Litcius/Paper detail

Unveiling Charge‐Transport Mechanisms in Electronic Devices Based on Defect‐Engineered MoS <sub>2</sub> Covalent Networks

Stefano Ippolito, Francesca Urban, Wenhao Zheng, Onofrio Mazzarisi, Cataldo Valentini, Adam G. Kelly, Sai Manoj Gali, Mischa Bonn, David Beljonne, Federico Corberi, Jonathan N. Coleman, Hai I. Wang, Paolo Samorı́

2023Advanced Materials42 citationsDOIOpen Access PDF

Abstract

Device performance of solution-processed 2D semiconductors in printed electronics has been limited so far by structural defects and high interflake junction resistance. Covalently interconnected networks of transition metal dichalcogenides potentially represent an efficient strategy to overcome both limitations simultaneously. Yet, the charge-transport properties in such systems have not been systematically researched. Here, the charge-transport mechanisms of printed devices based on covalent MoS2 networks are unveiled via multiscale analysis, comparing the effects of aromatic versus aliphatic dithiolated linkers. Temperature-dependent electrical measurements reveal hopping as the dominant transport mechanism: aliphatic systems lead to 3D variable range hopping, unlike the nearest neighbor hopping observed for aromatic linkers. The novel analysis based on percolation theory attributes the superior performance of devices functionalized with π-conjugated molecules to the improved interflake electronic connectivity and formation of additional percolation paths, as further corroborated by density functional calculations. Valuable guidelines for harnessing the charge-transport properties in MoS2 devices based on covalent networks are provided.

Topics & Concepts

Materials sciencePercolation (cognitive psychology)Covalent bondPercolation theoryCharge (physics)Variable-range hoppingDensity functional theoryChemical physicsNanotechnologyElectronicsSemiconductorMoleculeMolecular electronicsComputational chemistryConductivityOptoelectronicsChemistryThermal conductionPhysicsOrganic chemistryComposite materialPhysical chemistryQuantum mechanicsBiologyNeuroscience2D Materials and ApplicationsGraphene research and applicationsAdvanced Memory and Neural Computing
Unveiling Charge‐Transport Mechanisms in Electronic Devices Based on Defect‐Engineered MoS <sub>2</sub> Covalent Networks | Litcius