 49.0% for hydrogen, respectively, well beyond those achieved by conventional methods. This coverage is almost at the theoretical maximum, which is verified through scanning photoelectron microscope measurements as well as first-principles calculations. We believe that the present method is now ready to realize 'chemical pencil drawing' of atomically defined circuit devices on top of a monolayer of graphene.