Thank You for the whole playlist, it's very practical and well explained. By the minute 7:36 it is written that Δnp_0=np_0(e^(Vd/Φt)), so it becomes zero when I don't apply any voltage? Thank You again (still here in 2024)
Jordan, thank you for the video. At 1:14 you said "much, much less than" but I believe you meant "greater" based on what you wrote, what you later said, and the context.
At 9:11 you said '' Concentration gradient must be zero at x=W. '' but in the equation you plugged W in concentration itself - n - . Why didn't you plug in W to the gradient -dn/dx-? Doesn't change that much tho, just miss a negative sign on A. Also, your videos are great!
Thank You for the whole playlist, it's very practical and well explained. By the minute 7:36 it is written that Δnp_0=np_0(e^(Vd/Φt)), so it becomes zero when I don't apply any voltage? Thank You again (still here in 2024)
Jordan, thank you for the video. At 1:14 you said "much, much less than" but I believe you meant "greater" based on what you wrote, what you later said, and the context.
ik im almost a year late but yes you're right
At 9:11 you said '' Concentration gradient must be zero at x=W. '' but in the equation you plugged W in concentration itself - n - . Why didn't you plug in W to the gradient -dn/dx-? Doesn't change that much tho, just miss a negative sign on A. Also, your videos are great!
(6:40) What is Δn_p?
shouldn't it be like Δn_p(x)=npo(e^Vd/ΦT -1)e^(-x/Ln)?