پژوهش ها و چشم اندازهای اقتصادی

پژوهش ها و چشم اندازهای اقتصادی

بررسی تأثیر بلایای طبیعی بر امنیت انرژی در ایران

نویسندگان
پروین علی مرادی افشار 1
وحید عزیزی 2
سمیه فاتحی 3
1 استادیار، گروه علوم اقتصادی، دانشکدۀ علوم انسانی و اجتماعی، دانشگاه کردستان، سنندج، ایران
2 دانشجوی کارشناسی‌ارشد اقتصاد نظری، گروه علوم اقتصادی، دانشکدۀ علوم انسانی و اجتماعی، دانشگاه کردستان، سنندج، ایران
3 دانشجوی کارشناسی‌ارشد اقتصاد انرژی، گروه علوم اقتصادی، دانشکدۀ علوم انسانی و اجتماعی، دانشگاه کردستان، سنندج، ایران
10.22034/24.3.31
چکیده
درحال حاضر، توسعه اقتصادی و رفاه عمومی بدون داشتن منابع انرژی مطمئن و پایدار امکان‌پذیر نیست. بنابراین، تأمین امنیت انرژی از اولویت‏های اساسی هر جامعه و حکومتی به‌شمار می‏رود. از طرفی امنیت انرژی ارتباط تنگاتنگی با زندگی و فعالیت‏های تولیدی انسان دارد و به‌شدت با افزایش تعداد رویدادهای شدید طبیعی مرتبط است. بنابراین این پژوهش با هدف بررسی تأثیر بلایای طبیعی بر امنیت انرژی در ایران، طی دوره زمانی (1980 تا 2018) انجام شده است. جهت برآورد مدل و ارائۀ نتایج از روش اقتصادسنجی حداقل مربعات کاملاً اصلاح‌شده (FMOLS) استفاده شد. براساس نتایج این مطالعه متغیرهای باز بودن تجارت و رشد اقتصادی تأثیرات نامطلوبی بر امنیت انرژی دارد. شاخص صنعتی شدن، نوآوری تکنولوژیک و نرخ رشد شهرنشینی اثر مثبت و معنی‏داری بر امنیت انرژی دارد. با توجه به هدف اصلی تحقیق نتایج نشان می‏دهد که با افزایش تعداد بلایای طبیعی، امنیت انرژی کاهش می‏یابد. یافته‌های این مطالعه می‌تواند مرجعی برای لزوم ارتقای مدیریت انرژی باشد.
کلیدواژه‌ها
امنیت انرژی
بلایای طبیعی
حداقل مربعات کاملاً اصلاح‌شده

موضوعات

عنوان مقاله English

Natural Disasters and Energy Security in Iran

نویسندگان English

parvin alimoradi afshar 1
vahid azizi 2
Somayeh fatehi 3
1 Assistant Professor of Economics, Department of Economic Sciences, Faculty of Humanities and Social Sciences, University of Kurdistan, Sanandaj, Iran
2 M.A. Student in Theoretical Economics, Department of Economic Sciences, Faculty of Humanities and Social Sciences, University of Kurdistan, Sanandaj, Iran
3 . M.A. Student in Energy Economics, Department of Economic Sciences, Faculty of Humanities and Social Sciences, University of Kurdistan, Sanandaj, Iran
چکیده English

