04.07.2025; Ужгород, Україна: IX Міжнародна наукова конференція «Традиційні та інноваційні підходи до наукових досліджень»
Роботи, що індексуються в Google Scholar

FORMING ENVIRONMENTAL CULTURE IN THE MILITARY AS A FACTOR OF NATIONAL SECURITY

  • Elnur Mammadov
DOI: https://doi.org/10.62731/mcnd-04.07.2025.003
PDF

Опубліковано 04.07.2025

Як цитувати

Mammadov, E. (2025). FORMING ENVIRONMENTAL CULTURE IN THE MILITARY AS A FACTOR OF NATIONAL SECURITY. Матеріали конференцій МЦНД, (04.07.2025; Ужгород, Україна), 98–107. https://doi.org/10.62731/mcnd-04.07.2025.003

Завантаження

Дані завантаження ще не доступні.

Авторське право (c) 2025 Elnur Mammadov

Creative Commons License

Ця робота ліцензується відповідно до Creative Commons Attribution-ShareAlike 4.0 International License.

Google Scholar

Анотація

In an era marked by rapid technological advancements and evolving security threats, environmental challenges have become a key factor in the sustainability and effectiveness of military operations. Environmental degradation, particularly in conflict zones, has long been recognized as a critical concern for national security. Yet, despite its growing significance, the role of environmental culture in the military remains under-explored.

