stem/Semiconductors/Equations.md
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655 B

R=\frac{\rho L}{A}
  • R = Resistance
  • \rho = Resistivity (\Omega cm)
  • L = Length
  • A = CS Area
J=\sigma E
  • J = Current Density
  • \sigma = Conductivity (\frac{1}{\Omega cm})
  • E = Electric Field
V_{bi} = \frac{kT}{q}ln(\frac{N_D N_A}{n_i^2})
  • V_{bi} = Built-in Potential Doping
J=nev
  • n = Charge Density
  • e = Charge
  • v = Drift Velocity
v=\mu E
  • v = Drift Velocity
  • \mu = Mobility
  • E = Electric Field
\sigma = ne\mu
\rho=\frac{1}{\sigma}
\sigma=q(\mu_nn+\mu_pp)
  • q = Electronic Charge
  • \mu = Carrier Mobility (\frac{cm^2}{Vs})
1 eV = 1.602\times 10^{-19}J