Introduction

In recent years, economic development and public welfare are not possible without reliable and sustainable energy sources. Therefore, providing energy security is one of the basic priorities of every society and government. On the other hand, energy security is closely related to human life and productive activities and is strongly related to the increase in the number of extreme natural events in the past decades. Natural disasters can have different effects on energy consumption depending on the type of disaster and the desired energy source. Emergency food products can be useful for disaster situations, and carbon absorption is one of the solutions that can greatly reduce greenhouse gas emissions. The search for better energy performance of buildings and the using alternative sources of energy along with the rationalization of energy consumption can be directly related to reducing emission levels in the atmosphere and alleviating detrimental impacts on the environment. However, the transition to renewable energy sources requires careful planning and implementation to ensure energy security and prevent negative environmental effects, natural disasters also have significant implications for energy security, extreme weather events such as droughts and floods can affect the availability and reliability of energy resources, especially hydropower. Therefore, it is crucially important to consider the potential effects of climate change on energy systems and to develop adaptation strategies for ensuring energy security. Therefore, dealing with climate change and energy security are two critical challenges of any society today. Transitioning to renewable energy sources can reduce climate change, but requires careful planning and implementation to ensure energy security. In addition, it is vital to consider the potential impacts of climate change on energy systems and develop adaptation strategies to ensure energy security. Therefore, dealing with and managing severe natural disasters is necessary to ensure and manage energy security. Therefore, considering the importance of energy security on the one hand and limited research on the other to depict the impact of extreme natural events on energy security is of paramount importance. Therefore, considering the increasing frequency of natural disasters and energy security, how natural disasters affect energy security needs to be debated which has rarely been addressed yet. So, the aim of this research is to fill this theoretical gap so that the impact of severe natural hazards on energy security from a theoretical point of view to be investigated and solutions for diminishing the impact of natural disasters on energy security proposed.

Methodology

In this research, due to the fact that the degree of significance of all research variables was of the first order and with the difference of the first order of significance, to estimate the research model, it is possible to use co-accumulation methods to avoid creating false regression and misleading results. In econometric literature, various methods are introduced to check the existence of long-term relationship between variables. Therefore, this research uses Fully Modified Least Squares (FMOLS) cointegration method to estimate the research model. The fully modified least squares method by Phillips and Hansen (1990) to examine long-run relationships and estimate a co-integrated relationship that has a combination of I(1) was introduced and developed. This method uses a quasi-parametric correction to eliminate problems caused by long-term correlation between co-accumulation equations and changes in random variables. Characteristics of this estimator; They are highly consistent and asymptotically distributed normally without skew and provide better results in small samples. It also provides modified standard deviation that allows statistical inferences to be made. In fact, the fully modified least squares method applies two corrections of distortion and endogeneity to the ordinary least squares method. On the other hand, the FMOLS method is not affected by the length of the interval and is asymptotically unbiased and has a fully efficient combination of asymptotes when all variables are endogenous. In fact, by means of this method, an optimal estimate of the cointegration vector can be estimated.

Findings

In this study, for the first time, the effect of severe natural disasters on the risk of energy security in Iran during the period (1980-2018) have been examined. To estimate the model, fully modified least squares (FMOLS) method was used. According to the variable results, severe natural disasters have a negative and significant effect on energy security in Iran, which is in agreement with the results of the research by Qiu et al. (2023), Lee et al. (2021), Rakshit (2021), Wei et al. 2022). Open degree index without trade has a negative and significant effect on energy security during the studied period, which confirms the results of Qiu et al. (2023), Wei et al. (2023) and Lee and Park (2021) studies. The industrialization index has a positive and significant effect on energy security in Iran, and the results of this section agree with the results of Qiu et al. (2023) research. The growth rate of urbanization also has a positive and significant effect on energy security during the studied period, which rejects the results of Qiu et al. (2023) study. Technological innovation has a positive and significant effect on energy security. Financial development had no significant effect on energy security. The GDP variable has a negative and significant effect on energy security. The results of this section are contrary to the research results of Qiu et al. (2023) and Lee and Park (2021) and are consistent with the research results of Wei et al. (2023).

Discussion and Conclusion

Natural disasters are an inevitable part of life that threaten different aspects of human life. Natural disasters may create some long-term social, economic and environmental trends in the society, whose effects have economic consequences for the country for decades. The position of natural disasters and its effect on other variables in a disaster-prone country like Iran should be given special attention. Natural disasters should be a gateway to a scientific, strategic and accurate look at these events and their social, political and economic consequences. Increased investment in infrastructure and mechanisms related to crisis prevention and management, and serious attention should be paid to basic indicators such as trust and political legitimacy to facilitate the functioning of the government in crisis conditions. The results of this study show that policy makers should pay enough attention to natural environment, especially natural disasters in planning agenda to improve energy security so that appropriate policy interventions can help deminish the impact of extreme natural events on energy security.

