Modernization of polytechnic physics education in the conditions of present-day production

Issue 55, 2024

Gizatulla Imashev, Bayan Kuanbayeva, Lyailya Koishigulova, Marzhan Galymzhanova, Anar Tumysheva

Received 29.08.2023, Revised 17.11.2023, Accepted 25.02.2024

https://doi.org/10.54919/physics/55.2024.282qy3

Abstract

Relevance. The paper reveals the prerequisites for the modernisation of the modern system of polytechnic education when teaching physics in secondary school at the present stage. The paper defines the principles of construction and the content of the modernised polytechnic material, on which the process of forming practical skills in physics is based in secondary school.

Purpose. The article reveals the pedagogical conditions that contribute to improving the effectiveness of polytechnic training and the choice of future professions related to technology, as well as the essence of the practical activity of a physics teacher in a modern school in the totality of its principles, forms and methods of working with students.

Methodology. The paper uses such research methods as the analysis of psychological and pedagogical, scientific and methodological, educational and methodical literature on the problem of polytechnic education; a systematic approach to the study of new equipment and production technologies; analysis of their work on the introduction of polytechnic materials developed by the authors into the educational process of secondary schools; conducting and processing the results of a pedagogical experiment; discussion of the results of research at methodological seminars, scientific and practical conferences.

Results. In the aspect of the main directions aimed at modernisation of polytechnic education, the analysis is given and recommendations are proposed for regular and extracurricular activities in physics, in particular, recommendations for lessons with applied material, as well as practical classes. This paper describes the introduction of modern means of quality control of education at all levels and stages of the polytechnic education system in the process of teaching physics in secondary school.

Conclusions. The article is of interest to scientists, practical teachers, as well as to everyone who takes part in the renewal of modern society. The article discusses the materials of the scientific project carried out at Kh. Dosmukhamedov Atyrau University.

Keywords: innovative approaches; teaching methods; secondary school students; field of technology; applied significance

Suggested citation

Imashev G, Kuanbayeva B, Koishigulova L, Galymzhanova M, Tumysheva A. Modernization of polytechnic physics education in the conditions of present-day production. Sci Herald Uzhhorod Univ Ser Phys. 2024;(55):2823-2833. DOI: 10.54919/physics/55.2024.282qy3

