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Romania
Citizenship:
Ph.D. degree award:
Luminita Eugenia
Wagner
-
Institutul National de Cercetare-Dezvoltare pentru Chimie si Petrochimie - ICECHIM Bucuresti
Researcher | Scientific reviewer
Personal public profile link.
Curriculum Vitae (06/08/2020)
Expertise & keywords
organic dyes
Pigments
Hybrid materials
Fine organic chemistry
smart textiles
organic intermediates
Organic synthesis
paints
Functional coatings
thermochromic materials
Projects
Publications & Patents
Entrepreneurship
Reviewer section
Contingency of CBRN hazards and improvement of national security resources
Call name:
P 1 - SP 1.2 - Proiecte complexe realizate in consorții CDI
PN-III-P1-1.2-PCCDI-2017-0395
2018
-
2021
Role in this project:
Key expert
Coordinating institution:
Institutul National de Cercetare-Dezvoltare pentru Chimie si Petrochimie - ICECHIM Bucuresti
Project partners:
Institutul National de Cercetare-Dezvoltare pentru Chimie si Petrochimie - ICECHIM Bucuresti (RO); Ministerul Apararii Nationale prin Centrul de Cercetare Stiintifica pentru Aparare CBRN si Ecologie (RO); Academia Tehnica Militara (RO); UNIVERSITATEA POLITEHNICA DIN BUCURESTI (RO); CENTRUL DE CHIMIE ORGANICA AL ACADEMIEI ROMANE "C.D.NENITESCU" (RO); Centrul de Cercetare Stiintifica pentru Fortele Navale Constanta (RO)
Affiliation:
Institutul National de Cercetare-Dezvoltare pentru Chimie si Petrochimie - ICECHIM Bucuresti (RO)
Project website:
http://icechim-rezultate.ro/proiect.php?id=40&lang=ro si http://icechim-rezultate.ro/proiect.php?id=33&lang=en
Abstract:
SECURE-NET is a Complex Project designed to improve the institutional performance of the Consortium Research Partners (Institutions with Re-launch Capabilities in the Field of National Security). In this respect, the Complex Project proposes five research themes corresponding to the five Component Projects, which aim at: (i) contingency of chemical, biochemical, radiological and nuclear (CBRN) hazards by developing new decontamination products and by developing specific sensors for detecting chemical agents of combat, and (ii) improving national security by developing shock-absorbing composites, solid rocket fuel and multispectral camouflages. This Complex Project brings together institutions with tradition, having either similar specialisation or complementary specialisation, to strengthen scientific and technical competences in the field of National Security and Advanced Materials for military applications. The Project Consortium has a gender-balanced staff and promotes the involvement of a large number of teachers, researchers, doctoral students and post-doctoral students in all activities proposed by the Common Agenda. In addition, the project facilitates the transfer of scientific knowledge between participating institutions as well as the recruitment and training of new staff. The multitude of results generated by the implementation of SECURE-NET express the potential for significant influence upon (i) the scientific community through communication and dissemination of results (as a short- and medium-term impact), and (ii) the public and private environment by promoting new research services and new transferable products / technologies to the external environment of the Consortium, particularly to the national defence industry (as a long-term impact).
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New generation of photocatalytic self-cleaning systems for functionalization of technical textiles and architectural coatings
Call name:
Joint Applied Research Projects - PCCA 2013 - call
PN-II-PT-PCCA-2013-4-0864
2014
-
2017
Role in this project:
Key expert
Coordinating institution:
Institutul National de Cercetare-Dezvoltare pentru Chimie si Petrochimie - ICECHIM Bucuresti
Project partners:
Institutul National de Cercetare-Dezvoltare pentru Chimie si Petrochimie - ICECHIM Bucuresti (RO); INSTITUTUL DE CHIMIE FIZICA - ILIE MURGULESCU (RO); INSTITUTUL NATIONAL DE CERCETARE - DEZVOLTARE PENTRU FIZICA MATERIALELOR BUCURESTI RA (RO); INSTITUTUL NATIONAL DE CERCETARE DEZVOLTARE PENTRU FIZICA LASERILOR, PLASMEI SI RADIATIEI - INFLPR RA (RO); CHIMCOLOR S.R.L. (RO)
Affiliation:
Institutul National de Cercetare-Dezvoltare pentru Chimie si Petrochimie - ICECHIM Bucuresti (RO)
Project website:
http://www.cleanphotocoat.roit.ro
Abstract:
Pollution and its side effects on health, structural damage of materials, costs for maintenance, cleaning and replacement of damaged materials is one of the most important causes of severe human diseases and of great economic losses all over the world. The project is focused on the development of new photocatalytic coating materials for technical textiles and architectural finishing systems that can be used to decompose pollutants in the air and on the coated surfaces in order to maintain a clean and healthy environment and avoid economic loses. The objective of the project is to obtain stable, adherent, efficient and durable daylight photocatalytic self cleaning coatings for different types of substrates, such as flexible technical textiles and rigid construction structures. To accomplish the objective, issues that require skills in various fields are to be addressed, in view of: scientific research for designing new photocatalysts, innovation activity for the improvement of their efficiency by extending absorption in the visible range of the spectrum, and technological development in order to obtain photocatalytic coatings dedicated to a particular type of substrate. All