Policy recommendations

Paying attention to environmental issues to face natural disasters has become public knowledge in different societies. In terms of energy security, the following recommendations are suggested for Iran which is located in a dry and semi-arid climate and faces serious limitations:

Providing sufficient credits by promoting cooperation with international organizations. Lack of credits is one of the main obstacles to the implementation of legal articles approved in the development programs and advancing the goals set in the field of environmental issues of the country.
Adopting the approach of comprehensive and integrated management of the environment. In Iran varied organizations and institutions are involved with the environmental issues and none are fully responsible for it. Environmental Protection Organization, Forests and Ranges and Watershed Organization, Water Department of the Ministry of Energy, and the Iranian Fisheries Organization are each responsible for a part of environmental concerns with no mechanism for coordination between them.
Promotion of culture and environmental literacy of society to strengthen the spirit of cooperation of citizens with environmental policies.

Application of greenhouse gas emission management policies in the country.

کلیدواژه‌ها English

Energy Security
Natural Disasters
Fully Modified Least Squares
Ang, B., Choong, W., Ng, T., (2015). A framework for evaluating Singapore’s energy security. Appl. Energy 148, 314 325.http://dx.doi.org/10.1016/j.apenergy. 2015.03.088.
Augutis, J., Krikštolaitis, R., Martišauskas, L., Pečiulyte˙ , S., Žutautaite˙ , I., (2017). Integrated energy security assessment. Energy 138, 890–901.http://dx.doi. org/10.1016/j.energy.2017.07.113.
Ayodele, B. V., Mustapa, S. I., Mohammad, N., & Shakeri, M. (2021). Long-term energy demand in Malaysia as a function of energy supply: A comparative analysis of nonlinear autoregressive exogenous neural networks and multiple non-linear regression models. Energy Strategy Reviews, 38, Article 100750. https://doi.org/10.1016/ j.esr.2021.100750
Ayres, R. and Nair, I. (1984) ‘Thermodynamics and economics’, Physics Today, Vol 35, 1984, pp 62-71.
Azzarri, C., & Signorelli, S. (2020). Climate and poverty in Africa South of the Sahara. World Development, 125, 104691.
Babonneau, F., Kanudia, A., Labriet, M., Loulou, R., Vial, J. (2012). Energy Security: A Robust Optimization Approach to Design a Robust Asia. Asian Development Bank Economics Working Paper Series, (399), 17–14.
Bamisile, O., Ojo, O., Yimen, N., Adun, H., Li, J., Obiora, S., Huang, Q. (2021). Comprehensive functional data analysis of China’s dynamic, energy security index, Energy Reports, Volume 7, November 2021, Pages 6246-6259
Behrens, A., Egenhofer, C., & Checchi, A. (2009). Long-term energy security risks for europe: a sector-specific approach. CEPS Working Documents 309, Centre for European Policy Studies, Brussels, Belgium. International Energy Agency
Berndt, E. R. (1978) ‘Aggregate energy, efficiency, and productivity measurement’, Annual Review of Energy, Vol 3, 1978, pp 225-273.
Chandra Voumik, L., & Sultana, T. (2022). Impact of urbanization, industrialization, electrification and renewable energy on the environment in BRICS: Fresh evidence from novel CS-ARDL model. Heliyon, 8(11), Article e11457. https://doi.org/ 10.1016/j.heliyon. 2022.e11457.
Chen, P., Wu, Y., Meng, J., He, P., Li, D., Coffman, D. M., Liang, X., & Guan, D. (2022). The heterogeneous role of energy policies in the energy transition of Asia–Pacific emerging economies. Nature Energy, 9.
Chu, L. K., Ghosh, S., Do_gan, B., Nguyen, N. H., & Shahbaz, M. (2023). Energy security as new determinant of renewable energy: The role of economic complexity in top energy users. Energy, 263, Article 125799. https://doi.org/10.1016/j.energy.2022.125799
Dahmardeh, N., Safdari, M., & Shahiki Tash, M. (2010). The Effect of Macroeconomic Indices on Income Distribution in Iran. Iranian Journal of Trade Studies, 14(54), 25-55. (In Persian)
