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In Honor of Nobel Laureate Prof. M Stanley Whittingham
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Abstract Submission Open ! About 500 abstracts submitted from around 60 countries.


Featuring many Nobel Laureates and other Distinguished Guests

List of abstracts

As of 22/11/2024: (Alphabetical Order)
  1. Assis International Symposium (9th Intl. Symp. on Advanced Sustainable Iron & Steel Making)
  2. Carter International Symposium (3rd Intl Symp on Laws & their Applications for Sustainable Development)
  3. Durán International Symposium on Sustainable Glass Processing and Applications
  4. Echegoyen International Symposium (8th Intl. Symp. on Synthesis & Properties of Nanomaterials for Future Energy Demands)
  5. Guerrant International Symposium (2nd Intl Symp. on COVID-19/Infectious Diseases & their implications on Sustainable Development)
  6. Kumar international Symposium (8th Intl. Symp. on Sustainable Secondary Battery Manufacturing & Recycling)
  7. Navrotsky International Symposium (2nd Intl. Symp. on Geochemistry for Sustainable Development)
  8. Poeppelmeier International Symposium(3rd Intl Symp on Solid State Chemistry for Applications & Sustainable Development)
  9. Torem International Symposium (8th Intl. Symp. on Sustainable Mineral Processing)
  10. Ozawa International Symposium (3rd Intl. Symp. on Oxidative Stress for Sustainable Development of Human Beings)
  11. 7th Intl Symposium on New & Advanced Materials and Technologies for Energy, Environment, Health and Sustainable Development
  12. 8th International Symposium on Sustainable Biochar, Cement and Concrete Production and Utilization
  13. 6th Intl. Symp. on Sustainable Carbon and Biocoke and their Industrial Application
  14. 2nd Intl Symp. on Corrosion for Sustainable Development
  15. 4th Intl. Symp. on Electrochemistry for Sustainable Development
  16. 8th Intl. Symp. on Sustainable Energy Production: Fossil; Renewables; Nuclear; Waste handling , processing, & storage for all energy production technologies; Energy conservation
  17. 6th Intl. Symp. on Sustainable Mathematics Applications
  18. 2nd Intl. Symp. on Technological Innovations in Medicine for Sustainable Development
  19. 18th Intl. Symp. on Multiscale & Multiphysics Modelling of 'Complex' Material
  20. Modelling, Materials & Processes Interdisciplinary symposium for sustainable development
  21. 9th Intl. Symp. on Sustainable Molten Salt, Ionic & Glass-forming Liquids & Powdered Materials
  22. 2nd Intl Symp on Physics, Technology & Interdisciplinary Research for Sustainable Development
  23. 9th Intl. Symp. on Sustainable Materials Recycling Processes & Products
  24. Summit Plenary
  25. 9th Intl. Symp. on Sustainable Materials Recycling Processes & Products

    To be Updated with new approved abstracts

    [Solid and liquid wastes from industrial processes: Innovations in material recovery and environmental protection]
    CONTROL AND AUTOMATION OF ROTARY KILN
    Florian Kongoli1;
    1FLOGEN Technologies, Mont-Royal, Canada;
    sips23_7_498

    Rotary Kiln is a rotating cylindrical reactor that reduces the oxide feed minerals or dusts with carbon reductants and/or natural gas in order to extract a specific component from the feed by volatilization and produce a waste oxide material or to preliminary reduce the feed material into a pre-reduced one to be subsequently used in a specific reactor. Because of the specificity of these rotating reactors the number of shutdowns to clean the reactors are numerous and as such they constitute a big source of productivity loss. This work presents a unique control of process operations of rotary kilns, concentrating in one of the most difficult ones, the Waelz Process through the unique proprietary FLOGEN CONTOP design, decision making, control, optimization and automation system that made possible a considerable increase of the zinc recovery by volatilization and a drastic decrease of the numbers of shutdowns. 

    Keywords:
    CO2; Non-Ferrous; Recycling; Sustainability; Wastes; Zinc



    [Solid and liquid wastes from industrial processes: Innovations in material recovery and environmental protection]
    FOUNDRY WASTE OR SECONDARY RAW MATERIALS?
    Alena Pribulova1; Peter Futas2; Patrik Fedorko3; Jozef Petrik4; Peter Blasko5; Marcela Pokusova6;
    1Technical U. in Kosice, Kosice, ; 2Technical U. of Kosice, Kosice, Slovakia; 3Technical university, Faculty of Materials, Metallurgy and Recycling, Kosice, Slovakia; 4Technical university of Kosice, Kosice, Slovakia (Slovak Republic); 5Technical university of Kosice, Kosice, Slovakia; 6Slovak University of Technology in Bratislava, Bratislava, Slovenia;
    sips23_7_131

