Abstract:
The variation of electric potential has been investigated when a semiconducting structure
is placed under an external electric field. Finite Difference Methods have been employed
with Mathamatica software to generate codes. An external electric field was created by
applying voltages to the side faces of a box as (10V, oV, oV, oV). Three-dimensional plot
of electric potential versus position in x and y direction was created. By extracting data
along in x or y direction a line graph of potential versus position has been created. A
semiconducting strip made with two different dielectric mediums is placed inside the
box so that both mediums face the 10V side at the same time. Two curves were extracted
from potential map at x=7 [from medium one (e^] and at x=i3 [from medium two (e2)]. A
significant change in the curve shape has been observed with the semiconducting material
and without it. A faster potential drop has been observed in medium one with small
dielectric constant than the medium two with larger dielectric constant. The semiconductor
was rotated by 90 degrees so that only one medium faces the 10V side. A higher gradient of
the potential was observed in medium one compared to medium two with large dielectric
constant. Data was extracted at x=n. The potential has been changed from 10V to 5.8V
when it changed to medium one. At the interface of the two mediums it has been changed
to 2.36V and at the end of medium two it has been changed to 1.86V. By using these data
the true electric field was calculated for different materials.