Doytch, N., & Klein, Y. L. (2017). The impact of natural disasters on energy consumption: An analysis of renewable and nonrenewable energy demand in the residential and industrial sectors. Environmental Progress & Sustainable Energy, 37(1), 37–45. https://doi.org/10.1002/ep.12640
Dyer Hugh, Trombetta Maria Julia (2013), International Handbook of Energy Security, Cheltenham, Edward Elgar Publishing.
Hafezi, R., Souhankar, A. (2023). Energy Security in a Resource-Rich Economy: Case of Iran. The Handbook of Energy Policy, pp 1–31
Haghighat, J., & Akbar Mousavi, S. (2022). Advanced applied econometrics, second edition, Tehran: Noor Alam Publications. (In Persian)
Kalkuhl, M., & Wenz, L. (2020). The impact of climate conditions on economic production. Evidence from a global panel of regions. Journal of Environmental Economics and Management, 103, 102360. https://doi.org/10.1016/j.jeem.2020.102360
Imamqolipour Sefid Dashti, S. (2014). The economics of natural disasters. Tehran: Noore Elm
Karasoy, A. (2022). Is innovative technology a solution to Japan's long-run energy insecurity? Dynamic evidence from the linear and nonlinear methods. Technology in Society, 70, Article 102029. https://doi.org/10.1016/j.techsoc.2022.102029
Kanani maman, Y. (2018). The framework of Energy security impact on the optimal energy supply models based on scenario and stochastic models. Strategic Studies of public policy, 8(27), 49-66.
Kelly-Pitou, K., Ostroski, A., Contino, B., Grainger, B. M., Kwasinski, A., & Reed, G. F. (2017). Microgrids and resilience: Using a systems approach to achieve climate adaptation and mitigation goals. The Electricity Journal, 30(10), 23–31. https://doi.org/10.1016/j.tej.2017.11.008
Kuik, Onno, 2003. " Climate change policies, energy security and carbon dependency: trade-offs for the European :union: in the longerterm, " International Environmental Agreements: Politics, Law and Economics 3: 221–242, 2003.
Kundu, D., Dutta, D., Samanta, P., Dey, S., Sherpa, K. C., Kumar, S., & Dubey, B. K. (2022). Valorization of wastewater: A paradigm shift towards circular bioeconomy and sustainability. Science of the Total Environment, 848, Article 157709. https://doi.org/ 10.1016/j.scitotenv.2022.157709
Le, T. H., & Park, D. (2021). What drives energy insecurity across the world? A panel data analysis. Energy Research & Social Science, 77 (2021), Article 102093. https://doi.org/ 10.1016/j.erss.2021.102093
Le, T.-H., & Nguyen, C. P. (2019). Is energy security a driver for economic growth? Evidence from a global sample. Energy Policy, 129, 436–451.
Lee, C. C., & Wang, C. (2022). Financial development, technological innovation and energy security: Evidence from Chinese provincial experience. Energy Economics, 112, Article 106161. https://doi.org/10.1016/j.eneco.2022.106161
Lee, C. C., Yuan, Z., & Wang, Q. (2022). How does information and communication technology affect energy security? International evidence. Energy Economics, 109, Article 105969. https://doi.org/10.1016/j.eneco.2022.105969
Lee, C., Wang, C. W., Ho, S. J., & Wu, T. (2021). The impact of natural disaster on energy consumption: International evidence. Energy Economics, 97, 105021. https://doi.org/10.1016/j.eneco.2020.105021
Li, B., & Haneklaus, N. (2022). The potential of India's net-zero carbon emissions: Analyzing the effect of clean energy, coal, urbanization, and trade openness. Energy Reports, 8, 724–733. https://doi.org/10.1016/j.egyr.2022.01.241
Li, P., & Zhang, J. (2019). Is China's energy supply sustainable? New research model based on the exponential smoothing and GMM (1,1) methods. Energies, 12(2), 236. https://doi.org/10.3390/en12020236
Lin, B., Raza, M.Y. (2020) Analysis of energy security indicators and CO2 emissions. A case from a developing economy. Energy, 200, 117575.
