In
the past few years, several protocols have been reported on
the synthesis of CdSe nanoplatelets with narrow photoluminescence
(PL) spectrum, high PL quantum efficiency, and short exciton lifetime.
The corresponding core/shell nanoplatelets are however still mostly
based on CdSe/CdS, which possess an extended lifetime and a strong
red shift of the band-edge absorption and emission, in accordance
with a quasi-type-II band alignment. Here we report on a robust synthesis
procedure to grow a ZnS shell around CdSe nanoplatelets at moderate
temperatures of 100–150 °C, to improve the optical properties
of CdSe nanoplatelets via a type-I core/shell heterostructure. The
shell growth is performed under ambient atmosphere, in either toluene
or 1,2-dichlorobenzene. The variation of the shell thickness induces
a continuous red shift of the PL peak, eventually reaching 611 nm.
The PL quantum efficiency is increased compared to the original CdSe
cores, with values up to 60% depending on the shell thickness. High-resolution
transmission electron microscopy reveals a bending of the nanoplatelets
caused by strain due to 12% lattice mismatch between CdSe and ZnS.
The present procedure can easily be translated to other core/shell
nanocrystals, such as CdSe/CdS and CdSe/CdZnS nanoplatelets.
The spectral dependence of the two-photon absorption in CdSe/CdS core/shell nanocrystal heterorods has been studied via two-photon-induced luminescence excitation spectroscopy. We verified that the two-photon absorption in these samples is a purely nonlinear phenomenon, excluding the contribution from multistep linear absorption mediated by defect states. A large absorption cross section was observed for CdSe/CdS core/shell quantum rods, in the range of 10(5) GM (1 GM = 10(-50) cm(4) s phot(-1)), scaling with the total nanocrystal volume and thus independent of the core emission wavelength. In the two-photon luminescence excitation spectra, peaks are strongly blue-shifted with respect to the one-photon absorption peaks, for both core and shell transitions. The experimental results are confirmed by k·p calculations, which attribute the shift to both different parity selection rules that apply to one-photon and two-photon transitions and a low oscillator strength for two-photon transitions close to the ground-state one-photon absorption. In contrast with lead chalcogenide quantum dots, we found no evidence of a breakdown of the optical selection rules, despite the presence of band anisotropy, via the anisotropic hole masses, and the explicitly induced reduction of the electron wave function symmetry via the rod shape of the shell. The anisotropy does lead to an unexpected splitting of the electron P-states in the case of a large CdSe core encapsulated in a thin CdS shell. Hence, tuning of the core and shell dimensions and the concurrent transition from type I to quasi-type II carrier localization enables unprecedented control over the band-edge two-photon absorption.
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We investigate the spectral dependence of the linear and two-photon absorption of wurtzite CdS nanoparticles (dots and rods) by means of quantitative one-and two-photon photoluminescence excitation spectroscopy and effective mass theory modeling. Absolute two-photon absorption cross sections free from spectrally varying beam related uncertainties are obtained by means of a new reference dyebased method. The two-photon spectrum features of rods strongly differ from those of dots, due to the distinct energy structure of quasi-one-dimensional systems. The transversal confinement is found to dominate the energy of the absorption maxima while the longitudinal one dominates their absorption intensity. This suggests two-photon transition energy and intensity can be controlled independently in nanorods. For both geometries we observe a sizable spectral shift between the first one-and two-photon absorption maxima, which we conclude is inherent to the small rates of near-bandgap two-photon transitions rather than to the particular geometry of the absorber. The provided understanding of the spectral dependence of the two-photon absorption of CdS dots and rods is of strong interest for the design of nanocrystals with optimized two-photon absorption properties for bioimaging and phototherapy applications.
We show theoretically that carriers confined in semiconductor colloidal nanoplatelets (NPLs) sense the presence of neighbor, cofacially stacked NPLs in their energy spectrum. When approaching identical NPLs, the otherwise degenerate energy levels redshift and split, forming (for large stacks) minibands of several meV width. Unlike in epitaxial structures, the molecular behavior does not result from quantum tunneling but from changes in the dielectric confinement. The associated excitonic absorption spectrum shows a rich structure of bright and dark states, whose optical activity and multiplicity can be understood from reflection symmetry and Coulomb tunneling.We predict spectroscopic signatures which should confirm the formation of molecular states, whose practical realization would pave the way to the development of nanocrystal chemistry based on NPLs.
Colloidal semiconductor nanomaterials present broadband,
with large
cross-section, two-photon absorption (2PA) spectra, which turn them
into an important platform for applications that benefit from a high
nonlinear optical response. Despite that, to date, the only means
to control the magnitude of the 2PA cross-section is by changing the
nanoparticle volume, as it follows a universal volume scale, independent
of the material composition. As the emission spectrum is connected
utterly to the nanomaterial dimensions, for a given material, the
magnitude of the nonlinear optical response is also coupled to the
emission spectra. Here, we demonstrate a means to decouple both effects
by exploring the 2PA response of different types of heterostructures,
tailoring the volume dependence of the 2PA cross-section due to the
different dependence of the density of final states on the nanoparticle
volume. By heterostructure engineering, one can obtain 1 order of
magnitude enhancement of the 2PA cross-section with minimum emission
spectra shift.
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