Projects funded by the NCN
Artificial molecules in nanowires: atomistic calculations of excitonic spectra and machine learning
2018/31/B/ST3/01415
Keywords:
quantum dots nanowires atomistic calculations machine learning
Descriptors:
- ST3_13: Structure and dynamics of disordered systems, soft matter, etc.
- ST3_12: Molecular electronics
- ST3_5: Physical properties of semiconductors and insulators
Panel:
ST3 - Condensed matter physics: structure, electronic properties, fluids, nanosciences, biological physics
Host institution :
Uniwersytet Mikołaja Kopernika w Toruniu, Wydział Fizyki, Astronomii i Informatyki Stosowanej
woj. kujawsko-pomorskie
Principal investigator (from the host institution):
Number of co-investigators in the project: 3
Call: OPUS 16 - announced on 2018-09-14
Amount awarded: 693 000 PLN
Project start date (Y-m-d): 2019-07-09
Project end date (Y-m-d): 2024-07-08
Project duration:: 36 months (the same as in the proposal)
Project status: Pending project
Project description
Download the project description in a pdf file
Note - project descriptions were prepared by the authors of the applications themselves and placed in the system in an unchanged form.
Information in the final report
- Publication in academic press/journals (8)
- Electric-field control of exciton fine structure in alloyed nanowire quantum dot moleculesAuthors:Michał Świderski, Michał ZielińskiAcademic press:Physical Review B (rok: 2021, tom: 104, strony: 195411-195428), Wydawca: American Physical SocietyStatus:PublishedDOI:10.1103/PhysRevB.104.195411 - link to the publication
- Fine structure of dark and bright excitons in vertical electric fields: Atomistic theory of alloyed self-assembled InGaAs quantum dotsAuthors:Michał ZielińskiAcademic press:PHYSICAL REVIEW B (rok: 2020, tom: 102, strony: 245423), Wydawca: American Physical SocietyStatus:PublishedDOI:10.1103/PhysRevB.102.245423 - link to the publication
- Vanishing fine structure splitting in highly asymmetric InAs/InP quantum dots without wetting layerAuthors:Michał ZielińskiAcademic press:Scientific Reports (rok: 2020, tom: 10, strony: 13542), Wydawca: Nature ResearchStatus:PublishedDOI:10.1038/s41598-020-70156-1 - link to the publication
- Dark-bright excitons mixing in alloyed InGaAs self-assembled quantum dotsAuthors:Michał ZielińskiAcademic press:Physical Review B (rok: 2021, tom: 103, strony: 155418-155433), Wydawca: American Physical SocietyStatus:PublishedDOI:10.1103/PhysRevB.103.155418 - link to the publication
- Excitonic complexes in InAs/InP nanowire quantum dotsAuthors:Michał ZielińskiAcademic press:PHYSICAL REVIEW B (rok: 2020, tom: 101, strony: 195302), Wydawca: American Physical SocietyStatus:PublishedDOI:10.1103/PhysRevB.101.195302 - link to the publication
- Crystal feld splitting and spontaneous polarization in InP crystal phase quantum dotsAuthors:Martyna Patera, Michał ZielińskiAcademic press:Scientific Reports (rok: 2022, tom: 12, strony: 15561), Wydawca: Springer NatureStatus:PublishedDOI:https://www.nature.com/articles/s41598-022-19076-w - link to the publication
- Electron g‑factor in nanostructures: continuum media and atomistic approachAuthors:Krzysztof Gawarecki, Michał ZielińskiAcademic press:scientific reports (rok: 2020, tom: 10, strony: 22001), Wydawca: nature researchStatus:PublishedDOI:10.1038/s41598-020-79133-0 - link to the publication
- Antibonding ground states in crystal phase quantum dotsAuthors:Martyna Patera, Michał ZielińskiAcademic press:PHYSICAL REVIEW B (rok: 2022, tom: 106, strony: L041405), Wydawca: American Physical SocietyStatus:PublishedDOI:10.1103/PhysRevB.106.L041405 - link to the publication