Structural optimization of a superlattice infrared photodetector by evolutionary computation algorithms

Structural optimization of a superlattice infrared photodetector by evolutionary computation algorithms

We present a study of the use of evolutionary computation in the design of a new superlattice infrared photodetector (SLIP). Four optimization algorithms were used to find the parameters of the superlattice, specifically the thickness of the quantum wells and quantum barriers, which give the desired...

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Bibliographic Details
Published in:2019 34th Symposium on Microelectronics Technology and Devices (SBMicro) pp. 1 - 4
Main Authors: Povoa, Rogerio Cortez Brito Leite, Pereira, Pedro Henrique, Torelly, Guilherme M., Dias, Douglas Mota, Penello, Germano Maioli, Pires, Mauricio Pamplona, Horta, Bruno Araujo Cautiero, Souza, Patricia Lustoza
Format: Conference Proceeding
Language:English
Published: IEEE 01-08-2019
Subjects:
Evolutionary computation
Intersubband Transition
Optical superlattices
Optimization
Oscillators
Photodetector
Photodetectors
Quantum Well
Stationary state
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Summary:We present a study of the use of evolutionary computation in the design of a new superlattice infrared photodetector (SLIP). Four optimization algorithms were used to find the parameters of the superlattice, specifically the thickness of the quantum wells and quantum barriers, which give the desired detection energy with the highest possible oscillator strength. The initial parameters for optimization are of a reference SLIP with detection energy and corresponding oscillator strength equal to 300 meV and 0.22, respectively. All optimization algorithms converged to a new superlattice with an oscillator strength around 0.35 for the same detection, a value 59% greater than the reference SLIP.
DOI:10.1109/SBMicro.2019.8919346