Download article

References

  1. Imashev G. Development of technical and technological knowledge in the school physics course. Almaty: Otan; 2020.
  2. Atutov PR. Polytechnic education of schools: convergence of general education and vocational schools. Moscow: Pedagogika; 1986.
  3. Bugayev AI. Methodology of physics teaching at high school. Moscow: Prosveshcheniye; 1981.
  4.  Razumovsky VG. Developing the creative abilities of students in the process of teaching physics. Moscow: Prosveshcheniye; 1975.
  5. Glazunov AT. Engineering in high school physics course. Moscow: Obrazovaniye; 1977.
  6. Korshak EV. Scientific and technological progress and the study of physics in school. Kyiv: Radyanska Shkola; 1977.
  7. Shut MI. Electrics and magnetism. Kyiv: National Pedagogical Dragomanov University; 2002.
  8. Abylkassymova AE. Theory and methodology of teaching mathematics: didactic and methodological aspect. Almaty: Mektep; 2014.
  9. Almukhambetov BA. Modern system of professional development of education workers in Kazakhstan. Bull High Sch Kazakh. 2001;1:25-32.
  10. Seiteshev AP. Professional orientation of the personality. Theory and practice of education. Alma-Ata: Nauka; 1990.
  11. Oporkin IYa. Polytechnicism and education – realities and prospects. St. Petersburg: Nauka; 2005.
  12. Imashev G. Innovative technologies of training in physics at high school. Chisinau: Lambert Academic Publishing; 2015.
  13. Rieffel E, Polak W. Quantum computing: A gentle introduction. New York: MIT Press; 2011.
  14. Suprunova LL. Experience of modernization of education in India. Moscow: Progress-Traditsiya; 2009.
  15. Imashev G, Kuanbayeva B, Rakhmetova M, Salykbayeva Zh, Turkmenbayev A, Issatayeva Zh, Murynov B, Gainieva A. Development of modern polytechnic education at physics classes. AD ALTA: J Interdiscip Res. 2019;9(1(VII)):25-30.
  16. Yutkin II. Polytechnic education in the course of technology. Moscow: Nauka; 2005.
  17. Burinskaya NN. Polytechnic education and vocational guidance of students in the process of teaching chemistry. Moscow: Obrazovaniye; 2016.
  18. Davydov VV. Polytechnic problems in school. Moscow: Obrazovaniye; 2005.
  19. Maharramov A, Shikhaliyev NQ, Qajar A, Atakishiyeva GT, Niyazova A, Khrustalev VN, Akkurt M, Yildirim SÖ, Bhattarai A. Crystal structures and Hirshfeld surface analyses of (E)-1-[1-(4-tert-butyl­phen­yl)-2,2-di­chloro­ethen­yl]-2-phenyl­diazene, (E)-1-[1-(4-tert-butyl­phen­yl)-2,2-di­chloro­ethen­yl]-2-(4-methyl­phen­yl)diazene, (E)-1-[1-(4-tert-butyl­phen­yl)-2,2-di­chloro­ethen­yl]-2-(4-meth­oxy­phen­yl)diazene and (E)-1-[1-(4-tert-butyl­phen­yl)-2,2-di­chloro­ethen­yl]-2-(3-methyl­phen­yl)diazene. Acta Crystallogr Sect E: Crystallogr Commun. 2023;79:637-643.
  20. Shikhaliyev NQ, Bagirova KN, Niyazova AA, Mammadova GZ, Cisterna J, Cárdenas A, Brito I. Crystal Structure and Hirshfeld Surface Analysis of (E)-1-(4-Bromophenyl)-2-(2,2-Dichloro-1-(4-Fluorophenyl)vinyl)diazene. Crystallogr Rep. 2020;65(7):1169-1172.
  21. Kisała J, Ferraria AM, Mitina N, Cieniek B, Krzemiński P, Pogocki D, Nebesnyi R, Zaichenko O, Bobitski Y. Photocatalytic activity of layered MoS2 in the reductive degradation of bromophenol blue. RSC Adv. 2022;12(35):22465-22475.
  22. Lyubchyk SI, Lyubchyk SB, Lyubchyk AI. Characterization of adsorption properties inherent to zirconia dioxide for different positions of yttrium in the ZrO2–Y2O3 lattice. Semicond Phys, Quant Electr Optoelectr. 2022;25(4):362-371.
  23. Ahmadov F, Ahmadov G, Akbarov R, Aktag A, Budak E, Doganci E, Gurer U, Holik M, Kahraman A, Karaçali H, Lyubchyk S, Lyubchyk A, Mammadli A, Mamedov F, Nuruyev S, Pridal P, Sadigov A, Sadygov Z, Urban O, Yilmaz E, Yilmaz O, Zich J. Investigation of parameters of new MAPD-3NM silicon photomultipliers. J Instrument. 2022;17(1):C01001.