PDF

Посилання

  1. 1. Akhundov, R. (2017). Radiation-thermal activation of coal for water purification. In Ecological and environmental chemistry (pp. 141-141).
  2. 2. Akhundov, R. (2023). Application of means of remote radiation reconnaissance. In Modern trends ın the development of ınformatıon and communıcatıon technologıes and management tools. Abstracts of the Thirteenth International Scientific and Technical Conference. – Kharkiv, Ukraine (Vol. 2, pp. 8-9).
  3. 3. Akhundov, R. (2024). Environmental Warfare–Modern Global Challenge. In Modeling, Control and Information Technologies: Proceedings of International scientific and practical conference (No. 7, pp. 332-335).
  4. 4. Akhundov, R. (2024). The Environmental Consequences of Military Activity. In 20 години България в НАТО и НАТО в България (pp. 410-422). Военна академия „Г. C Раковски".
  5. 5. Akhundov, R. G. (2023). Methods of conducting chemical exploration. Abstracts of reports of the eleventh international scientific and technical conference ”Problems of ınformatızatıon”. – Kharkiv, Ukraine (Vol 2, pp.104-105).
  6. 6. Akhundov, R. G., & Ibadov, P. (2023). Problematic issues and prospects for the development of airborne radiation, chemical and biological reconnaissance systems. Baku: National security and military sciences, -2023.-1 (9). – p, 38-46.
  7. 7. Akhundov, R. G., & Mustafayev, I. I. (2020). Radiation-initiated processes of activation of charcoal. Journal of Radiation Researches, 7(1), 27-34.
  8. 8. Akhundov, R., & Hashimov, E. (2025). Military activity and the environment: The need for a systemic approach to radiological and chemical safety. In Zdobutky ta dosyagnennya prykladnykh ta fundamentalʹnykh nauk XXI stolittya: Zbirnyk naukovykh prats z materialamy IX Mizhnarodnoyi naukovoyi konferentsiyi (pp. 187-196). UKRLOGOS Group. https://doi.org/10.62731/mcnd-16.05.2025.004
  9. 9. Akhundov, R., & Hashimov, E. (2025). Radiation and chemical protection as a strategic priority of environmental security in the military sphere. In Zdobutky ta dosyagnennya prykladnykh ta fundamentalʹnykh nauk XXI stolittya: Zbirnyk naukovykh prats z materialamy IX Mizhnarodnoyi naukovoyi konferentsiyi (pp. 202-209). UKRLOGOS Group. https://doi.org/10.62731/mcnd-16.05.2025.005
  10. 10. Akhundov, R., & Islamov, I. (2025). Implementation of new technologies for cleaning and neutralizing radiological and chemical contaminants in military environments. Матеріали конференцій МЦНД, (30.05. 2025; Київ, Україна), 321-329. https://doi.org/10.62731/mcnd-30.05.2025.006
  11. 11. Axundov, R. Q. (2022). Radiasiya və kimyəvi təhdidlərdən mühafizənin vəziyyəti və inkişaf perspektivləri. Bakı: Milli təhlükəsizlik və hərbi elmlər, (3), 8.
  12. 12. Axundov, R. Q. (2023). Azərbaycan Ordusunda radiasiya, kimyəvə bioloji mühafizənin inkişaf problemləri və onlarin həlli yollari. Hərb sənətinin aktual problemləri” beynəlxalq elmi-praktik konfransın materialları,–Bakı: MMU, 137-138.
  13. 13. Axundov, R. Q. (2023). Azərbaycan Ordusunda radiasiya, kimyəvi və bioloji kəşfiyatının əsasları. Bakı: Hərbi bilik, (4), 16-20.
  14. 14. Axundov, R. Q. (2023). Dərinin fərdi qoruyucu vasitələrinin tətbiqi və inkişaf perspektivləri. Bakı: Milli təhlükəsizlik və hərbi elmlər, (4), 9.
  15. 15. Axundov, R. Q. (2023). Radiasiya, kimyəvi və bioloji mühafizə sisteminin texniki təminatının analizi. Ümummilli lider Heydər Əliyevin anadan olmasının, 100, 470-472.
  16. 16. Axundov, R. Q. (2023). Radiasiya, kimyəvi və bioloji mühafizə sisteminin təkmilləşdirilmə istiqamətləri. Müdafiə sənayesi üzrə ixtisaslı kadr hazırlığı: radioelektron, aerokosmik sistemlər və robotlar” mövzusunda II Respublika elmi-texniki konfransın materialları,–Bakı: AzTU, 89-92.
  17. 17. Axundov, R. Q., Abıyev, Q. A., & Nabizadə, Z. Radiasiyanın aktiv kömürlərin mexaniki möhkəmliyinə təsiri. Tibb elmləri doktoru Əzəm Təyyar oğlu Ağayevin anadan olmasının, 75, 14-17.
  18. 18. Axundov, R., & Abdullayev, R. S. (2023). Karbon əsaslı adsorbentlərin sintezi və tətbiqi. Bakı: Milli təhlükəsizlik və hərbi elmlər, (1), 9.
  19. 19. Babanlı, A. M., & Ibragimov, B. G. (2017). Specific heat in diluted magnetic semiconductor quantum ring. Superlattices and Microstructures, 111, 574-578.
  20. 20. Bayramov, A. A. et al. (2018). SMART control system of systems for dynamic objects group. Bulgarska Voenna Misal.
  21. 21. Bayramov, A. A. et al. (2018, April). The supervisory control systems deployment in mountainous terrain. In VIII Int. Conf.“Modern development trends of ICT and control methods (pp. 3-4).
