Replication Data for: Transient ultrafast and negative diffusion of charge carriers in suspended MoSe2 from multilayer to monolayer

Understanding the ultrafast transport properties of charge carriers in transition metal dichalcogenides is essential for advancing technologies based on these materials. Here, we study MoSe2 crystals with thicknesses down to the monolayer, combining ultrafast spatiotemporal microscopy and quantitati...

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Detalles Bibliográficos
Autores: Lo Gerfo Morganti, Giulia, Rosati, Roberto, Brinatti Vazquez, Guillermo Daniel, Varghese, Sebin, Saleta Reig, David, Malic, Ermin, van Hulst, Niek, Tielrooij, Klaas-Jan
Tipo de recurso: conjunto de datos
Fecha de publicación:2026
País:España
Institución:Consorci de Serveis Universitaris de Catalunya (CSUC)
Repositorio:CORA.Repositori de Dades de Recerca
OAI Identifier:oai:dnet:cora.rdr____::11925d1e2a01042ee52aa7fd175736e4
Acceso en línea:https://doi.org/10.34810/DATA3088
Access Level:acceso abierto
Palabra clave:Physics
Transition metal dichalcogenides
Excitons
Descripción
Sumario:Understanding the ultrafast transport properties of charge carriers in transition metal dichalcogenides is essential for advancing technologies based on these materials. Here, we study MoSe2 crystals with thicknesses down to the monolayer, combining ultrafast spatiotemporal microscopy and quantitative microscopic modelling. Crucially, we obtain the intrinsic ultrafast transport dynamics by studying suspended crystals that do not suffer from detrimental substrate effects. In mono- and bilayer crystals, we identify four sequential transport regimes. The first two regimes involve high-energy non-thermalized and quasi-thermalized carriers that propagate rapidly with diffusivities up to 1000 cm2/s. After ~1.5 ps, a remarkable third regime occurs with apparent negative diffusion, finally followed by exciton propagation limited by trapping into defect states. Interestingly, for trilayer and thicker crystals, only the first and last regimes occur. This work underscores the role of traps and dielectric environment in electron transport, offering valuable insights for the development of (flexible) (opto)electronic applications.