Colloidal two-dimensional (2D) lead chalcogenide nanoplatelets (NPLs) represent highly interesting materials for near- and short wave-infrared applications including innovative glass fiber optics exhibiting negligible attenuation. In this work, we demonstrate...
Colloidal 2D PbSe nanoplatelets (NPLs) are promising
near- and
short wave-infrared emitters for optoelectronic applications at telecommunication
wavelengths. However, their photoluminescence quantum yield (PLQY)
is limited by the ubiquitous presence of surface-related trap states.
Here, we apply a treatment of colloidal PbSe NPLs with different metal
halides (MX2, M = Zn, Cd, Pb; X = F, Cl, Br, I) to improve
their emission brightness. A surface passivation of the NPLs by PbI2 leads to the best results with a strongly increased PLQY
(27% for PbSe NPLs emitting at 0.98 eV (1265 nm) and up to 61% for
PbSe NPLs emitting at 1.25 eV (989 nm)). Simultaneously, the full
width at half-maximum of the NPL photoluminescence decreased by 10%
after the treatment. X-ray photoelectron spectroscopy and complementary
surface treatment of PbSe NPLs with organic halides reveal the combined
passivating role of both X-type binding halides X– and Z-type binding metal halides MX2 in enhancing the
optical properties of the PbSe NPLs. Our results emphasize the potential
of 2D PbSe NPLs for efficient emission tailored for the application
in fiber optics.
Metal halide perovskites (MHPs) are disruptive materials for a vast class of optoelectronic devices. The presence of electronic trap states has been a tough challenge in terms of characterization and thus mitigation. Many attempts based on electronic spectroscopies have been tested, but due to the mixed electronic−ionic nature of MHP conductivity, many experimental results retain a large ambiguity in resolving electronic and ionic charge contributions. Here we adapt a method, previously used in highly resistive inorganic semiconductors, called photoinduced current transient spectroscopy (PICTS) on lead bromide 2D-like ((PEA) 2 PbBr 4 ) and standard "3D" (MAPbBr 3 ) MHP single crystals. We present two conceptually different outcomes of the PICTS measurements, distinguishing the different electronic and ionic contributions to the photocurrents based on the different ion drift of the two materials. Our experiments unveil deep level trap states on the 2D, "ion-frozen" (PEA) 2 PbBr 4 and set new boundaries for the applicability of PICTS on 3D MHPs.
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