Heimat: High enhancement and Interference of Molecular Transitions (Nanoantennas for higher-multipole light-matter coupling) (Q84167): Difference between revisions

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Heimat: High enhancement and Interference of Molecular Transitions (Nanoantennas for higher-multipole light-matter coupling)

Revision as of 12:29, 14 October 2020

Project in Poland financed by DG Regio
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English
Heimat: High enhancement and Interference of Molecular Transitions (Nanoantennas for higher-multipole light-matter coupling)
Project in Poland financed by DG Regio

    Statements

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    468,842.0 zloty
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    112,522.08 Euro
    13 January 2020
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    468,842.0 zloty
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    112,522.08 Euro
    13 January 2020
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    100.0 percent
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    1 October 2016
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    30 November 2018
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    UNIWERSYTET MIKOŁAJA KOPERNIKA W TORUNIU
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    Due to their extraordinary ability to tailor spatial and spectral distribution of light, nanoantennas are perfect candidate platforms to enhance in a controllable manner interactions between matter and light. The aim of the project is to exploit nanoantennas to drastically increase the probability of - typically very weak - higher multipole coupling of light to molecules, or on the contrary - to attenuate highly probable events. For this purpose we plan to combine methods of quantum chemistry, nanoplasmonics and molecular physics. In perspective, the project may enable a development of novel means of quantum state control of matter and generation of exotic states of light, with applications in atomic and molecular spectroscopy, quantum optics and information technologies. (Polish)
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    Due to their extraordinary ability to tailor spatial and spectral distribution of light, nanoantennas are perfect candidate platforms to enhance in a controllable manner interactions between matter and light. The aim of the project is to exploit nanoantennas to drastically increase the probability of – typically very weak – higher multipole coupling of light to molecules, or on the contrary – to attenuate highly probable events. For this purpose we plan to combine methods of quantum chemistry, nanoplasmonics and molecular physics. In perspective, the project may enable a development of novel means of quantum state control of matter and generation of exotic states of light, with applications in atomic and molecular spectroscopy, quantum optics and information technologies. (English)
    14 October 2020
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    Identifiers

    POIR.04.04.00-00-1B2E/16
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