    According to the Waste Act, a waste is something that the owner wants to get rid of, or the removal of which is necessary from the point of view of caring for a healthy environment. The term secondary raw material is not defined in the legislation, but it is commonly used in practice [1]. It is a raw material that is obtained from waste by various procedures, i.e. it is created by human activity, which distinguishes it from primary raw material that was created by natural processes without human intervention. The condition for treating treated waste to be called a secondary raw material is that there is a demand for it and that it is traded on the producer's side.
    Foundry production is accompanied by the creation of a large amount of waste. At each stage of casting production, different types of waste are generated in different quantities. The largest amount of waste is used foundry sand, followed by various fine-grained wastes that arise during melting, preparation of moulding materials, production of moulds and cores, and during processing and blasting of castings [2]. Another important foundry waste is the slag that is created during melting in any furnace equipment.
    The current situation in Europe is "pushing" the producers of these wastes to reduce their amount. One possibility is waste recycling [3,4]. Most foundry waste cannot be directly recycled, but with certain modifications, they become secondary raw materials that can be used primarily in construction, agriculture, and partially also in foundries.
    This contribution analyses the waste generated in the foundry process and points out the possibilities of their treatment and further use.

    Keywords:
    Material; Recycling; Slags; Wastes;


    References:
    [1] Bodikova, E.: Support of new technologies leading to the use of waste as secondary raw materials in the conditions of EU member states : Acta Metallurgica Slovaca, 12, pp.33 – 38, 2006
    [2] Pribulova, A., Gengel, P., Bartosova, M.: Waste from the production of steel and cast iron castings (dust - their characteristics, properties and possibilities of their further use), Faculty of Metallurgy, Technical University of Košice, 2010, ISBN: 978-80-553-0601-8
    [3] European Commission: COM (2005) final. Communication from the Commission to the Council, the European Parliament, the European Economic and Social Committee and the Committee of the Regions. Promoting the sustainable use of resources: thematic strategy of waste prevention and recycling, Brussels, 21.12. 2005
    [4] Council of Europe Regulation 96/61/WE Pollution Reduction and Limitation (IPPC), 1996



    NEW BIOMATERIALS MADE BY DIFFERENT ORIGIN GELATINS FOR SKIN WOUND HEALING
    Carmen Gaidau1; Maria Rapa2;
    1R&D National Institute, Bucharest, Romania; 2POLITEHNICA University of Bucharest, Bucharest, Romania;
    sips23_7_93

    Skin is the most vulnerable organ to different kinds of injuries due to its large surface and potential for exposure to biological, mechanical, thermal, and radiation factors. In this context, the demand for innovative biomaterials for chronic wounds, skin burns, or skin disease treatment is high [1].
    Collagen is a consecrated biomaterial for different skin wound healing formulations like powders, creams, films, hydrogels, and microspheres, due to high biocompatibility and non-toxicity as compared to synthesis polymers [2]. Recent research reported the advanced efficiency of gelatin and collagen hydrolysate in wound healing as compared to native collagen [1], due to the more available peptides and binding sites for the regeneration mechanism in the wound healing process.
    The presentation will explore the potential of gelatins of different origins extracted from bovine and donkey hides, rabbit skin or fish scales to be processes as collagen nanofibers with preserved bioactivity and high efficiency in skin restoration due to the scaffold structure with increased surface area-to-volume ratio as compared to gelatin [3-7].
    The main properties of these gelatins such as dry substance, ash and protein content, conductivity, viscosity, and molecular weight will be presented in connection to spinnable properties in view of manufacturing collagen nanofibers for new biomaterials used in wound healing.
    The electrospinning parameters for fabrication of wound healing mats based on gelatins of different origins will be presented and the influence of solvents will be highlighted. The antimicrobial properties were improved by adding active substances from essential oils to metal and oxide nanoparticles. Coaxial electrospinning was used for volatile essential oils encapsulation and slow release in interaction with skin wounds.
    The properties of collagen nanofibers manufactured from different gelatins will be presented in connection with their specific structure and origin: size dimension and morphology (SEM), surface composition (EDX), antioxidant properties, phenol releasing, cytotoxic concentrations, in vivo biocompatibility, and antimicrobial properties.
    Finally, the behavior of gelatin nanofibers as compared to gelatins to preservation treatments by different gamma radiation doses will be discussed.
    Different gelatin nanofibers successfully fabricated from different raw materials showed the huge potential for biomaterials innovation as compared to the use of classical native collagen in skin wound healing.

