BrainMap

Oana Catalina Mocioiu

PhD.

- INSTITUTUL DE CHIMIE FIZICA - ILIE MURGULESCU

Researcher | Teaching staff | Scientific reviewer | Other

Web of Science ResearcherID: not public

Curriculum Vitae (27/03/2025)

Expertise & keywords

Development of a new generation of eco-friendly fire retardants for the treatment of cellulosic materials Call name: PNCDI IV, SP 5.7.1 - Proiect experimental demonstrativ
PN-IV-P7-7.1-PED-2024-0582 2025 - 2026

Role in this project:

Coordinating institution: INSTITUTUL DE CHIMIE FIZICA - ILIE MURGULESCU

Project partners: INSTITUTUL DE CHIMIE FIZICA - ILIE MURGULESCU (RO); SAFETY FIRE SOLUTION CONCEPT SRL (RO)

Affiliation:

Project website:

Abstract:

The project proposal ECOFIREMAT aims to design and investigate an innovative fire retardant that is halogen-free, non-toxic, and environmentally friendly in compliance with EU regulations. The objective of the project is to improve construction materials' fire safety by preventing ignition while also mitigating fungal growth and insect damage. The approach involves the application of a novel combination of a boron-silica complex and copper nanoparticles (CuNP) obtained by microwave-assisted method onto wood and textile materials through a spraying process. The CuNP prepared using Peppermint extract offers an eco-friendly and cost-effective solution due to the abundance of raw materials and the availability of residual peppermint waste from industrial practices in Romania. The boron-silica-CuNP assembly will be achieved through a sonication process, rendering a synergistic effect on the fire retardancy of the end product. The performance of the boron-silica-CuNP complex will be assessed by examining the flammability of the treated products upon direct contact with a flame, the minimum concentration of oxygen needed for combustion, total heat release, and smoke production. The ECOFIREMAT project has significant potential to enhance fire safety universally. It offers an innovative halogen-free solution with improved fire-resistant and antimicrobial properties, addressing the need to replace hazardous and toxic materials with sustainable safe, and compliant ones.

Functionalized mesoporous bioglass based 3D scaffolds for hard tissue regeneration Call name: P 2 - SP 2.1 - Proiect experimental - demonstrativ
PN-III-P2-2.1-PED-2019-0598 2020 - 2022

Role in this project:

Coordinating institution: INSTITUTUL DE CHIMIE FIZICA - ILIE MURGULESCU

Project partners: INSTITUTUL DE CHIMIE FIZICA - ILIE MURGULESCU (RO); INSTITUTUL NATIONAL DE CERCETARE DEZVOLTARE PENTRU STIINTE BIOLOGICE (RO)

Affiliation: INSTITUTUL DE CHIMIE FIZICA - ILIE MURGULESCU (RO)

Project website: http://www.icf.ro/pr_2019/BIOSCAFTIS/index.html

Abstract:

The project proposal “Functionalized mesoporous bioglass based 3D scaffolds for hard tissue regeneration“, aims to improve the well-being of people by treating them with new biomaterials. The objective of the project is to restore and improve the function of hard tissue by using functional bioactive scaffolds. These scaffolds will provide good mechanical properties in a suitable environment for tissue regeneration and repair. Sodium free mesoporous bioglasses (MBGs) doped with cerium will be used for scaffold manufacture using a combination of structure-directing agents and a polymer foam replication method. The BIOSCAFTIS project is based on our early results demonstrating that MBGs doped with cerium have good bioactivity and biocompatibility properties. In order to improve the growth and remodelling of bone tissue the surface of the scaffold will be functionalized with vitamin D3. The properties of the scaffolds e.g. bioactivity, mechanical strength, antimicrobial activity and drug delivery profile will be evaluated using adequate characterization techniques. The performance integration of 3D scaffolds to native tissues will be investigated using in vitro experimental models mimicking interaction with osteoblast cells. As a result of the research the project aims to disrupt the area of biomaterials by developing a new class of materials for medical applications.

NEW DIAGNOSIS AND TREATMENT TECHNOLOGIES FOR THE CONSERVATION AND REVITALIZATION OF ARCHAEOLOGICAL COMPONENTS FROM NATIONAL CULTURAL HERITAGE Call name: P 1 - SP 1.2 - Proiecte complexe realizate in consorții CDI
PN-III-P1-1.2-PCCDI-2017-0476 2018 - 2021

Role in this project:

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 OVIDIUS (RO); INSTITUTUL DE CHIMIE FIZICA - ILIE MURGULESCU (RO); UNIVERSITATEA "VALAHIA" TARGOVISTE (RO)

Affiliation: INSTITUTUL DE CHIMIE FIZICA - ILIE MURGULESCU (RO)

Project website: https://icechim.ro/project/tehnologii-noi-de-diagnoza-si-tratament-pentru-conservarea-si-revitalizarea-componentelor-arheologice-ale-patrimoniului-cultural-national-arheocons/

Abstract:

The cultural heritage, as a source of national historical and cultural authenticity, is subjected to deterioration, and for stopping it, some specific procedures are required: cleaning, replacement of old materials and application of new protective materials compatible with the original, and advanced monitoring with sustainability assessment. The consortium of the present project has a unique expertise in Romania, recognised in Europe, through the many published papers, essential projects in Romania (Basarabi Churches, Potlogi Palace, etc.), OSIM and EPO patents, technology transfer, nanomaterials in chemical and biological preservation for cultural heritage objects and objectives; the partner institutions complement each other on a regional basis in the working plan of the whole project.

