Micromachines (Dec 2023)

Performance Investigations of InAs/InP Quantum-Dash Semiconductor Optical Amplifiers with Different Numbers of Dash Layers

  • Youxin Mao,
  • Xiaoran Xie,
  • Chunying Song,
  • Zhenguo Lu,
  • Philip J. Poole,
  • Jiaren Liu,
  • Mia Toreja,
  • Yang Qi,
  • Guocheng Liu,
  • Pedro Barrios,
  • Daniel Poitras,
  • John Weber,
  • Ping Zhao,
  • Martin Vachon,
  • Mohamed Rahim,
  • Penghui Ma,
  • Silas Chen,
  • Ahmad Atieh

DOI
https://doi.org/10.3390/mi14122230
Journal volume & issue
Vol. 14, no. 12
p. 2230

Abstract

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We present here a performance comparison of quantum-dash (Qdash) semiconductor amplifiers (SOAs) with three, five, eight, and twelve InAs dash layers grown on InP substrates. Other than the number of Qdash layers, the structures were identical. The eight-layer Qdash SOA gave the highest amplified spontaneous emission power (4.3 dBm) and chip gain (26.4 dB) at 1550 nm, with a 300 mA CW bias current and at 25 °C temperature, while SOAs with fewer Qdash layers (for example, three-layer Qdash SOA), had a wider ASE bandwidth (90 nm) and larger 3 dB gain saturated output power (18.2 dBm) in a shorter wavelength range. The noise figure (NF) of the SOAs increased nearly linearly with the number of Qdash layers. The longest gain peak wavelength of 1570 nm was observed for the 12-layer Qdash SOA. The most balanced performance was obtained with a five-layer Qdash SOA, with a 25.4 dB small-signal chip gain, 15.2 dBm 3 dB output saturated power, and 5.7 dB NF at 1532 nm, 300 mA and 25 °C. These results are better than those of quantum well SOAs reported in a recent review paper. The high performance of InAs/InP Qdash SOAs with different Qdash layers shown in this paper could be important for many applications with distinct requirements under uncooled scenarios.

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