Q3056491 (Q3056491): Difference between revisions
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(Created claim: summary (P836): The proposed industrial research project will be implemented by the Institute of Solids Physics of the University of Latvia (LU CFI) and SIA Sidrabe Vacuum. This interdisciplinary project includes research activities in physics (1.3) and chemistry (1.4), electro-engineering, electronics, information and communication technologies (2.2), material sciences (2.5) and nanotechnologies (2.10), according to the Frascati Manual of the Organisation for...) |
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The proposed industrial research project will be implemented by the Institute of Solids Physics of the University of Latvia (LU CFI) and SIA Sidrabe Vacuum. This interdisciplinary project includes research activities in physics (1.3) and chemistry (1.4), electro-engineering, electronics, information and communication technologies (2.2), material sciences (2.5) and nanotechnologies (2.10), according to the Frascati Manual of the Organisation for Economic Cooperation and Development (OECD). Such a detector has a wide-ranging application linked to the recording of mechanical voltage abnormalities, such as dynamic voltage detection and monitoring to diagnose possible structural damages using a structural monitoring process. Thin layer coating is a highly economical method in terms of materials, in which a thin layer of material can be deposited directly on the material of interest or on polymer sheet or monitorable details.In order to successfully achieve the goal, the project has several tasks:(1) develop ML material synthesis technology (ZnS: MN and SrAl2O4: EU, Dy, Cr) and magnetron foaming methods of the desired material;(2) to investigate the ratios of mechanical voltage to fluorescent intensity in materials and to choose the optimal material for determination of mechanical voltage;(3) to investigate the main components of the fluorescent mechanism, the origin, structure and importance of the internal and impurity-related defects of the material in order to improve the properties of ML;(4) to create ML thin layers with the required mechanical voltage and luminescence ratios; (5) develop the main design of the optical mechanical voltage on the basic parameters of the TRL. Additional project results will include 1 patent applications and 5 scientific articles in peer-reviewed journals.The project is directly related to the RIS3 specialisation field Smart Materials, Technologies and Engineering Systems and supports sectors of future growth where high value-added products and services exist or may appear. The project results are expected to be used according to NACE C26.51 and NACE C33.11 and NACE F43.3 codes.The project will be implemented by a qualified scientific team (4.35 PLE), including 3 students (1,15 PLE, one of which will be newly created (0.35 PLE)) and 3 young scientists (1.5 FLE). The project involves non-economic activities and combines fundamental and industrial research. The total costs of the project are EUR 535856.88 (59.93 % for LU CFI and 40.07 % for Sidrabe Vacuum), ERDF contribution EUR 440956.63 (82.29 %), State budget covers EUR 54710.98 (10.21 %) and EUR 40189.27 (7.5 %) is co-funding of project implementers. The duration of the project is 30 months. (English) | |||||||||||||||
| Property / summary: The proposed industrial research project will be implemented by the Institute of Solids Physics of the University of Latvia (LU CFI) and SIA Sidrabe Vacuum. This interdisciplinary project includes research activities in physics (1.3) and chemistry (1.4), electro-engineering, electronics, information and communication technologies (2.2), material sciences (2.5) and nanotechnologies (2.10), according to the Frascati Manual of the Organisation for Economic Cooperation and Development (OECD). Such a detector has a wide-ranging application linked to the recording of mechanical voltage abnormalities, such as dynamic voltage detection and monitoring to diagnose possible structural damages using a structural monitoring process. Thin layer coating is a highly economical method in terms of materials, in which a thin layer of material can be deposited directly on the material of interest or on polymer sheet or monitorable details.In order to successfully achieve the goal, the project has several tasks:(1) develop ML material synthesis technology (ZnS: MN and SrAl2O4: EU, Dy, Cr) and magnetron foaming methods of the desired material;(2) to investigate the ratios of mechanical voltage to fluorescent intensity in materials and to choose the optimal material for determination of mechanical voltage;(3) to investigate the main components of the fluorescent mechanism, the origin, structure and importance of the internal and impurity-related defects of the material in order to improve the properties of ML;(4) to create ML thin layers with the required mechanical voltage and luminescence ratios; (5) develop the main design of the optical mechanical voltage on the basic parameters of the TRL. Additional project results will include 1 patent applications and 5 scientific articles in peer-reviewed journals.The project is directly related to the RIS3 specialisation field Smart Materials, Technologies