Impacts of CO2 emissions on agriculture: Empirical evidence from Turkey

Yıl: 2020 Cilt: 37 Sayı: 1 Sayfa Aralığı: 33 - 43 Metin Dili: İngilizce DOI: 10.16882/derim.2020.700482 İndeks Tarihi: 07-12-2020

Impacts of CO2 emissions on agriculture: Empirical evidence from Turkey

Öz:
There are ongoing debates around the world regarding the effects of climate change on agriculture. All sectorsare known to be affected by climate change, and the agricultural sector is no exception. The present studyinvestigates the effects of climate change on agriculture in Turkey in the 1961-2018 period. In order to determinethe link between the variables, an Autoregressive Distributed Lag (ARDL) bounds testing approach to cointegration and Vector Autoregressive (VAR) analysis are applied. Results of the study show that CO2 emissionshave a significant impact on agriculture. Thus, as Turkey’s population increases, food sufficiency and security willemerge as more important issues over the next decade, it is vital to take adaptive measures to cope with climatechange and its impact on agriculture.
Anahtar Kelime:

CO2 emisyonlarının tarım üzerindeki etkileri: Türkiye örneği

Öz:
İklim değişikliğinin tarım üzerindeki etkileri konusunda dünya çapında devam eden tartışmalar bulunmaktadır. Tüm sektörlerin iklim değişikliğinden etkilendiği bilinmektedir ve tarım sektörü bu etkiden istisna değildir. Bu çalışma, iklim değişikliğinin Türkiye'de tarım üzerindeki etkilerini 1961-2018 dönemi için araştırmaktadır. Değişkenler arasındaki bağlantıyı belirlemek için, eş-bütünleşmeye bir gecikmesi dağıtılmış otoregresif (ARDL) sınır testi yaklaşımı ve vektör otoregresif (VAR) analiz uygulanmıştır. Çalışmanın sonuçları, CO2 emisyonlarının tarım üzerinde önemli bir etkiye sahip olduğunu göstermektedir. Dolayısıyla, Türkiye'nin nüfusu artışı ile beraber, gıda yeterliliği ve güvenliği önümüzdeki on yıl içinde daha önemli konular olarak ortaya çıkacak ve iklim değişikliğinin etkilerini göz önünde tutan önlemlerin alınması elzem olacaktır.
Anahtar Kelime:

