Final answer:
To find the junction depth for a Gaussian distribution in phosphorus diffusion in a p-type wafer, the given surface concentration, background concentration, and the Dt product are used in the formula derived from a Gaussian distribution profile.
Step-by-step explanation:
The question pertains to semiconductor physics, specifically to the process of phosphorus diffusion in a p-type silicon wafer and finding out the junction depth associated with a Gaussian distribution. To calculate the junction depth where the concentration equals the intrinsic level (approximately equal to the background concentration for p-type material), we use the concept of the Gaussian distribution. The equation for the junction depth (xj) in a Gaussian distribution is given by:
xj = √(2 * Dt * ln(Nsurface/Nbackground))
Where:
- Dt is the diffusion coefficient multiplied by time (product for diffusion)
- Nsurface is the surface concentration
- Nbackground is the background concentration
- ln is the natural logarithm function
Given:
- Nsurface = 5 x 10ⁱ⁸ /cm³
- Nbackground = 1 x 10ⁱ⁵ /cm³
- Dt = 10⁻⁸ cm²
Plugging the values into the junction depth equation we get:
xj = √(2 * 10⁻⁸ cm² * ln(5 x 10ⁱ⁸ /cm³ / 1 x 10ⁱ⁵ /cm³))
Solving for xj will provide the junction depth for the phosphorus diffusion in the silicon wafer.