posted on 2017-03-24, 00:00authored byA. Higuera-Rodriguez, B. Romeira, S. Birindelli, L. E. Black, E. Smalbrugge, P. J. van Veldhoven, W. M. M. Kessels, M. K. Smit, A. Fiore
The
III–V semiconductor InGaAs is a key material for photonics
because it provides optical emission and absorption in the 1.55 μm
telecommunication wavelength window. However, InGaAs suffers from
pronounced nonradiative effects associated with its surface states,
which affect the performance of nanophotonic devices for optical interconnects,
namely nanolasers and nanodetectors. This work reports the strong
suppression of surface recombination of undoped InGaAs/InP nanostructured
semiconductor pillars using a combination of ammonium sulfide, (NH4)2S, chemical treatment and silicon oxide, SiOx, coating. An 80-fold enhancement in the
photoluminescence (PL) intensity of submicrometer pillars at a wavelength
of 1550 nm is observed as compared with the unpassivated nanopillars.
The PL decay time of ∼0.3 μm wide square nanopillars
is dramatically increased from ∼100 ps to ∼25 ns after
sulfur treatment and SiOx coating. The
extremely long lifetimes reported here, to our knowledge the highest
reported to date for undoped InGaAs nanostructures, are associated
with a record-low surface recombination velocity of ∼260 cm/s.
We also conclusively show that the SiOx capping layer plays an active role in the passivation. These results
are crucial for the future development of high-performance nanoscale
optoelectronic devices for applications in energy-efficient data optical
links, single-photon sensing, and photovoltaics.