and Engineering Systems and supports sectors of future growth where high value-added products and services exist or may appear. The project results are expected to be used according to NACE C26.51 and NACE C33.11 and NACE F43.3 codes.The project will be implemented by a qualified scientific team (4.35 PLE), including 3 students (1,15 PLE, one of which will be newly created (0.35 PLE)) and 3 young scientists (1.5 FLE). The project involves non-economic activities and combines fundamental and industrial research. The total costs of the project are EUR 535856.88 (59.93 % for LU CFI and 40.07 % for Sidrabe Vacuum), ERDF contribution EUR 440956.63 (82.29 %), State budget covers EUR 54710.98 (10.21 %) and EUR 40189.27 (7.5 %) is co-funding of project implementers. The duration of the project is 30 months. (English) / rank | |||||||||||||||
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| Property / summary: The proposed industrial research project will be implemented by the Institute of Solids Physics of the University of Latvia (LU CFI) and SIA Sidrabe Vacuum. This interdisciplinary project includes research activities in physics (1.3) and chemistry (1.4), electro-engineering, electronics, information and communication technologies (2.2), material sciences (2.5) and nanotechnologies (2.10), according to the Frascati Manual of the Organisation for Economic Cooperation and Development (OECD). Such a detector has a wide-ranging application linked to the recording of mechanical voltage abnormalities, such as dynamic voltage detection and monitoring to diagnose possible structural damages using a structural monitoring process. Thin layer coating is a highly economical method in terms of materials, in which a thin layer of material can be deposited directly on the material of interest or on polymer sheet or monitorable details.In order to successfully achieve the goal, the project has several tasks:(1) develop ML material synthesis technology (ZnS: MN and SrAl2O4: EU, Dy, Cr) and magnetron foaming methods of the desired material;(2) to investigate the ratios of mechanical voltage to fluorescent intensity in materials and to choose the optimal material for determination of mechanical voltage;(3) to investigate the main components of the fluorescent mechanism, the origin, structure and importance of the internal and impurity-related defects of the material in order to improve the properties of ML;(4) to create ML thin layers with the required mechanical voltage and luminescence ratios; (5) develop the main design of the optical mechanical voltage on the basic parameters of the TRL. Additional project results will include 1 patent applications and 5 scientific articles in peer-reviewed journals.The project is directly related to the RIS3 specialisation field Smart Materials, Technologies and Engineering Systems and supports sectors of future growth where high value-added products and services exist or may appear. The project results are expected to be used according to NACE C26.51 and NACE C33.11 and NACE F43.3 codes.The project will be implemented by a qualified scientific team (4.35 PLE), including 3 students (1,15 PLE, one of which will be newly created (0.35 PLE)) and 3 young scientists (1.5 FLE). The project involves non-economic activities and combines fundamental and industrial research. The total costs of the project are EUR 535856.88 (59.93 % for LU CFI and 40.07 % for Sidrabe Vacuum), ERDF contribution EUR 440956.63 (82.29 %), State budget covers EUR 54710.98 (10.21 %) and EUR 40189.27 (7.5 %) is co-funding of project implementers. The duration of the project is 30 months. (English) / qualifier | |||||||||||||||
point in time: 15 July 2021
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Revision as of 12:35, 15 July 2021
Project Q3056491 in Latvia
| Language | Label | Description | Also known as |
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| English | No label defined |
Project Q3056491 in Latvia |
Statements
440,956.62 Euro
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535,856.88 Euro
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1 April 2021
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30 September 2023
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Atvasināta publiska persona LATVIJAS UNIVERSITĀTES CIETVIELU FIZIKAS INSTITŪTS
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56°54'57.24"N, 24°9'56.95"E
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56°55'38.06"N, 24°11'16.94"E