  22. 22. Bayramov, A. A., & Hashimov, E. G. (2019). Development of UAV SoS flight combat reconnaissance mission program. Advanced Information Systems, 3(1), 152-156. DOI: 10.20998/2522-9052.2019.1.25
  23. 23. Hashimov, E. G., & Bayramov, A. A. (2015). Detection unobserved moving armored vehicles by seismic method. National Security and Military Sciences, 1(1), 128-132.
  24. 24. Hashimov, E. G., & Bayramov, A. A. (2017). Application of GIS and seismic location method for detection of invisible military objects. Monograph//- Baku: Military Publishing House, 246 p.
  25. 25. Hashimov, E. G., & Maharramov, R. R. (2025). Taking Control of Dead Zone of Radiolocation Station by the Automatic Acting Electro-Optic System. Defence Science Journal, 75(1). pp. 84-89, DOI : https://doi.org/10.14429/dsj.19950
  26. 26. Hashimov, E. G., Bayramov, A. A., & Khalilov, B. M. (2015). Operative detection of ground enemy objects. Herbi Bilik, (1), 33-47.
  27. 27. Hashimov, E., Sabziev, E., & Muradov, S. (2025). Development prospects and mathematical solution methods for integrating beacon systems into UAVs. Reliability: Theory & Applications, 20(SI 7 (83)), 66-73.
  28. 28. Ibrahimov, B. (2023). Investigation of Noise Immunity telecommunication systems according to the criterion energy efficiency. Transport and Telecommunication, 24(4), 375-384.
  29. 29. Ibrаhimov, B. G., & Hashimov, E. G. (2023). Research quality of functioning of the efficiency optical telecommunication systems using spectral technologies.
  30. 30. Islamov, I., Akhundov, R., Dimitrov, D., & Panevski, V. (2025). Modeling of a Circular Disk Monopole Antenna Fed from a Microwave Broadband Coplanar Waveguide. Advanced Physical Research, 7(2), 184-195. https://doi.org/10.62476/apr.72184.
  31. 31. Mammadov, E. V., Islamov, I. C., (2025). Development of effective personal protective equipment against radiation and chemical hazards. Current directions of development of information and communication technologies and control tools (Vol. 4, pp. 84–85). Baku–Kharkiv–Žilina: Impress. https://www.kpi.kharkov.ua/eng/
  32. 32. Mammadov, E. V., Islamov, I. C., (2025). Development of multilayered protection systems against chemical, radiological, and biological hazards for military personnel. Current directions of development of information and communication technologies and control tools (Vol. 1, pp. 112–113). Baku–Kharkiv–Žilina: Impress. https://www.kpi.kharkov.ua/eng/
  33. 33. Mammadov, E. V., Islamov, I. C., (2025). Eco-innovations and sustainable development in the military sector in the face of contemporary challenges. Current directions of development of information and communication technologies and control tools (Vol. 1, pp. 126–127). Baku–Kharkiv–Žilina: Impress. https://www.kpi.kharkov.ua/eng/
  34. 34. Mammadov, E. V., Islamov, I. C., (2025). Innovative technologies for radiological and chemical safety in military units. Current directions of development of information and communication technologies and control tools (Vol. 1, pp. 118–119). Baku–Kharkiv–Žilina: Impress. https://www.kpi.kharkov.ua/eng/
  35. 35. Mammadov, E. V., Islamov, I. C., (2025). The impact of military activities on the environment: Pathways for minimizing consequences. Current directions of development of information and communication technologies and control tools (Vol. 1, pp. 122–123). Baku–Kharkiv–Žilina: Impress. https://www.kpi.kharkov.ua/eng/
  36. 36. Piriyev, H., & Hashimov, E. (2023). Second Karabakh war: military-political and military-technical aspects // -Baku: Scientific Works of the Heydar Aliyev Military Institute. 1 (21). -
  37. pp. 7-16.
  38. 37. Rustamov, A., et al. (2025). Analysis of antenna system modeling with the help of simulation technology of navigation equipments. Advanced Information Systems, 9(2), 36–43. https://doi.org/10.20998/2522-9052.2025.2.05
  39. 38. Ахундов, Р. Г. (2024). Влияние военной деятельности на окружающую среду. Санкт-Петербург, 29(1), 51.
  40. 39. Ибрагимов, Б. Г. О., & Гасанов, А. Г. О. (2017). Исследование и оценка эффективности мультисервисных сетей NGN/IMS при передаче мультимедийных трафиков. T-Comm-Телекоммуникации и Транспорт, 11(2), 15-18.
  41. 40. Ибрагимов, Б. Г. О., Гасанов, А. Г. О., Алиева, А. А. К., & Исаев, А. М. О. (2019). Исследование показателей качества функционирования мультисервисных телекоммуникационных сетей на базе архитектурной концепции будущих сетей. Надежность и качество сложных систем, (1 (25)), 88-95.