Johanna Dehnel scite author profile

The full blossoming of quantum technologies requires the availability of easy-to-prepare materials where quantum coherences can be effectively initiated, controlled, and exploited, preferably at ambient conditions. Solid-state multilayers of colloidally grown quantum dots (QDs) are highly promising for this task because of the possibility of assembling networks of electronically coupled QDs through the modulation of sizes, inter-dot linkers, and distances. To usefully probe coherence in these materials, the dynamical characterization of their collective quantum mechanically coupled states is needed. Here, we explore by two-dimensional electronic spectroscopy the coherent dynamics of solid-state multilayers of electronically coupled colloidally grown CdSe QDs and complement it by detailed computations. The time evolution of a coherent superposition of states delocalized over more than one QD was captured at ambient conditions. We thus provide important evidence for inter-dot coherences in such solid-state materials, opening up new avenues for the effective application of these materials in quantum technologies.

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Spin-Exciton Delocalization Enhancement in Multilayer Chiral Linker/Quantum Dot Structures

Fridman

Dehnel

Yochelis

et al. 2019

J. Phys. Chem. Lett.

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The control of complex devices on the nanoscale is challenging. The development of nanoparticles, such as quantum dots, that serve as "artificial atoms" enables the manipulation of energy levels at the nanoscale. Using quantum dots and wet chemistry, multilayer structures with unique coupling properties can be realized. The coupling of such quantum dots is essential for several applications, such as parallel computing. Earlier work showed enhancement of the delocalization using covalent bonds and short linkers. Here, we demonstrate a way to achieve better coupling using helical chiral molecules that exhibit long spin-wave function delocalization. The delocalization is controlled by manipulation of the spin state using polarized light.

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Room Temperature Inter-Dot Coherent Dynamics in Multilayers Quantum Dot Materials

Collini

Gattuso²,

Kolodny³

et al. 2020

Preprint

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<div><div><div><p>The full blossoming of quantum technologies requires the availability of easy-to-prepare materials where quantum coherences can be effectively initiated, controlled and exploited, preferably at ambient conditions. Solid-state multilayers of colloidally grown quantum dots (QDs) are highly promising for this task because of the possibility of assembling networks of electronically coupled QDs through the modulation of sizes, inter-dot linkers and distances. To usefully probe coherence in these materials, the dynamical characterization of their collective quantum mechanically coupled states is needed. Here we explore by 2D electronic spectroscopy the coherent dynamics of solid-state multilayers of electronically coupled colloidally grown CdSe QDs and complement it by detailed computations. The time evolution of a coherent superposition of states delocalized over more than one QD was captured at ambient conditions. We thus provide important evidence for inter-dot coherences in such solid-state materials, opening up the effective exploitation of these materials towards quantum technologies.</p></div></div></div>

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Room Temperature Inter-Dot Coherent Dynamics in Multilayers Quantum Dot Materials

Collini

Gattuso²,

Kolodny³

et al. 2020

Preprint

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Johanna Dehnel

Room-Temperature Inter-Dot Coherent Dynamics in Multilayer Quantum Dot Materials

Spin-Exciton Delocalization Enhancement in Multilayer Chiral Linker/Quantum Dot Structures

Room Temperature Inter-Dot Coherent Dynamics in Multilayers Quantum Dot Materials

Room Temperature Inter-Dot Coherent Dynamics in Multilayers Quantum Dot Materials

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