Liu, J., Li, X., & Zhong, S. (2022). Does innovation efficiency promote energy consumption intensity? New evidence from China. Energy, Reports, 8, 426–436. https://doi.org/10.1016/j.egyr.2022.05.096
Ma, B., & Yu, Y. (2017). Industrial structure, energy-saving regulations and energy intensity: Evidence from Chinese cities. Journal of Cleaner Production, 141, 1539–1547. https://doi.org/10.1016/j.jclepro.2016.09.221
Milošević, Z., Veskovic, M., Gavrilov, M. B., Lukić, T., & Marković, S. B. (2013). Using natural disasters to instigate radical policy changes – the effect of Fukushima nuclear power plant accident on nuclear energy policies. Acta Geographica Slovenica, 53(1), 181–189. https://doi.org/10.3986/ags53303
Mohammadi, T., & NabiZadeh, A. H. (2013). Investigating the Relationship between Real Exchange Rate Misalignment and Imports of Intermediate-Capital and Consumer Goods in Iran. Economics Research, 13(51), 113-149. (In Persian)
Murshed, M. (2021). Can regional trade integration facilitate renewable energy transition to ensure energy sustainability in South Asia? Energy Reports, 7, 808–821. https://doi.org/10.1016/j.egyr.2021.01.038
Nepal, R., Paija, N., Tyagi, B., & Harvie, C. (2021). Energy security, economic growth and environmental sustainability in India: Does FDI and trade openness play a role? Journal of Environmental Management, 281, Article 111886. https://doi.org/10.1016/ j. jenvman.2020.111886
NOAA (2022) Climate change impacts. National Oceanic and Atmospheric Administration. https://www.noaa.gov/education/resource-collections/climate/climate-change-impacts
Owusu, P. A., & Sarkodie, S. A. (2016). A review of renewable energy sources, sustainability issues and climate change mitigation. Cogent Engineering, 3(1), 1167990. https://doi.org/10.1080/23311916.2016.1167990
Phillips, P. C. B. & Hansen, B. (1990). “Statistical Inferences in Instrumental Variables Regression with I(1) Processes”. The Review of Economic Studies, 57(1), 99-125.
Qiu, L., Wang, X., Wei, J. (2023). Energy security and energy management: The role of extreme natural events, Innovation and Green Development, 2 (2): June 2023, 100051, 1 – 9
Rakshit, B. (2021). Impact of natural disasters on energy consumption: evidence from Indian states. Energy Research Letters, 2(3). https://doi.org/10.46557/001c.27017
Rehman, S. A. U., Cai, Y., Fazal, R., Das Walasai, G., & Mirjat, N. H. (2017). An integrated modeling approach for forecasting long-term energy demand in Pakistan. Energies, 10(11). https://doi.org/10.3390/en10111868. Article 11.
Santos, A. J. L., & Lucena, A. F. (2021). Climate change impact on the technical-economic potential for solar photovoltaic energy in the residential sector: a case study for Brazil. Energy and Climate Change, 2, 100062. https://doi.org/10.1016/j.egycc.2021.100062
Soleimani, Y(2022), Scientific Monthly "Economic Security", research paper, 10th year, 3rd issue (consecutive 98, June 1401, pp. 65-74) Energy security considerations regarding the summit Global Environment Glasgo
Sovacool, B. K. (2014). Environmental issues, climate changes, and energy security in developing European Energy Supply via TIAM-WORLD. Environmental Modeling & Assessment, 17, 19–37 (https://doi.org/10.1007/s10666-011-9273-3
Stern, D.I. (1993). Energy and economic growth in the U.S.A., A multivariate approach, Energy Economics 15, 37- 150.
Tashkini, A. (2006). Applied Econometrics with the Microfit. Tehran: Tehran Dibagaran Publications . (In Persian)
Tete, K. H. S., Soro, Y. M., Sidib_e, S. S., & Jones, R. V. (2023). Assessing energy security within the electricity sector in the West African economic and monetary :union:: Intercountry performances and trends analysis with policy implications. Energy Policy, 173, Article 113336. https://doi.org/10.1016/j.enpol.2022.113336
Tippee, B. (2012). “Defining Energy Security”, Oil and Gaz Journal, Available at: 1c/regular-features/journally-speaking/defining-energy-security.html, (06.07.2014).
پژوهش ها و چشم اندازهای اقتصادی
دوره 24، شماره 3
پاییز 1403
صفحه 31-60