Flogen
In Honor of Nobel Laureate Prof. Ferid Murad


SIPS2021 has been postponed to Nov. 27th - Dec. 1st 2022
at the same hotel, The Hilton Phuket Arcadia,
in Phuket, Thailand.
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Abstract Submission Open! About 300 abstracts submitted from about 40 countries


Featuring 9 Nobel Laureates and other Distinguished Guests

List of Accepted Abstracts

As of 22/12/2024: (Alphabetical Order)
  1. Dmitriev International Symposium (6th Intl. Symp. on Sustainable Metals & Alloys Processing)
  2. Horstemeyer International Symposium (7th Intl. symp. on Multiscale Material Mechanics and Sustainable Applications)
  3. Kipouros International Symposium (8th Intl. Symp. on Sustainable Molten Salt, Ionic & Glass-forming Liquids and Powdered Materials)
  4. Kolomaznik International Symposium (8th Intl. Symp. on Sustainable Materials Recycling Processes and Products)
  5. Marcus International Symposium (Intl. symp. on Solution Chemistry Sustainable Development)
  6. Mauntz International Symposium (7th Intl. Symp. on Sustainable Energy Production: Fossil; Renewables; Nuclear; Waste handling , processing, and storage for all energy production technologies; Energy conservation)
  7. Nolan International Symposium (2nd Intl Symp on Laws and their Applications for Sustainable Development)
  8. Navrotsky International Symposium (Intl. symp. on Geochemistry for Sustainable Development)
  9. Poveromo International Symposium (8th Intl. Symp. on Advanced Sustainable Iron and Steel Making)
  10. Trovalusci International Symposium (17th Intl. Symp. on Multiscale and Multiphysics Modelling of 'Complex' Material (MMCM17) )
  11. Virk International Symposium (Intl Symp on Physics, Technology and Interdisciplinary Research for Sustainable Development)
  12. Yoshikawa International Symposium (2nd Intl. Symp. on Oxidative Stress for Sustainable Development of Human Beings)
  13. 6th Intl. Symp. on New and Advanced Materials and Technologies for Energy, Environment and Sustainable Development
  14. 7th Intl. Symp. on Sustainable Secondary Battery Manufacturing and Recycling
  15. 7th Intl. Symp. on Sustainable Cement Production
  16. 7th Intl. Symp. on Sustainable Surface and Interface Engineering: Coatings for Extreme Environments
  17. 8th Intl. Symp. on Composite, Ceramic and Nano Materials Processing, Characterization and Applications
  18. International Symposium on Corrosion for Sustainable Development
  19. International Symposium on COVID-19/Infectious Diseases and their implications on Sustainable Development
  20. 4th Intl. Symp. on Sustainability of World Ecosystems in Anthropocene Era
  21. 3rd Intl. Symp. on Educational Strategies for Achieving a Sustainable Future
  22. 3rd Intl. Symp. on Electrochemistry for Sustainable Development
  23. 9th Intl. Symp. on Environmental, Policy, Management , Health, Economic , Financial, Social Issues Related to Technology and Scientific Innovation
  24. 7th Intl. Symp. on Sustainable Production of Ferro-alloys
  25. 2nd Intl Symp on Geomechanics and Applications for Sustainable Development
  26. 3rd Intl. Symp.on Advanced Manufacturing for Sustainable Development
  27. 5th Intl. Symp. on Sustainable Mathematics Applications
  28. Intl. Symp. on Technological Innovations in Medicine for Sustainable Development
  29. 7th Intl. Symp. on Sustainable Mineral Processing
  30. 7th Intl. Symp. on Synthesis and Properties of Nanomaterials for Future Energy Demands
  31. International Symposium on Nanotechnology for Sustainable Development
  32. 8th Intl. Symp. on Sustainable Non-ferrous Smelting and Hydro/Electrochemical Processing
  33. 2nd Intl. Symp. on Physical Chemistry and Its Applications for Sustainable Development
  34. 2nd Intl Symp on Green Chemistry and Polymers and their Application for Sustainable Development
  35. 8th Intl. Symp. on Quasi-crystals, Metallic Alloys, Composites, Ceramics and Nano Materials
  36. 2nd Intl Symp on Solid State Chemistry for Applications and Sustainable Development
  37. Summit Plenary
  38. Modelling, Materials and Processes Interdisciplinary symposium for sustainable development
  39. 7TH INTL. SYMP. ON SUSTAINABLE PRODUCTION OF FERRO-ALLOYS