    Keywords:
    Material; Recycling; Sustainability; Technology; Wastes; gelatin, gelatin nanofibers, wound healing, nanofibers properties, by-products valorization


    References:
    [1] Prelipcean, A.-M.; Iosageanu, A.; Gaspar-Pintiliescu, A.; Moldovan, L.; Craciunescu, O.; Negreanu-Pirjol, T.; Negreanu-Pirjol, B.; Mitran, R.-A.; Marin, M.; D’Amora, U. Marine and Agro-Industrial By-Products Valorization Intended for Topical Formulations in Wound Healing Applications. Materials 2022, 15, 3507. https://doi.org/10.3390/ma15103507
    [2] Deaconu, M.; Prelipcean, A.-M.; Brezoiu, A.-M.; Mitran, R.-A.; Isopencu, G.; Matei, C.; Berger, D.Novel Collagen-Polyphenols-Loaded Silica Composites for Topical Application. Pharmaceutics 2023, 15, 312. https://doi.org/10.3390/pharmaceutics15020312
    [3] Maria Râpă , Traian Zaharescu, Laura Mihaela Stefan, Carmen Gaidău,*, Ioana Stănculescu ,*, Rodica Roxana Constantinescu and Maria Stanca, Bioactivity and Thermal Stability of Collagen–Chitosan Containing Lemongrass Essential Oil for Potential Medical Applications, Polymers 2022, 14, 3884, https://doi.org/10.3390/polym14183884
    [4] Maria Râpa , Carmen Gaidau2,* , Liliana Mititelu-Tartau , Mariana-Daniela Berechet , Andrei Constantin Berbecaru, Irina Rosca, Aurica P. Chiriac , Ecaterina Matei, Andra-Mihaela Predescu, Cristian Predescu, Bioactive Collagen Hydrolysate-Chitosan/Essential Oil Electrospun Nanofibers Designed for Medica lWound Dressings, Pharmaceutics 2021, 13, 1939, https://doi.org/10.3390/pharmaceutics13111939
    [5] Ecaterina Matei, Carmen Gaidau, Maria Râpă, Laura Mihaela Stefan, Lia-Mara Ditu ,
    Andra Mihaela Predescu , Maria Stanca , Mircea Cristian Pantilimon , Daniela Berechet , Cristian Predescu and Anamaria Mosutiu, Sustainable Coated Nanostructures Based on Alginate and Electrospun Collagen Loaded with Antimicrobial Agents, Coatings 2021, 11, 121, https://doi.org/10.3390/coatings11020121
    [6] Ecaterina Matei, Carmen Gaidau2*, Maria Râpă1*, Roxana Constantinescu, Simona Savin, Mariana Daniela Berechet, Andra Mihaela Predescu, Andrei Constantin Berbecaru, George Coman, Cristian Predescu, Sustainable Rabbit Skin Glue to Produce Bioactive Nanofibersfor Non-Active Wound Dressings, Materials 2020, 13(23), 5388; https://doi.org/10.3390/ma13235388
    [7] Maria Râpă , Carmen Gaidău*, Laura Mihaela Stefan, Ecaterina Matei, Mihaela Niculescu, Mariana Daniela Berechet, Maria Stanca, Cristina Tablet, Mădălina Tudorache, Raluca Gavrilă, Cristian Predescu, Ruxandra Vidu, New Nanofibers based on Protein By-Products with Bioactive Potential for Tissue Engineering, Materials 2020, 13(14), 3149; https://doi.org/10.3390/ma13143149



    [Solid and liquid wastes from industrial processes: Innovations in material recovery and environmental protection]
    PLANT AND MINERAL WASTE-BASED NEW MATERIALS FOR USE IN HYDRO- AND PYROMETALLURGICAL PROCESSES
    Svetlana Yefremova1; Askhat Kablanbekov2; Baimakhan Satbaev3; Feruza Berdikulova4; Nurgali Shalabaev5; Sergey Yermishin4; Serik Satbaev6; Alma Terlikbayeva4; Abdurassul Zharmenov4;
    1National Center on Complex Processing of Mineral Raw Materials, Almaty, Kazakhstan; 2Kazakh-British Technical University, Almaty, Kazakhstan; 3Astana Branch of National Center on Complex Processing of Mineral Raw Materials of the Republic of Kazakhstan RSE, Astana, Kazakhstan; 4National Center on Complex Processing of Mineral Raw Materials of the Republic of Kazakhstan RSE, Almaty, Kazakhstan; 5Abylkas Saginov Karaganda Technical University, Karaganda, Kazakhstan; 6National Center on Complex Processing of Mineral Raw Materials, Astana, Kazakhstan;
    sips23_7_209