these issues will be solved due to a multidisciplinary partnership formed of high rank specialists in materials physics, laser physics, physical-chemistry, polymer chemistry, dyestuffs chemistry, and chemistry of textile materials, constantly having in mind obtaining safety products and technologies and achieving economic advantages from the production stage up to the application by the end-users.The method used for the synthesis of semiconductor materials is a key factor that determines their efficiency, the main reason for developing comparative studies regarding the most important oxide type photocatalysts used in practice (TiO2 and ZnO) that could be obtained and doped by wet methods (hydrothermal,sol-gel) or by laser pyrolysis route. Investigations developed in the project comprise also sensitizing the photocatalysts at the surface or by obtaining composites in order to use more efficient visible light in the photocatalytic decomposition of pollutants. Thus, we aim to develop new and optimized photocatalytically materials exhibiting activity upon visible light with surface characteristics of improved performance and of the high chemical and physical stability, crucial for broader scale utilization of photocatalytic systems in commercial application. However, another important challenge will be to obtain film building materials containing photocatalysts specially designed for coating technical textiles or for architectural coatings. Technologies regarding photocatalytic coatings developed in the project present several barriers that can be lifted by carrying out this project. The photocatalytic coatings that will be obtained will be compatible with the substrates, protect them to self-degradation and maintain their initial physical-mechanical characteristics, presenting high photocatalytic efficiency in visible light and durability. The newly developed photocatalytic coatings during the project will decompose air pollutants and other contaminants in outdoor and indoor applications using sunlight or artificial light, especially after expanding widespread use of LEDs for interior or exterior lighting of buildings, tunnels, advertising materials, thus making possible an enhancement of the photocatalytic effect and thus providing significant benefits for the environment and human health. Photocatalytic materials obtained in project together with the development of technically applicable photocatalytic coating systems adaptable to different types of substrates will represent a step change in this field particularly regarding the economic viability of a range of potential processes.
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Thermosensitive energy saving systems with tailored solar reflecting/absorbing properties for construction structures
Call name:
Joint Applied Research Projects - PCCA-2011 call, Type 2
PN-II-PT-PCCA-2011-3.2-1391
2012
-
2016
Role in this project:
Project coordinator
Coordinating institution:
Institutul National de Cercetare-Dezvoltare pentru Chimie si Petrochimie - ICECHIM Bucuresti
Project partners:
Institutul National de Cercetare-Dezvoltare pentru Chimie si Petrochimie - ICECHIM Bucuresti (RO); UNIVERSITATEA POLITEHNICA DIN BUCURESTI (RO); CHIMCOLOR S.R.L. (RO)
Affiliation:
Institutul National de Cercetare-Dezvoltare pentru Chimie si Petrochimie - ICECHIM Bucuresti (RO)
Project website:
http://www.thermosolar.roit.ro
Abstract:
In principle thermochromic and thermotropic systems can function as energy saving systems. For high temperatures, during summertime thermochromic coatings have the ability to reflect solar energy, reducing the surface’s temperature; while in wintertime absorb solar energy, increasing the surface’s temperature as reversible color change takes place. Applied thus on external building surfaces, they have the potential for the reduction of heating and cooling loads, contributing to the reduction of urban temperatures, fight heat island and reduce air pollution.
Color-changing compounds have become increasingly important in recent years in the study and the production of thermochromic coatings that is coatings which respond thermally to their environment, changing reversibly their color from darker to lighter tones as temperature rises. The novelty comes from the use concomitant of thermotropic hydrogels which respond thermally by changing transparency from total transparent to translucent. Combining these features of termotropic hydrogels and thermochromic dyes we can obtain complex thermosensitive systems that respond to an increase in temperature by switching the color hypsochromically while accompanied by a change in transparency of the hydrogels.
During the project we intend to develop thermosensitive energy saving coatings that action on the entire Vis-NIR range and are most typically applied to roofs but additionally can also be applied to exterior and interior walls in much the same way. Thermosensitive coatings that will aim to obtain change reflectivity and color as a function of temperature, present enhanced weathering and durability and may be in any suitable formulation for application on roofs or walls such as water-based, oil-based, epoxy-based or acrylic-based formulations.
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FILE DESCRIPTION
DOCUMENT
List of research grants as project coordinator or partner team leader
Significant R&D projects for enterprises, as project manager
R&D activities in enterprises
Peer-review activity for international programs/projects
[T: 0.3725, O: 159]