    To be Updated with new approved abstracts

    Effect of Heat Treatment parameters on Microstructure morphology and Mechanical Properties of automotive steel
    Shahid Hussain Abro1; Guwanwook Thouth Kim2;
    1NED UNIVERSITY OF ENGINEERING AND TECHNOLOGY PAKISTAN, KARACHI, Pakistan; 2KOREA ADVANCED INSTITUTE OF SCIENCE AND TECHNOLOGY, Daejeon, South Korea;
    sips20_12_309

    The SAE/AISI 1045 steel is one of the structural steels widely used in the automotive sector to several key components such as connecting shafts, axles etc. It is also used in petrochemicals and power generation units. In material science and engineering; four interdependent parameters are of paramount importance which includes; process structure, properties and performance. Among all factors the structure / microstructure is of utmost importance since it governs the properties at large. For example it depends on the size, shape, and distribution of various micro constituents therein. Therefore, the main aim of this study is to investigate the response of the microstructures (structure-property correlation) upon application of heat treatment processes such as annealing, normalizing, tempering and hardening. This was followed by the characterization such as spectrometry analysis was carried out for chemical composition of the steel. While impact and hardness tests were also conducted. Results suggest an improved toughness and hardness when tempering temperature was reduced. This is attributed to decreased grain sizes of micro constituents upon such treatment. Interestingly one more aspect was noted that the chemical composition changes slightly during heat treatment processes which might be in range of standard. However, it could affect the surface properties of steel during service.

    Keywords:
    Ferro-Alloys; Metallurgy; Metals; Steel; Sustainability; Treatment;


    References:
    K. Funatani and G. Totten, "Present Accomplishments and Future Challenges of Quenching Technology," in Proceedings of the 6th International Federation of Heat treatment and Surface Engineering Congress, IFHTSE, Kyongju, Korea, 1997, pp. 20-27.
    [2] D. Fadare, T. Fadara, and O. Akanbi, "Effect of heat treatment on mechanical properties and microstructure of NST 37-2 steel," 2011.
    [3] T. Gladman, D. Dulieu, and I. McIvor, "Microalloying 75 Symposium," Washington, DC, pp. 25-34, 1977.
    [4] P. N. Rao, Manufacturing technology vol. 1: Tata McGraw-Hill Education, 2013.
    [5] A. Çalik, "Effect of cooling rate on hardness and microstructure of AISI 1020, AISI 1040 and AISI 1060 Steels," International journal of Physical sciences, vol. 4, pp. 514-518, 2009.
    [6] S. Sankaran, V. S. Sarma, and K. Padmanabhan, "Low cycle fatigue behavior of a multiphase microalloyed medium carbon steel: comparison between ferrite–pearlite and quenched and tempered microstructures," Materials Science and Engineering: A, vol. 345, pp. 328-335, 2003.
    [7] G. Gopalkrishna, R. B. Gurumurthy, and M. Davanageri, "Heat treatment and mechanical characterization of En8 steel," in AIP Conference Proceedings, 2019, p. 050005.
    [8] S. Rahman, K. E. Karim, and M. H. S. Simanto, "Effect of Heat Treatment on Low Carbon Steel: An Experimental Investigation," in Applied Mechanics and Materials, 2017, pp. 7-12.
    [9] C. M. Moleejane, "An experimental investigation of the effect of microstructural features on mechanical properties of EN8 steel," Cape Peninsula University of Technology, 2009.
    [10] M. B. Ndaliman, "An assessment of mechanical properties of medium carbon steel under different quenching media," AU JT, vol. 10, pp. 100-104, 2006.
    [11] S. Harisha, S. Sharma, U. A. Kini, and M. G. Shankar, "Study on Spheroidization and Related Heat Treatments of Medium Carbon Alloy Steels," in MATEC Web of Conferences, 2018, p. 02008.
    [12] T. Senthilkumar and T. K. Ajiboye, "Effect of heat treatment processes on the mechanical properties of medium carbon steel," Journal of Minerals & Materials Characterization & Engineering, vol. 11, pp. 143-152, 2012.
    [13] I. Akhyar and M. Sayuti, "Effect of heat treatment on hardness and microstructures of AISI 1045," in Advanced Materials Research, 2015, pp. 575-579.
    [14] T. B. Massalski, "Binary alloy phase diagrams," ASM international, vol. 3, p. 2874, 1992.
    [15] G. F. Vander Voort, S. R. Lampman, B. R. Sanders, G. J. Anton, C. Polakowski, J. Kinson, et al., "ASM handbook," Metallography and microstructures, vol. 9, pp. 44073-0002, 2004.
    [16] N. M. Ismail, N. A. A. Khatif, M. A. K. A. Kecik, and M. A. H. Shaharudin, "The effect of heat treatment on the hardness and impact properties of medium carbon steel," in IOP Conference Series: Materials Science and Engineering, 2016, p. 012108.



