Design of spin-filtering devices with rectifying effects and negative differential resistance using armchair phosphorene nanoribbon

“…36 Perfect spin filtering was also obtained in the SnSe 2 nanoribbon doped with Ag, 52 and in armchair phosphorene nanoribbons doped with different transition metal atoms. 61 Magnetism has also been predicted to arise from the unpassivated edges of pristine nanoribbons, such as MoS 2 , 62,63 arsenene, and antimonene. 64 Even half-metallicity and perfect spin filtering have been predicted in bare ZnO nanoribbons.…”

Magnetism and perfect spin filtering in pristine MgCl₂ nanoribbons modulated by edge modification

“…36 Perfect spin filtering was also obtained in the SnSe 2 nanoribbon doped with Ag, 52 and in armchair phosphorene nanoribbons doped with different transition metal atoms. 61 Magnetism has also been predicted to arise from the unpassivated edges of pristine nanoribbons, such as MoS 2 , 62,63 arsenene, and antimonene. 64 Even half-metallicity and perfect spin filtering have been predicted in bare ZnO nanoribbons.…”

Magnetism and perfect spin filtering in pristine MgCl₂ nanoribbons modulated by edge modification

Spin-selective transport in edge-passivated zigzag magnesium dichloride nanoribbons: Towards bipolar spin diode and spin rectification devices

Tuning of the electronic structures and spin-dependent transport properties of phosphorene nanoribbons by vanadium substitutional doping