Phononic Crystals for Heat and Sound Nanodevices (Q84192): Difference between revisions
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(Removed claim: financed by (P890): Directorate-General for Regional and Urban Policy (Q8361), Removing unnecessary financed by statement) |
(Changed label, description and/or aliases in fr: translated_label) |
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| label / fr | label / fr | ||
Cristaux phononiques pour la chaleur et le son Nanodevices | |||
Revision as of 16:23, 30 November 2021
Project Q84192 in Poland
| Language | Label | Description | Also known as |
|---|---|---|---|
| English | Phononic Crystals for Heat and Sound Nanodevices |
Project Q84192 in Poland |
Statements
687,790.0 zloty
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687,790.0 zloty
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100.0 percent
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1 January 2017
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31 December 2018
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UNIWERSTET IM. ADAMA MICKIEWICZA W POZNANIU
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Energy transport phenomena such as sound and heat flow are fundamental issues of basic research as well as a key problem of many everyday technological applications. The need for high frequency phonons management arises from new challenges brought by the quest of continuous improvement and miniaturisation of nanodevices. Therefore, novel easily manageable, cost efficient and environment friendly functional material structures for sound and heat control are highly attractive for numerous applications in nanotechnology, telecommunication and energy harvesting. The project aims to develop new materials, establish comprehensive understanding and ability to measure and control high frequency phonons at the nanoscale propagating in silicon phononic crystal membranes. The project is built on three pillars: nanofabrication based on the well-developed technology of silicon, investigation of hypersonic phonon propagation and thermal transport by means of Brillouin and Raman spectroscopy. (Polish)
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Energy transport phenomena such as sound and heat flow are fundamental issues of basic research as well as a key problem of many everyday technological applications. The need for high frequency phonons management arises from new challenges brought by the quest of continuous improvement and miniaturisation of nanodevices. Thus, novel easily manageable, cost efficient and environment friendly functional material structures for sound and heat control are highly attractive for numerous applications in nanotechnology, telecommunication and energy harvesting. The project aims to develop new materials, establish comprehensive understanding and ability to measure and control high frequency phonons at the nanoscale Propagating in silicon phononic crystal membranes. The project is built on three pillars: nanofabrication based on the well-developed technology of silicon, investigation of hypersonic phonon Propagation and thermal transport by means of Brillouin and Raman spectroscopy. (English)
14 October 2020
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Identifiers
POIR.04.04.00-00-1E1A/16
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