Author Correction: Longitudinal unzipping of 2D transition metal dichalcogenides

Abstract: An amendment to this paper has been published and can be accessed via a link at the top of the paper.

“…[7][8][9][10] Several attempts have been made to reduce the dimensionality of TMDs towards more one-dimensional nanoribbons. Top-down techniques, where the two-dimensional parent material is cut into strips have been realized through chemical unzipping techniques [11,12] as well as with lithographic strategies employing electron [13] or ion beams [14].…”

Charge-induced phase transition in encapsulated HfTe2 nanoribbons

“…[7][8][9][10] Several attempts have been made to reduce the dimensionality of TMDs towards more one-dimensional nanoribbons. Top-down techniques, where the two-dimensional parent material is cut into strips have been realized through chemical unzipping techniques [11,12] as well as with lithographic strategies employing electron [13] or ion beams [14].…”

Charge-induced phase transition in encapsulated HfTe2 nanoribbons

“…Unlike the GO membrane that has ample oxygen-containing active sites, the surface S-layers of MoS 2 are relatively inert, whose chemical modification is difficult, resulting in a longer useful life of MoS 2 membrane. [34][35][36][37][38] Wang et al confirmed the above membrane property through experiments. 14 MoS 2 membrane with high water permeance flux (30-250 L m À2 h À1 bar À1 ) was obtained; the interlayer spacing in this membrane did not change after being immersed in water for three days.…”

Modification of a MoS₂ composite membrane using nano-silica for high-efficiency dye separation

“…The bright excitons in A7WSe 2 generally show a mixed spin configuration in the electron and hole pairs, while the lowest energy dark excitons show a varying spin configuration with bending, potential for possible applications in spinbased quantum information processes. TMD nanoribbons can be made by cutting the preexisting TMD nanotubes or sheets through chemical reactions, 40,41 laser irradiation, 42 or ion-beam milling, 43 growing nanoribbons with TMD nanowires, 44 or growing nanoribbons inside carbon nanotubes. 45,46 The TMD nanoribbons with a width of B1-4 nm were already prepared.…”

Spin-polarization anisotropy controlled by bending in tungsten diselenide nanoribbons and tunable excitonic states