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Electron-Hole Recombination Statistics in Semiconductors through Flaws with Many Charge Conditions

1958; American Institute of Physics; Volume: 109; Issue: 4 Linguagem: Inglês

10.1103/physrev.109.1103

1536-6065

Chih‐Tang Sah, W. Shockley,

Integrated Circuits and Semiconductor Failure Analysis

A flaw with $s$ electronic units of negative charge makes transitions to charge $s+1$ by hole emission at rate $e(p, s)$ or by electron capture at rate $nc(n, s)$ and returns to charge $s$ at rates $e(n, s+1)$ and $pc(p, s+1)$. Here $n$ is the electron density in the conduction band and $p$ is the hole density in the valence band. The steady-state ratio of populations ${N}_{s+1}$ to ${N}_{s}$ is given by $\frac{c(n, s)[n+{n}^{*}(s+\frac{1}{2})]}{c(p, s+1)[p+{p}^{*}(s+\frac{1}{2})]},$ where ${n}^{*}(s+\frac{1}{2})=\frac{e(p, s)}{c(n, s)}$ and ${p}^{*}(s\frac{1}{2})=\frac{e(n, s+1)}{c(p, s+1)}$. This distribution corresponds to an effective Fermi level for the flaws only for the condition of thermal equilibrium. Expressions for the recombination rate based on the steady-state distribution are derived. For a given transition $s\ensuremath{\rightleftarrows}s+1$ the following special cases are defined: (1) denuded: $n<{n}^{*}$, $p<{p}^{*}$; (2) $n$-dominated: $n>{n}^{*}$, $p<{p}^{*}$; (3) $p$-dominated: $n<{n}^{*}$, $p>{p}^{*}$; (4) flooded: $n>{n}^{*}$, $p>{p}^{*}$. Diagrams which aid in visualizing the relative importance of the various transitions are presented. Some speculations on the nature of trapping centers are given.