posted on 2017-01-17, 00:00authored byKonrad Maier, Andreas Helwig, Gerhard Müller, Pascal Hille, Jörg Teubert, Martin Eickhoff
We demonstrate that the complex adsorption
behavior of H2O on InGaN/GaN nanowire arrays is
directly revealed by their
ambient-dependent photoluminescence properties. Under low-humidity,
ambient-temperature, and low-excitation-light conditions, H2O adsorbates cause a quenching of the photoluminescence. In contrast,
for high humidity levels, elevated temperature, and high excitation
intensity, H2O adsorbates act as efficient photoluminescence
enhancers. We show that this behavior, which can only be detected
due to the low operation temperature of the InGaN/GaN nanowires,
can be explained on the basis of single H2O adsorbates
forming surface recombination centers and multiple H2O
adsorbates forming surface passivation layers. Reversible creation
of such passivation layers is induced by the photoelectrochemical
splitting of adsorbed water molecules and by the interaction of reactive
H3O+ and OH– ions with photoactivated
InGaN surfaces. Due to electronic coupling of adsorbing molecules
with photoactivated surfaces, InGaN/GaN nanowires act as sensitive
nanooptical probes for the analysis of photoelectrochemical surface
processes.