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Piedāvāto industriālās pētniecības projektu īstenos Latvijas Universitātes Cietvielu fizikas institūts (LU CFI) un SIA Sidrabe Vacuum. Šis starpdisciplinārais projekts ietver pētniecības aktivitātes fizikas (1.3.) un ķīmijas (1.4.) zinātnēs, elektroinženierijas, elektronikas, informācijas un komunikāciju tehnoloģijas (2.2.), materiālu zinātnes (2.5.) un nanotehnoloģijas (2.10.), saskaņā ar Ekonomiskās sadarbības un attīstības organizācijas (OECD) Frascati rokasgrāmatu.Projekta galvenais mērķis ir mehanoluminiscentu (ML) plāno kārtiņu izstrāde optiskiem reāla laika mehāniskā sprieguma detektoriem. Šādam detektoram ir plaša pielietojamība, kas sasitīta ar mehāniskā sprieguma anomāliju reģistrēšanu, piemēram, dinamisku sprieguma detektēšana un monitorēšana, lai diagnosticētu iespējamos konstrukciju bojājumus, izmantojot strukturālās uzraudzības procesu. Plāno kārtiņu pārklājums ir materiālu ziņā ļoti ekonomiska metode, kurā plānu materiāla kārtu var nogulsnēt tieši uz interesējošā materiāla vai arī uz polimēra loksnes vai monitorējamās detaļas.Lai veiksmīgi sasniegtu mērķi, projektā ir vairāki uzdevumi:(1) izstrādāt ML materiālu sintēzes tehnoloģija (ZnS: Mn un SrAl2O4: Eu, Dy, Cr) un vēlamā materiāla magnetronu uzputināšanas metodes;(2) izpētīt mehāniskā sprieguma un luminiscences intensitātes attiecības materiālos un izvēlēties optimālo materiālu mehāniskā sprieguma noteikšanai;(3) izpētīt galvenās luminiscences mehānisma detaļas, materiāla iekšējo un ar piemaisījumiem saistīto defektu izcelsmi, struktūru un nozīmi, lai uzlabotu ML īpašības;(4) izveidot ML plānās kārtiņas ar nepieciešamajām mehāniskā sprieguma un luminiscences attiecībām;(5) izstrādāt optisko mehāniskā sprieguma detektoru.Projekta galvenais rezultāts ir ML materiāla (paredzamā TRL 6) laboratorijas tehnoloģijas izstrāde ar uzlabotiem parametriem un uz izstrādātā materiāla pamata izveidots optisks reāla laika mehāniskā sprieguma detektors. Papildu projekta rezultāti būs 1 patenta pieteikums un 5 zinātniskie raksti augsta ranga recenzētos žurnālos.Projekts ir tieši saistīts ar RIS3 specializācijas jomu “Viedie materiāli, tehnoloģijas un inženiertehniskās sistēmas” un atbalsta turpmākās izaugsmes nozares, kurās pastāv vai varētu parādīties produkti un pakalpojumi ar augstu pievienoto vērtību. Projekta īstenošanas rezultāta izmantošana paredzama atbilstoši NACE C26.51 kodam, ka arī NACE C33.11 un NACE F43.3 kodiem.Projektu īstenos kvalificēta zinātniskā komanda (4.35 PLE), tai skaitā 3 studenti (1,15 PLE, no kā viena pozīcija būs jaunizveidota (0.35 PLE)) un 3 jaunie zinātnieki (1.5 PLE). Projekts ir saistīts ar neekonomisku darbību un apvieno fundamentālo un rūpniecisko izpēti. Projekta kopējās izmaksas ir 535 856.88 EUR (59,93% LU CFI un 40,07% Sidrabe Vacuum), ERAF ieguldījums 440956.63 EUR (82,29%), Valsts budžets sedz 54710.98 EUR (10,21%) un 40189,27 EUR (7,5%) ir projekta īstenotāju līdzfinansējums. Projekta ilgums ir 30 mēneši. (Latvian)
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The proposed industrial research project will be implemented by the Institute of Solids Physics of the University of Latvia (LU CFI) and SIA Sidrabe Vacuum. This interdisciplinary project includes research activities in physics (1.3) and chemistry (1.4), electro-engineering, electronics, information and communication technologies (2.2), material sciences (2.5) and nanotechnologies (2.10), according to the Frascati Manual of the Organisation for Economic Cooperation and Development (OECD). Such a detector has a wide-ranging application linked to the recording of mechanical voltage abnormalities, such as dynamic voltage detection and monitoring to diagnose possible structural damages using a structural monitoring process. Thin layer coating is a highly economical method in terms of materials, in which a thin layer of material can be deposited directly on the material of interest or on polymer sheet or monitorable details.In order to successfully achieve the goal, the project has several tasks:(1) develop ML material synthesis technology (ZnS: MN and SrAl2O4: EU, Dy, Cr) and magnetron foaming methods of the desired material;(2) to investigate the ratios of mechanical voltage to fluorescent intensity in materials and to choose the optimal material for determination of mechanical voltage;(3) to investigate the main components of the fluorescent mechanism, the origin, structure and importance of the internal and impurity-related defects of the material in order to improve the properties of ML;(4) to create ML thin layers with the required mechanical voltage and luminescence ratios; (5) develop the main design of the optical mechanical voltage on the basic parameters of the TRL. Additional project results will include 1 patent applications and 5 scientific articles in peer-reviewed journals.The project is directly related to the RIS3 specialisation field Smart Materials, Technologies and Engineering Systems and supports sectors of future growth where high value-added products and services exist or may appear. The project results are expected to be used according to NACE C26.51 and NACE C33.11 and NACE F43.3 codes.The project will be implemented by a qualified scientific team (4.35 PLE), including 3 students (1,15 PLE, one of which will be newly created (0.35 PLE)) and 3 young scientists (1.5 FLE). The project involves non-economic activities and combines fundamental and industrial research. The total costs of the project are EUR 535856.88 (59.93 % for LU CFI and 40.07 % for Sidrabe Vacuum), ERDF contribution EUR 440956.63 (82.29 %), State budget covers EUR 54710.98 (10.21 %) and EUR 40189.27 (7.5 %) is co-funding of project implementers. The duration of the project is 30 months. (English)
15 July 2021
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Ķengaraga iela 8, Rīga, LV-1063
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Krustpils iela 17, Rīga, LV-1073
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Identifiers
1.1.1.1/20/A/138
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