posted on 2024-01-25, 01:07authored bySonja Wieland, Abdurrahman Ali El Yumin, Simon Settele, Jana Zaumseil
Oxygen defects in semiconducting single-walled carbon
nanotubes
(SWCNTs) are localized disruptions in the carbon lattice caused by
the formation of epoxy or ether groups, commonly through wet-chemical
reactions. The associated modifications of the electronic structure
can result in luminescent states with emission energies below those
of pristine SWCNTs in the near-infrared range, which makes them promising
candidates for applications in biosensing and as single-photon emitters.
Here, we demonstrate the controlled introduction of luminescent oxygen
defects into networks of monochiral (6,5) SWCNTs using a solid-state
photocatalytic approach. UV irradiation of SWCNTs on the photoreactive
surfaces of the transition metal oxides TiOx and ZnOx in the presence of trace
amounts of water and oxygen results in the creation of reactive oxygen
species that initiate radical reactions with the carbon lattice and
the formation of oxygen defects. The created ether-d and epoxide-l
defect configurations give rise to two distinct red-shifted emissive
features. The chemical and dielectric properties of the photoactive
oxides influence the final defect emission properties, with oxygen-functionalized
SWCNTs on TiOx substrates being brighter
than those on ZnOx or pristine SWCNTs
on glass. The photoinduced functionalization of nanotubes is further
employed to create lateral patterns of oxygen defects in (6,5) SWCNT
networks with micrometer resolution and thus spatially controlled
defect emission.