    The Concept of Industrial and Innovative Development of the Republic of Kazakhstan for 2021-2025 includes the development of production of rare and rare earth metals among the priority areas. The latter, unfortunately, is associated with the emissions of organic compounds into the environment. To avoid this, it is necessary to purify solutions of rare-metal production from organic pollutants.
    Sorption with carbon sorbents of a novel type is considered to be the most effective way of removing organic impurities during the hydrometallurgy process of non-ferrous metals [1]. However, there are no data on the behavior of these sorbents in the hydrometallurgy of rare metals. Carbon sorbents active against the ions of rare, precious and heavy metals have been obtained from the waste of rice and coke production such as rice husk and special fine coke. It is known that activated carbons from rice husk are effective to remove organic pollutants [2-4]. But their production is associated with the formation of secondary waste.
    The purpose of the current work is to use rice husk and special fine coke to generate a new selective composite sorbent and resource-saving high-temperature material for use in hydro- and pyrometallurgical sectors of industry.
    Carbon and silica-containing components are isolated from the both waste. The carbon components are used to produce a composite sorbent. The silica-containing components are used to produce a high-temperature material. The combination of a finely dispersed rice husk carbon material with a large specific surface area and a more durable, meso- and macroporous special coke carbon material contributes to the formation of a carbon-carbon matrix when obtaining a composite sorbent. The combination of stoichiometric amounts of amorphous silicon dioxide isolated from rice husk, special fine coke ash and original rice husk is used to ensure the formation of highly refractory silicon carbide. The burning of rice husk contributes to the forming of a porous structure of the prepared material. The formation, on the one hand, of highly refractory phases and, on the other hand, of a porous system enhances the strength, durability and thermal insulation properties of the resulting refractory material.
    So, rice husk and special fine coke (some of the most common waste types) are promising raw materials for creating a selective composite sorbent of a novel type. In order to ensure the complex processing of special fine coke and rice husk, it seems practical to use silica-containing waste from composite sorbent production mixed with raw rice husk to synthesize a resource-saving high-temperature material.
    This research is funded by the Science Committee of the Ministry of Science and Higher Education of the Republic of Kazakhstan (grant number AP 19677767).

    Keywords:
    Hydrometallurgical; Material; Recycling; Technology; Wastes; Rice husk; Special fine coke; Sorbent; Refractory materials


    References:
    [1] Yu.V. Surovikin, V.A. Likholobov, V.V. Sergeev, I.V. Makarov, Solid Fuel Chemitry 6 (2014) 47-56.
    [2] Y. Deng, X. Wang, Y. Li, J. Shao, H. Yang, H. Chen, Sheng Wu Gong Cheng Xue Bao (Chinese Journal of biotechnology) 10 (2015) 1492-500.
    [3] M. Akhtar, M.I. Bhanger, S. Iqbal, S.M. Hasany, Journal of Hazardous Materials 1 (2006) 44-52.
    [4] S.L. Ng, C.E. Seng, P.E. Lim, Chemosphere 10 (2009) 1392-400.



    [Solid and liquid wastes from industrial processes: Innovations in material recovery and environmental protection]
    ZERO WASTE PROCESSING OF ZINC CONTAINING SLAGS FROM LEAD INDUSTRY
    Juergen Antrekowitsch1;
    1Christian Doppler Laboratory, Leoben, Austria;
    sips23_7_368

    Slags from primary lead industry are well known as potential resource for zinc which is accumulated in the slag during lead smelting. At some of the smelters a subsequent fuming process is installed to recover zinc which is usually present in a range between 4 to 16 %.

    However, at many lead producers this is not the case and the slag is landfilled. Out of this, over the years, a huge number of dumps was generated worldwide. The Chair of Nonferrous Metallurgy at Montanuniverstaet Leoben has developed possible strategies to treat such slags in a way that zinc and lead can be recovered and the remaining mineral phase containing first of all typical slag components can also be utilized. These concepts allow a full remediation of a dumpsite or a zero waste treatment of slag from ongoing smelter operations.

    The present paper describes the reduction process which is performed under CO2-neutral conditions, utilizing either hydrogen or charcoal. Furthermore, possibilities for slag modification and optimization are explained, allowing a utilization of the slag in building and construction industry. Results from various test campaigns in lab- and technical scale are discussed.

    Finally, an overview of the worldwide potential and some process scenarios including economic considerations are presented.

    Keywords:
    Lead; Recycling; Slags; Zinc


    References:
    [1] Auer M., C. Wölfler and J. Antrekowitsch: Inflluence of different carbon content on reduction of zinc oxide via metal bath. Applied Sciences (2022), 12, 2, 4180
    [2] Hanke G., J. Antrekowitsch, F. Castro and H. Krug: Maximizing the efficiency of by-product treatment by multi-metal recovery and slag valorization. Rewas 2022 – Developing tomorrow‘s technical cycles (2022), Anaheim, Kalifornien, USA, 201–211
    [3] Leuchtenmueller M., C. Legerer, U. Brandner U. and J. Antrekowitsch: Carbothermic Reduction of Zinc Containing Industrial Wastes: A Kinetic Model, Metallurgical and Materials Transactions B: Process Metallurgy and Materials Processing Science (2021), 548-557






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