Role of Valley Anisotropy in Optical Absorption of Monodisperse PbS Nanocrystals

Poddubny, Alexander N.; Litvyak, V. M.; Nestoklon, M. O.; Cherbunin, R. V.; Golubkov, V. V.; Onushchenko, P. A.; Бабкина, А. Н.; Onushchenko, A. A.; Goupalov, S. V.

doi:10.1021/acs.jpcc.7b10778

Cited by 7 publications

(6 citation statements)

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“…To overcome this problem, in ref 9 the bulk electron energy dispersion 15 and the experimental effective masses 16 were used to obtain the tight-binding (TB) parameters of PbS and PbSe suitable for large-scale calculations. 6,17 Note that, in practical realizations of the TB method, surface passivation is not required due to the high ionicity of PbX. 9,11,18 For our TB calculations we model QDs as truncated cubes "carved out" from the bulk rocksalt lattice by the {100} and {111} planes separated by the distances of a 0 (N + 1/2) and − a N M…”

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confidence: 99%

“…However, due to computational complexity these approaches can be hardly applied to the systematic calculations of the nanostructures. To overcome this problem, in ref the bulk electron energy dispersion and the experimental effective masses were used to obtain the tight-binding (TB) parameters of PbS and PbSe suitable for large-scale calculations. , Note that, in practical realizations of the TB method, surface passivation is not required due to the high ionicity of PbX. ,, …”

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Exciton Fine Structure in Lead Chalcogenide Quantum Dots: Valley Mixing and Crucial Role of Intervalley Electron–Hole Exchange

2020

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We study the exciton fine structure in quantum dots of multivalley lead chalcogenides. We demonstrate that intervalley electron−hole exchange interaction, ignored in previous studies, dramatically modifies the exciton fine structure and leads to appearance of the ultrabright valley-symmetric spin-triplet exciton state dominating interband optical absorption. Valley mixing leads to brightening of other symmetry-allowed spin-triplet states which dominate low-temperature photoluminescence.

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Exciton Fine Structure in Lead Chalcogenide Quantum Dots: Valley Mixing and Crucial Role of Intervalley Electron–Hole Exchange

2020

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“…Here we use notations for the irreducible representations of the point symmetry group T d consistent with those of ref . The oscillator strengths of optical transitions that distribute nonuniformly among the eight triplets are determined by numerical calculations in the framework of the empirical tight-binding model. , First, the electron and hole states are calculated using the nearest-neighbor sp 3 d 5 s* tight-binding approach with the parameters accurately fitted to reproduce ab initio many-body calculations of PbS band structure . We neglect the passivation of the surface, which only slightly changes the quantum confinement energies of the states near the band gap.…”

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confidence: 99%

Intrinsic Exciton Photophysics of PbS Quantum Dots Revealed by Low-Temperature Single Nanocrystal Spectroscopy

Kim

Krishnamurthy

et al. 2019

Nano Lett.

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With a tunable size-dependent photoluminescence (PL) over a wide infrared wavelength range, lead chalcogenide quantum dots (QDs) have attracted significant scientific and technological interest. Nevertheless, the investigation of intrinsic exciton photophysics at the single-QD level has remained a challenge. Herein, we present a comprehensive study of PL properties for the individual core/shell PbS/CdS QDs emissive near 1.0 eV. In contrast to the sub-meV spectral line widths observed for II/VI QDs, PbS/CdS QDs are predicted to possess broad homogeneous line widths. Performing spectroscopy at cryogenic (4 K) temperatures, we provide direct evidence confirming theoretical predictions, showing that intrinsic line widths for PbS/CdS QDs are in the range of 8–25 meV, with an average of 16.4 meV. In addition, low-temperature, single-QD spectroscopy reveals a broad low-energy side emission attributable to optical as well as localized acoustic phonon-assisted transitions. By tracking single QDs from 4 to 250 K, we were able to probe temperature-dependent evolutions of emission energy, line width, and line shape. Finally, polarization-resolved PL imaging showed that PbS/CdS QDs are characterized by a 3D emission dipole, in contrast with the 2D dipole observed for CdSe QDs.

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“…Among many atomistic methods we chose the empirical tight binding approach in nearest neighbour approximation, proved to be useful for many cubic semiconductors [30]. The use of the recent parametrization [26], which accurately reproduces experimental effective masses in the L valleys and show good agreement with experiment [31], allow us to study a wide range of NW sizes and shapes. We neglect the surface passivation, as the surface states in highly ionic crystals lie far outside the band gap [22] and there is no need to saturate the dangling bonds [25].…”

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Shape effect on the valley splitting in lead selenide nanowires

Avdeev

2019

Phys. Rev. B

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We study the cross-section shape and size effects on the valley splitting in PbSe nanowires within the framework of empirical sp 3 d 5 s * tight-binding method. We consider ideallized prismatic nanowires, grown along [110], with the cross-section shape varying from rectangular (terminated by {001} and {110} facets) to rhombic (terminated mostly by {111} facets). The valley splitting energies have the maximal value (up to hundreds meV) in rectangular nanowires, while in rhombic ones they are almost absent. The shape dependence is shown to be similar for a wide range cross-section sizes and different point symmetries of nanowires. arXiv:1901.09773v1 [cond-mat.mes-hall]

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Role of Valley Anisotropy in Optical Absorption of Monodisperse PbS Nanocrystals

Cited by 7 publications

References 52 publications

Exciton Fine Structure in Lead Chalcogenide Quantum Dots: Valley Mixing and Crucial Role of Intervalley Electron–Hole Exchange

Exciton Fine Structure in Lead Chalcogenide Quantum Dots: Valley Mixing and Crucial Role of Intervalley Electron–Hole Exchange

Intrinsic Exciton Photophysics of PbS Quantum Dots Revealed by Low-Temperature Single Nanocrystal Spectroscopy

Shape effect on the valley splitting in lead selenide nanowires

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