Add to ORKGWe report an extension of the analytical dead space multiplication theory that provides the means to theoretically determine the spatial distribution of electron and hole impact-ionization events in an arbitrarily specified heterojunction multiplication region. The model can be used to understand the role of the dead space in regularizing the locations of impact ionization. It can also be utilized to analyze, design, and optimize new generations of ultra-low noise, multistaged gain avalanche photodiodes based upon judiciously energizing and relaxing carriers to enhance electron impact ionization and suppress hole impact ionization
The effects of impact ionization in the InGaAs absorption layer on the multiplication, excess noise ...
A systematic study of impact ionization, avalanche multiplication, and excess noise in InAs diodes h...
11We propose a simple expression to relate the total excess noise factor of a single-carrier multipl...
It is, by now, well known that McIntyre\u27s localized carrier-multiplication theory cannot explain ...
Simple, approximate formulas are developed to calculate the mean gain and excess noise factor for av...
A stochastic dead-space model for impact ionization is developed and used to study the effect of the...
Simple, approximate formulas are developed to calculate the mean gain and excess noise factor for av...
We present a non-local history-dependent model for impact ionization gain and noise in avalanche pho...
The nonlocal enhancement in the velocities of charge carriers to ionization is shown to outweigh the...
The history-dependent recurrence theory for multiplication noise in avalanche photodiodes (APDs), de...
Abstract-Approximate analytical expressions are derived for the mean gain and the excess noise facto...
For applications requiring the detection of low light levels, avalanche photodiodes (APDs) are the p...
12noWe present a nonlocal history-dependent model for impact ionization gain and noise in avalanche ...
Multiplication measurements on GaAs p+-i-n+s with i-region thicknesses, w, between 1 μm and 0.025 μm...
The effect of dead space on the mean gain, the excess noise factor, and the avalanche breakdown volt...
The effects of impact ionization in the InGaAs absorption layer on the multiplication, excess noise ...
A systematic study of impact ionization, avalanche multiplication, and excess noise in InAs diodes h...
11We propose a simple expression to relate the total excess noise factor of a single-carrier multipl...
It is, by now, well known that McIntyre\u27s localized carrier-multiplication theory cannot explain ...
Simple, approximate formulas are developed to calculate the mean gain and excess noise factor for av...
A stochastic dead-space model for impact ionization is developed and used to study the effect of the...
Simple, approximate formulas are developed to calculate the mean gain and excess noise factor for av...
We present a non-local history-dependent model for impact ionization gain and noise in avalanche pho...
The nonlocal enhancement in the velocities of charge carriers to ionization is shown to outweigh the...
The history-dependent recurrence theory for multiplication noise in avalanche photodiodes (APDs), de...
Abstract-Approximate analytical expressions are derived for the mean gain and the excess noise facto...
For applications requiring the detection of low light levels, avalanche photodiodes (APDs) are the p...
12noWe present a nonlocal history-dependent model for impact ionization gain and noise in avalanche ...
Multiplication measurements on GaAs p+-i-n+s with i-region thicknesses, w, between 1 μm and 0.025 μm...
The effect of dead space on the mean gain, the excess noise factor, and the avalanche breakdown volt...
The effects of impact ionization in the InGaAs absorption layer on the multiplication, excess noise ...
A systematic study of impact ionization, avalanche multiplication, and excess noise in InAs diodes h...
11We propose a simple expression to relate the total excess noise factor of a single-carrier multipl...