Interfacial reaction-dominated full oxidation of 5 nm diameter silicon nanowires

Abstract: Silver catalyzed ultrathin silicon nanowires grown by low-temperature chemical-vapor-deposition J. Appl. Phys. 107, 096105 (2010); 10.1063/1.3393601Study of the effect of gas pressure and catalyst droplets number density on silicon nanowires growth, tapering, and gold coverage While almost all Si nanostructures, including Si nanowires (SiNWs), Si nanocrystals, and Si nanotrench-like structures on a supra-or sub-10 nm scale exhibit self-limiting oxidative behavior, herein we report full oxidation of SiNWs 5 nm … Show more

“…Consequently, the thinner Si-NWs will be readily oxidized under the same driving force of oxidation, leading to full oxidation, as observed in the sub-10 nm Si-NWs. [10][11][12]14 In summary, the present MD simulation showed that the residual stress decreased with increasing curvature in the sub-10 nm regime of the diameter. In this regime, the unoxidized Si core of the thinner Si-NWs deformed more to compensate for the volume expansion of the surface oxide layer, resulting in the smaller compressive stress.…”

“…[2][3][4][5][6][7][8][9][10][11][12][13] However, recent experimental work with Si-NWs with diameters of approximately 10 nm reported full oxidation of the NWs. [10][11][12][13][14] These experimental observations are puzzling from the viewpoint of the previous theoretical model that the self-limiting oxidation is caused by the interfacial compressive stress which is proportional to the curvature of NWs. [7][8][9] The theoretical analysis would imply that the oxidation is extremely limited or totally suppressed in very thin Si-NWs.…”

Stress evolution during the oxidation of silicon nanowires in the sub-10 nm diameter regime

“…Consequently, the thinner Si-NWs will be readily oxidized under the same driving force of oxidation, leading to full oxidation, as observed in the sub-10 nm Si-NWs. [10][11][12]14 In summary, the present MD simulation showed that the residual stress decreased with increasing curvature in the sub-10 nm regime of the diameter. In this regime, the unoxidized Si core of the thinner Si-NWs deformed more to compensate for the volume expansion of the surface oxide layer, resulting in the smaller compressive stress.…”

“…[2][3][4][5][6][7][8][9][10][11][12][13] However, recent experimental work with Si-NWs with diameters of approximately 10 nm reported full oxidation of the NWs. [10][11][12][13][14] These experimental observations are puzzling from the viewpoint of the previous theoretical model that the self-limiting oxidation is caused by the interfacial compressive stress which is proportional to the curvature of NWs. [7][8][9] The theoretical analysis would imply that the oxidation is extremely limited or totally suppressed in very thin Si-NWs.…”

Stress evolution during the oxidation of silicon nanowires in the sub-10 nm diameter regime

Interface modification and trap-type transformation in Al-doped CdO/Si-nanowire arrays/p-type Si devices by nanowire surface passivation

A diffusion, oxidation reaction and large viscoelastic deformation coupled model with applications to SiC fiber oxidation