The overall objective of the project is to develop new materials, new methods and technologies that obey the principles of authenticity, reversibility and value, with a strong impact on immobile cultural heritage objects (fresco, basreliefs and mosaic) and mobile (decorative artefacts from ceramics, glass, metal, bone, objects of art and archaeology). Specific objectives: Developing innovative technologies for protecting national cultural heritage, multidisciplinary cross-sectoral approach, encouraging young professionals as leaders in heritage preservation, exploitation of research results for new jobs, promoting heritage education, professional expertise among all factors involved in the patrimony protection system.

The project, with a high degree of innovation and originality, applies unique technologies in Romania based on new materials compatible with the original materials and develops new techniques practical applied to: Roman Mosaic and Hypogeum Tomb, Constanta, Adamclisi Museum (basreliefs), Constanta County, Corvin’s Castle (Fresca Loggia Mathia) and Archaeology Museum, Hunedoara.

Nanoconfinement in mesoporous Silica: Towards next generation Energy storage Materials Call name: P 1 - SP 1.1 - Proiecte de cercetare pentru stimularea tinerelor echipe independente
PN-III-P1-1.1-TE-2016-0520 2018 - 2020

Role in this project:

Coordinating institution: INSTITUTUL DE CHIMIE FIZICA - ILIE MURGULESCU

Project partners: INSTITUTUL DE CHIMIE FIZICA - ILIE MURGULESCU (RO)

Affiliation: INSTITUTUL DE CHIMIE FIZICA - ILIE MURGULESCU (RO)

Project website: http://www.icf.ro/pr_2018/Contract_95_2018_stema.pdf

Abstract:

The most promising “green” energy generation and storage technology which can economically replace coal and gas at scale is concentrated solar power (CSP). The STEMA project aims to increase the heat storage capacity for this technology with ~50% by developing new solid, shape-stabilized phase change materials through the nanoconfinement of molten salts (such as alkali nitrates and halides) in mesoporous silica matrices. This innovative approach is based on a concept demonstrated by the project team in 2015, involving the maximization of the weight fraction of the active heat storage component through impregnation inside the silica mesopores and in the interparticle spaces, while yielding shape-stability (preservation of macroscopic solid form upon active component phase transition) through capillary forces. The project aims at laboratory demonstration of a novel material with 220J/g heat storage over 100 °C range, an increase of ~50% over state-of-the-art. In contrast with current approaches based only on sensible heat storage, this project will utilize both latent and sensible heat storage mechanisms, increasing the storage capacity and operating temperature range which will yield increased efficiencies and decreased cost per kWh for CSP. Fundamental research pertaining to this promising research field will also be carried out, with the aims of investigating the physico-chemical processes taking place upon molten salt nanoconfinement (adsorption/desorption, crystallization, stability and chemical reactions).

The project proposes a multidisciplinary approach and aims to consolidate the research team position as a leader in the field of shape-stabilized phase change materials with high storage potential, based on nanoconfinement effects. Furthermore, the project activities are aimed at both applicative and fundament research, increasing the team international visibility and capacity for further collaborative projects with industry and academia.

Sustainable autonomous system for nitrites/nitrates and heavy metals monitoring of natural water sources Call name: P 3 - SP 3.2 - Proiecte ERA.NET
M-ERA.NET-WaterSofe 2016 - 2018

Role in this project:

Coordinating institution: INSTITUTUL DE CHIMIE FIZICA - ILIE MURGULESCU

Project partners: INSTITUTUL DE CHIMIE FIZICA - ILIE MURGULESCU (RO); NANOM MEMS SRL (RO); INSTITUTUL NATIONAL DE CERCETARE- DEZVOLTARE PENTRU MICROTEHNOLOGIE - IMT BUCURESTI INCD (RO); UNIVERSITATEA TRANSILVANIA BRASOV (RO)

Affiliation: INSTITUTUL DE CHIMIE FIZICA - ILIE MURGULESCU (RO)

Project website: http://www.icf.ro/pr_2016/WaterSafe/index.html

Abstract:

The project sets to develop a new energy autonomous system based on (photo)electrochemical sensors for detection of different ionic species in natural water sources and ultra-thin solar cells (UTSC). It focuses on three directions: high efficiency, new materials in solar energy harvesting and fabrication of small UTSC and the power stabilizing device able to supply the needed voltage to the sensors and electronic module; new microsensors for detection of nitrites/nitrates and heavy metals in water; low cost autonomous energy system integration and fabrication.

The harvester will include a UTSC, a dedicated storage and a power stabilizing device. SnO2, TiO2, ZnO materials will be optimised for sensors and (TiO2, ZnO,CuxS)or(CZTS, CuxS, TiO2) for the solar cells. Bacterial flagellar filaments will be investigated and engineered as sensitive biolayer for heavy metal detection. The project will provide a technology demonstrator and water monitoring system prototype.

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:

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 DE CHIMIE FIZICA - ILIE MURGULESCU (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.

Laser processing of thin nanostructured oxide films for transparent and conventional electronics. Call name:
PN II 11061 (1106/2007) 2007 - 2010

Role in this project: Key expert

Coordinating institution: INSTITUTUL NATIONAL DE CERCETARE - DEZVOLTARE PENTRU FIZICA MATERIALELOR BUCURESTI RA

Project partners: INSTITUTUL NATIONAL DE CERCETARE - DEZVOLTARE PENTRU FIZICA MATERIALELOR BUCURESTI RA (RO)

Affiliation: INSTITUTUL NATIONAL DE CERCETARE - DEZVOLTARE PENTRU FIZICA MATERIALELOR BUCURESTI RA (RO)

Project website:

Abstract:

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