Coupled Colloidal Quantum Dot Molecules

Koley, Somnath; Cui, Jiabin; Panfil, Yossef E.; Banin, Uri

doi:10.1021/acs.accounts.0c00691

Cited by 49 publications

(51 citation statements)

References 54 publications

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“…Although the QDs optical waveguide can be considered a coupled system of multiple quantum dots (see for example 31 ), the theoretical model was implemented for a single QD.…”

Section: Discussionmentioning

confidence: 99%

Sensing applied pressure by triggering electronic quantum many-body excitations in an optical waveguide

Chiara¹,

Lee²,

Weber³

et al. 2021

Preprint

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Recently, nanomaterials are arousing increasing interest and a wide variety of optoelectronic devices have been developed, such as light-emitting diodes, solar cells, and photodetectors. However, the study of the light emission properties of quantum dots under pressure is still limited. By using a joint theoretical and experimental approach, we developed a polymer waveguide doped with CdSe quantum dots for pressure sensing.Absorption and re-emission effects of the quantum dots are affected by the pressure applied on the waveguide. Specifically, since both amplitude and wavelength are modulated, not only the pressure can be detected, but also its location along the waveguide.The calibration results demonstrate the feasibility of the proposed force sensor design.Theoretical model and simulations further validate the presented sensing principle.The proposed prototype benefits from the main advantages of optical sensors, such as their predisposition to miniaturization, small cable sizes and weights, immunity to

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“…Although the QDs optical waveguide can be considered a coupled system of multiple quantum dots (see for example 31 ), the theoretical model was implemented for a single QD.…”

Section: Discussionmentioning

confidence: 99%

Sensing applied pressure by triggering electronic quantum many-body excitations in an optical waveguide

Chiara¹,

Lee²,

Weber³

et al. 2021

Preprint

View full text Add to dashboard Cite

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“…In particular, there should be a size at which the AR lifetimes become independent of the volume of the QD (perhaps above the biexcitonic radius), where such exciton-exciton correlation becomes important. For example, recent advances in synthesizing single NCs that have multiple, spatially separated excitonic sites 92,178,179 may require the inclusion of all possible quasiparticlequasiparticle correlations to accurately model the decay of biexcitonic states.…”

Section: Auger Recombinationmentioning

confidence: 99%

Simulations of nonradiative processes in semiconductor nanocrystals

Jasrasaria,

Weinberg,

Philbin

et al. 2022

Preprint

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The description of carrier dynamics in spatially confined semiconductor nanocrystals (NCs), which have enhanced electron-hole and exciton-phonon interactions, is a great challenge for modern computational science. These NCs typically contain thousands of atoms and tens of thousands of valence electrons with a discrete spectra at low excitation energies, similar to atoms and molecules, that converges to the continuum bulk limit at higher energies. Computational methods developed for molecules are limited to very small nanoclusters, and methods for bulk systems with periodic boundary conditions are not suitable due to the lack of translational symmetry in NCs. This perspective focuses on our recent efforts in developing a unified atomistic model based on the semiempirical pseudopotential approach, which is parametrized by first-principle calculations and validated against experimental measurements, to describe two of the main nonradiative relaxation processes of quantum confined excitons: exciton cooling and Auger recombination. We focus on the description of both electron-hole and exciton-phonon interactions in our approach and discuss the role of size, shape, and interfacing on the electronic properties and dynamics for II-VI and III-V semiconductor NCs.

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“…Bonding and antibonding of colloids could lead to higher and lower enthalpies. Two recent examples of research in this field were given [ 62 , 63 ]. The nature built these new superstructures in all overheated melts by homogeneous nucleation.…”

Section: Perspectives: Mpemba Effect and Bonding-antibonding Of Superatomsmentioning

confidence: 99%

Building and Breaking Bonds by Homogenous Nucleation in Glass-Forming Melts Leading to Transitions in Three Liquid States

Tournier

Ojovan

2021

Materials

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The thermal history of melts leads to three liquid states above the melting temperatures Tm containing clusters—bound colloids with two opposite values of enthalpy +Δεlg × ΔHm and −Δεlg × ΔHm and zero. All colloid bonds disconnect at Tn+ > Tm and give rise in congruent materials, through a first-order transition at TLL = Tn+, forming a homogeneous liquid, containing tiny superatoms, built by short-range order. In non-congruent materials, (Tn+) and (TLL) are separated, Tn+ being the temperature of a second order and TLL the temperature of a first-order phase transition. (Tn+) and (TLL) are predicted from the knowledge of solidus and liquidus temperatures using non-classical homogenous nucleation. The first-order transition at TLL gives rise by cooling to a new liquid state containing colloids. Each colloid is a superatom, melted by homogeneous disintegration of nuclei instead of surface melting, and with a Gibbs free energy equal to that of a liquid droplet containing the same magic atom number. Internal and external bond number of colloids increases at Tn+ or from Tn+ to Tg. These liquid enthalpies reveal the natural presence of colloid–colloid bonding and antibonding in glass-forming melts. The Mpemba effect and its inverse exist in all melts and is due to the presence of these three liquid states.

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Coupled Colloidal Quantum Dot Molecules

Cited by 49 publications

References 54 publications

Sensing applied pressure by triggering electronic quantum many-body excitations in an optical waveguide

Sensing applied pressure by triggering electronic quantum many-body excitations in an optical waveguide

Simulations of nonradiative processes in semiconductor nanocrystals

Building and Breaking Bonds by Homogenous Nucleation in Glass-Forming Melts Leading to Transitions in Three Liquid States

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