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Charge-transport anisotropy in black phosphorus: critical dependence on the number of layers

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dc.contributor.author Banerjee, Swastika
dc.contributor.author Pati, Swapan Kumar
dc.date.accessioned 2017-01-24T06:44:42Z
dc.date.available 2017-01-24T06:44:42Z
dc.date.issued 2016
dc.identifier.citation Banerjee, S.; Pati, S. K., Charge-transport anisotropy in black phosphorus: critical dependence on the number of layers. Physical Chemistry Chemical Physics 2016, 18 (24), 16345-16352 http://dx.doi.org/10.1039/c6cp02129h en_US
dc.identifier.citation Physical Chemistry Chemical Physics en_US
dc.identifier.citation 18 en_US
dc.identifier.citation 24 en_US
dc.identifier.issn 1463-9076
dc.identifier.uri https://libjncir.jncasr.ac.in/xmlui/10572/2249
dc.description Restricted Access en_US
dc.description.abstract Phosphorene is a promising candidate for modern electronics because of the anisotropy associated with high electron-hole mobility. Additionally, superior mechanical flexibility allows the strain-engineering of various properties including the transport of charge carriers in phosphorene. In this work, we have shown the criticality of the number of layers to dictate the transport properties of black phosphorus. Trilayer black phosphorus (TBP) has been proposed as an excellent anisotropic material, based on the transport parameters using Boltzmann transport formalisms coupled with density functional theory. The mobilities of both the electron and the hole are found to be higher along the zigzag direction (similar to 10(4) cm(2) V-1 s(-1) at 300 K) compared to the armchair direction (similar to 10(2) cm(2) V-1 s(-1)), resulting in the intrinsic directional anisotropy. Application of strain leads to additional electron-hole anisotropy with 103 fold higher mobility for the electron compared to the hole. Critical strain for maximum anisotropic response has also been determined. Whether the transport anisotropy is due to the spatial or charge-carrier has been determined through analyses of the scattering process of electrons and holes, and their recombination as well as relaxation dynamics. In this context, we have derived two descriptors (S and F(k)), which are general enough for any 2D or quasi-2D systems. Information on the scattering involving purely the carrier states also helps to understand the layer-dependent photoluminescence and electron (hole) relaxation in black phosphorus. Finally, we justify trilayer black phosphorus (TBP) as the material of interest with excellent transport properties. en_US
dc.description.uri 1463-9084 en_US
dc.description.uri http://dx.doi.org/10.1039/c6cp02129h en_US
dc.language.iso English en_US
dc.publisher Royal Society of Chemistry en_US
dc.rights @Royal Society of Chemistry, 2016 en_US
dc.subject Chemistry en_US
dc.subject Physics en_US
dc.subject Field-Effect Transistors en_US
dc.subject Mobility en_US
dc.subject Semiconductor en_US
dc.title Charge-transport anisotropy in black phosphorus: critical dependence on the number of layers en_US
dc.type Article en_US


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