  24. Dmytruk Y, Ivasiv V, Nebesnyi R, Maykova S. Optimum conditions determination of methyl methacrylate obtaining over tungsten-containing catalyst. East-Eur J Enterp Technol. 2015;4(6):4-7.
  25. Nebesna Y, Ivasiv V, Nebesnyi R. The study of technological and kinetic regularities of simultaneous methacrylates obtaining over zirconium-containing catalysts. East-Eur J Enterp Technol. 2015;5(6):49-52.
  26. Wang L, Ismailova J, Uteubayeva Y, Chen J, Kunzharikova K. Effect of pore size distribution on phase behavior of sour gas and hydrocarbon mixtures in tight oil reservoirs. In: Society of Petroleum Engineers - SPE Annual Caspian Technical Conference 2020, CTC 2020. Virtual, Online: Society of Petroleum Engineers; 2020.
  27. Ismailova J, Delikesheva D, Abdukarimov A, Zhumanbetova N, Sarsenova A. Development and application of fluid characterization algorithms to obtain an accurate description of a pvt model for Kazakhstani oil. East-Eur J Enterp Technol. 2023;5(6(125)):6-20.
  28. Ismailova J, Abdukarimov A, Delikesheva D, Mombekov B, Ismailov A. Application of fusion property estimation within the multisolid wax prediction model on Kazakhstani crude. Heat Transf. 2023. DOI: 10.1002/htj.22960.
  29. Mihai S, Bondarev A, Negoiu M. Complexes of Pt(II) and Pd(II) with symmetrical bipodal N,N-bis-antipyrine-N'pyridinethioureas. Rev Chim. 2013;64(2):191-194.
  30. Grigore E, Pantea O, Bombos D, Calin C, Bondarev A, Gheorghe C. Effect of inhibitors based amine derivates on some carbon steel corrosion. Rev Chim. 2015;66(5):685-690.
  31. Aueshov AP, Arynov KT, Eskibaeva CZ, Zhilkibaev OT, Sataev MS, Beisbekova RD. Production of iron phosphide by reduction of polyphosphates with metallic iron. Russ J Appl Chem. 2014;87(6):684-688.
  32. Auyeshov AP, Arynov KT, Yeskibayeva CZ, Zhylkybayev OT, Beisbekova RD, Alzhanov KB. Effect of α- and β-polymethyle nenaphthalenesulfonate upon properties of cement grout and concrete. Modern Appl Sci. 2015;9(6):173-183.
  33. Lyubchyk A, Lygina O, Lyubchyk S, Fonseca I, Tulepov M, Mansurov Z, Lyubchik S. Activated carbons from co-mingled liquid and solid organic wastes. Euras Chem-Technol J. 2015;17:47-65.
  34. Khardazi S, Zaitouni H, Neqali A, Lyubchyk S, Mezzane D, Amjoud M, Choukri E, Kutnjak Z. Enhanced thermal stability of dielectric and energy storage properties in 0.4BCZT-0.6BTSn lead-free ceramics elaborated by sol-gel method. J Phys Chem Sol. 2023;177:111302.
  35. Doroshkevich AS, Zakharova AS, Oksengendler BL, Lyubchyk AI, Lyubchyk SI, Lyubchyk SB, Tatarinova AA, Kirillov AK, Vasilenko TA, Gorban OO, et al. The Rectifying Contact of Hydrated Different Size YSZ Nanoparticles for Advanced Electronics. Nanomater. 2022;12(24):4493.
  36. Nebesnyi R, Ivasiv V, Pikh Z, Zhyznevskyi V, Dmytruk Y. The kinetics of the gas phase aldol condensation reaction of propionic acid with formaldehyde on B2O3-P2O5-WO3/SiO2 catalyst. Chem Chem Technol. 2014;8(1):29-34.
  37. Nebesnyi R, Ivasiv V, Dmytuk Y, Lapychak N. Acrylic Acid Obtaining By Acetic Acid Catalytic Condensation With Formaldehyde. East-Eur J Enterp Technol. 2013;6(6(66)):40-42.
  38. Bondarev A, Mihai S, Pântea O, Neagoe S. Use of biopolymers for the removal of metal ion contaminants from water. Macromol Symp. 2011;303(1):78-84.
  39. Bondarev A, Popovici DR, Călin C, Mihai S, Sȋrbu E-E, Doukeh R. Black Tea Waste as Green Adsorbent for Nitrate Removal from Aqueous Solutions. Mater. 2023;16(12):4285.
Make a Submission

Indexing

info@physics.uz.ua