论文信息 - Nitrogen-plasma study for plasma-assisted MBE growth of 1.3 μm laser diodes

Nitrogen-plasma study for plasma-assisted MBE growth of 1.3 μm laser diodes

Abstract We have studied the influence of radio-frequency plasma cell operating conditions on the plasma-assisted molecular-beam epitaxy growth of bulk GaAsN and GaInAsN quantum wells. For low N 2 flow rates, the species that mostly incorporate are atoms and the dissociation fraction of N 2 for the lowest flow rate and the highest RF power has been found to be up to 0.7. For high N 2 flow rates, the species that mostly incorporate are vibrationally excited molecules in the N 2 ( X , v ) ground state. The vibrational temperature of the N 2 ( X , v ) ground state has been found to be higher than 10 4 K. The ion damage has been decreased by increasing the N 2 pressure which induces a decrease of the electron temperature and consequently a decrease of the plasma ionization. Oxygen has been evidenced to incorporate proportionally to nitrogen and its emission line has been identified in the plasma emission spectrum. Finally, quantum-well structures emitting at around 1.3 μm at 300 K have been fabricated and characterized by photoluminescence and photocurrent spectroscopy.

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