    Verification of T-x-y diagrams on the boundary of Fe-Ni-Co-Cu-S system
    Vasily Lutsyk1; Vera Vorob'Eva1; Anna Zelenaya1; Maria Parfenova1;
    1INSTITUTE OF PHYSICAL MATERIALS SCIENCE SB RAS, Ulan-Ude, Russian Federation;
    sips20_12_273

    The quaternary Fe-Ni-Co-Cu system is a basic system for many industrial alloys, including currently actively developing alloys with high entropy of mixing [1]. The study of the formation of copper-nickel deposits, optimization of the processes in metallurgy of copper, nickel and cobalt, the production of new compounds with various properties have a physicochemical basis and can be solved through obtaining the accurate and reliable information on phase equilibriums within the four-component Fe-Ni-Cu-S and Fe-Ni-Co-S systems as well as their ternary boundary systems [2-4].
    We had elaborated 3D computer models for T-x-y diagrams of real systems and for their prototypes with the expanded borders between the phase regions and afterwards we have printed 3D-puzzles of the exploded phase diagrams with the phase regions and with the clusters of phase regions as its elements.
    After the verifying of information on the bounding ternary systems, the assembling of the four-dimensional T-x-y-z diagrams has been completed. The methodology, which has been successfully developed by the authors for a long time, includes a comprehensive approach implemented in several stages: 1) to develop a prototype (4D computer model) of T-x-y-z diagram for a four-component system, based on knowledge about boundary systems and basic phase interactions within the volume of the system under study; 2) to obtain sufficient and reliable experimental data in a wide range of concentrations and temperatures; 3) to refine the T-x-y-z diagram prototype of the study system, taking into account the experimental results obtained.
    This work was been performed under the program of fundamental research SB RAS (project 0270-2021-0002).

    Keywords:
    Ferro-Alloys; Metallurgy; Technology; Phase Diagrams; Computer Simulation


    References:
    1. Vorob'eva V.P., Zelenaya A.E., Lutsyk V.I., Sineva S.I., Starykh R.V., Novozhilova O.S. High-Temperature Area of the Fe-Ni-Co-Cu Diagram: Experimental Study and Computer Design // Journal of Phase Equilibria & Diffusion. 2021; doi: https://doi.org/10.1007/s11669-021-00863F-3.
    2. Lutsyk V.I., Vorob'eva V.P., Zelenaya A.E. 3D computer model of the Ni-Cu-NiS-Cu2S Subsystem T-x-y diagram above 575oC // Russian Journal of Physical Chemistry. 2019. V. 93. No 13. P. 2593-2599.
    3. Lutsyk, Vorob'eva V.P., Zelenaya A.E., Lamueva M.V. Т-х-у 3D Computer Model of the Co-Cu-CoS-Cu2S Subsystem T-x-y Diagram Above 800oC // Journal of Mining and Metallurgy. Section B: Metallurgy. 2021; doi: http://dx.doi.org/10.2298/JMMB1.
    4. Lutsyk V.I., Vorob'eva V.P. 3D Computer Models of the T-x-y Diagrams, Forming the Fe-Ni-Co-FeS-NiS-CoS Subsystem // Russian Journal of Physical Chemistry. 2017. V. 91. No 13. P. 2593-2599.






    To be Updated with new approved abstracts