Theoretical analyses of amorphous semiconductor multijunctions

Abstract: The transport of charge carriers in a multijunction, consisting of alternating thin p- and n-type sublayers of amorphous semiconductor, has been analyzed theoretically. It is shown that the multijunction behaves in the dark like a pn-junction diode, while it has an advantage in reducing range limitation of photogenerated carriers. These properties are realized when the sublayer thickness is of the order of 100 nm for realistic values of doping levels and localized state density.

“…4. Now using (4) and (9b) in (9a) and then applying dw,,/d8 = 0 for a new equilibrium under the applied field, one has…”

“…Now the equilibrium condition in (4) gives solutions as (6 a) either 6 = 0" or 6 = 90" and if 8 #= 0, 6 + 90", the cone angle is given by…”

“…1). The energy density, W, has been calculated using these values of K , and K , in (4) for all values of 0 (i.e., from H = 0 to 360") with P, = 1 C/m2. Fig.…”

Electric field dependent dielectric constants in amorphous semiconductors

“…4. Now using (4) and (9b) in (9a) and then applying dw,,/d8 = 0 for a new equilibrium under the applied field, one has…”

“…Now the equilibrium condition in (4) gives solutions as (6 a) either 6 = 0" or 6 = 90" and if 8 #= 0, 6 + 90", the cone angle is given by…”

“…1). The energy density, W, has been calculated using these values of K , and K , in (4) for all values of 0 (i.e., from H = 0 to 360") with P, = 1 C/m2. Fig.…”

Electric field dependent dielectric constants in amorphous semiconductors

Special conductivity effects in amorphous hydrogenated silicon

Planar anisotropy in amorphous semiconductors