- #1
DeldotB
- 117
- 8
Good day all:
For the diode equation: I(V)=I_{sat}e^{\frac{Ve}{nKT}}-I_{sat}
I also know that the second term in the equation is negligible if: V> > nV_{T}
Vt is thermal voltage
n is ...just a factor related to the quality of the material
I have these initial conditions:
V> 0.1V\, \, \, ,kT\approx .025 eV\, \, \, n\approx 2
Its easy to show that the my inital conditions lead to a V much greater that n*thermal voltage.
My question is: Why is the saturation Current negligible? I know it has something to do with recombination rate but can anyone give me a simple explanation? So many websites just say that the order relation is true but give no evidence as to why.
For the diode equation: I(V)=I_{sat}e^{\frac{Ve}{nKT}}-I_{sat}
I also know that the second term in the equation is negligible if: V> > nV_{T}
Vt is thermal voltage
n is ...just a factor related to the quality of the material
I have these initial conditions:
V> 0.1V\, \, \, ,kT\approx .025 eV\, \, \, n\approx 2
Its easy to show that the my inital conditions lead to a V much greater that n*thermal voltage.
My question is: Why is the saturation Current negligible? I know it has something to do with recombination rate but can anyone give me a simple explanation? So many websites just say that the order relation is true but give no evidence as to why.
