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2D atomic crystal molecular superlattices by soft plasma intercalation

Lufang Zhang, Haiyan Nan, Xiu‐Mei Zhang, Qifeng Liang, Aijun Du, Zhenhua Ni, Xiaofeng Gu, Kostya Ostrikov, Shaoqing Xiao

2020Nature Communications64 citationsDOIOpen Access PDF

Abstract

Abstract Two-dimensional (2D) atomic crystal superlattices integrate diverse 2D layered materials enabling adjustable electronic and optical properties. However, tunability of the interlayer gap and interactions remain challenging. Here we report a solution based on soft oxygen plasma intercalation. 2D atomic crystal molecular superlattices (ACMSs) are produced by intercalating O 2 + ions into the interlayer space using the plasma electric field. Stable molecular oxygen layer is formed by van der Waals interactions with adjacent transition metal dichalcogenide (TMD) monolayers. The resulting interlayer gap expansion can effectively isolate TMD monolayers and impart exotic properties to homo-(MoS 2 [O 2 ] x ) and hetero-(MoS 2 [O 2 ] x /WS 2 [O 2 ] x ) stacked ACMSs beyond typical capacities of monolayer TMDs, such as 100 times stronger photoluminescence and 100 times higher photocurrent. Our potentially universal approach to tune interlayer stacking and interactions in 2D ACMSs may lead to exotic superlattice properties intrinsic to monolayer materials such as direct bandgap pursued for future optoelectronics.

Topics & Concepts

MonolayerSuperlatticeIntercalation (chemistry)Materials sciencePhotoluminescenceStackingvan der Waals forceGrapheneBand gapCrystal (programming language)PhotocurrentNanotechnologyCondensed matter physicsChemical physicsCrystallographyOptoelectronicsChemistryMoleculeInorganic chemistryPhysicsOrganic chemistryProgramming languageComputer science2D Materials and ApplicationsAdvanced Photocatalysis TechniquesPerovskite Materials and Applications
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