Belge Türü: Makale Makale Türü: Araştırma Makalesi Erişim Türü: Erişime Açık
  • Abbas, F., & Choudhury, N. (2013). Electricity consumption-economic growth nexus: an aggregated and disaggregated causality analysis in India and Pakistan. Journal of Policy Modeling, 35(4):538-553.
  • Abid, M.E.A., Scheffran, J., Schneider, U.A., & Ashfaq, M. (2015). Farmers’ perceptions of and adaptation strategies to climate change and their determinants: the case of Punjab province, Pakistan. Earth System Dynamics, 6(1): 225-243.
  • Alam, Q. (2013). Climate change, agricultural productivity and economic growth in India: The bounds test analysis. International Journal of Applied Research and Studies, 2(11):1-14.
  • Ali, S., Liu, Y., Ishaq, M., Shah, T., Ilyas, A., & Din, I. U. (2017). Climate change and its impact on the yield of major food crops: Evidence from Pakistan. Foods, 6(6):39.
  • Amponsah, L., Kofi Hoggar, G., & Yeboah Asuamah, S. (2015). Climate change and agriculture: modelling the impact of carbon dioxide emission on cereal yield in Ghana. Agriculture and Food Sciences Research, 2:32-38.
  • Batten, D.S., & Belongia, M.T. (1986). Monetary policy, real exchange rates, and US agricultural exports. American Journal of Agricultural Economics, 68(2):422-427.
  • Bessler, D.A., & Babula, R.A. (1987). Forecasting wheat exports: do exchange rates matter? Journal of Business & Economic Statistics, 5(3):397-406.
  • Carter, C.A., Gray, R.S., & Furtan, W.H. (1990). Exchange rate effects on inputs and outputs in Canadian agriculture. American Journal of Agricultural Economics, 72(3):738-743.
  • Chambers, R.G., & Just, R.E. (1982). An investigation of the effect of monetary factors on agriculture. Journal of Monetary Economics, 9(2):235-247.
  • Chandio, A.A., Jiang, Y., Rehman, A., & Dunya, R. (2018). The linkage between fertilizer consumption and rice production: Empirical evidence from Pakistan. AIMS Agriculture and Food, 3(3):295-305.
  • Chandio, A.A., Jiang, Y., & Rehman, A. (2019). Energy consumption and agricultural economic growth in Pakistan: is there a nexus? International Journal of Energy Sector Management, 13(3):597-609.
  • Chandio, A.A., Jiang, Y., Rehman, A., & Rauf, A. (2020). Short and long-run impacts of climate change on agriculture: an empirical evidence from China. International Journal of Climate Change Strategies and Management. https://doi.org/10.1108/IJCCSM- 05- 2019-0026. Access date: 10/02/2020.
  • Cline, W.R. (2008). Global Warming and Agriculture: Impact Estimates by Country, Peterson Institute Press: All Books, Peterson Institute for International Economics, 4037.
  • Dong, K., Sun, R., & Dong, X. (2018). CO2 emissions, natural gas and renewables, economic growth: assessing the evidence from China. Science of the Total Environment, 640:293-302.
  • Godfray, H.C.J., Beddington, J.R., Crute, I.R., Haddad, L., Lawrence, D., Muir, J.F., Pretty, J., Robinson, S., Thomas, S.M., & Toulmin, C. (2010). Food security: the challenge of feeding 9 billion people. Science, 327(5967):812-818.
  • Huang, J.K. (2014). Climate change and agriculture: Impact and adaptation. Journal of Integrative Agriculture, 13(4):657-659.
  • Li, X., Takahashi, T., Suzuki, N., & Kaiser, H.M. (2011). The impact of climate change on maize yields in the United States and China. Agricultural Systems, 104(4):348-353.
  • Lobell, D.B., Cahill, K.N., & Field, C.B. (2007). Historical effects of temperature and precipitation on California crop yields. Climatic Change, 81(2):187-203.
  • Nelson, G.C., Rosegrant, M.W., Koo, J., Robertson, R.D., Sulser, T., Zhu, T., Ringler, C., Msang, S., Palazzo, A., Batka, M., Magalhaes, M., Valmonte-Santos, R., Ewing, M., Lee, D.R. (2009). Climate change: Impact on agriculture and costs of adaptation. Food Policy Report. International Food Policy Research Institute (IFPRI). http://dx.doi.org/10.2499/0896295354. Access date: 10/01/2020.
  • Orden, D., & Fackler, P.L. (1989). Identifying monetary impacts on agricultural prices in VAR models. American Journal of Agricultural Economics, 71(2):495-502.
  • Parry, M.L., Rosenzweig, C., Iglesias, A., Livermore, M., & Fischer, G. (2004). Effects of climate change on global food production under SRES emissions and socio-economic scenarios. Global Environmental Change, 14(1):53-67.
  • Phillips, P.C., & Loretan, M. (1991). Estimating longrun economic equilibria. The Review of Economic Studies, 58(3):407-436.
  • Spanos, A. (1990). The simultaneous-equations model revisited: Statistical adequacy and identification. Journal of Econometrics, 44(1- 2):87-105.
  • Sahinli, M.A. (2013). Pressures and risks to the agricultural environment: Turkey and EU countries. Journal of Animal and Veterinary Advances, 12:194-200.
  • Sahinli, M.A. (2019). Effects of agricultural supports: the case of Turkey. Journal of Environmental Protection and Ecology, 20(1):515-525.
  • Taylor, J.S., & Spriggs, J. (1989). Effects of the monetary macro-economy on Canadian agricultural prices. Canadian Journal of Economics, 278-289.
  • Wang, B., Sun, Y., & Wang, Z. (2018). Agglomeration effect of CO2 emissions and emissions reduction effect of technology: A spatial econometric perspective based on China's province-level data. Journal of cleaner Production, 204:96-106.
  • WDI (2020). https://datacatalog.worldbank. org/ dataset/world-development-indicators. Access date: 01/02/2020.
  • Xuab, H., Tianab, Z., Zhongc, H., Fan, D., Shic, R., Niubd, Y., Hee, X. & Chenf, M. (2017). Impacts of climate change on peanut yield in China simulated by CMIP5 multi-model ensemble projections. In Remote Sensing and Modeling of Ecosystems for Sustainability XIV (10405: 104050W). International Society for Optics and Photonics.
  • Zhang, J., Zhao, Y., Wang, C., & He, Y. (2006). Effects of climate change on winter wheat growth and yield in North China. Ying Yong Sheng Tai Xue Bao= The Journal of Applied Ecology, 17(7):1179-1184.
APA Pakdemirli B (2020). Impacts of CO2 emissions on agriculture: Empirical evidence from Turkey. , 33 - 43. 10.16882/derim.2020.700482
Chicago Pakdemirli Bekir Impacts of CO2 emissions on agriculture: Empirical evidence from Turkey. (2020): 33 - 43. 10.16882/derim.2020.700482
MLA Pakdemirli Bekir Impacts of CO2 emissions on agriculture: Empirical evidence from Turkey. , 2020, ss.33 - 43. 10.16882/derim.2020.700482
AMA Pakdemirli B Impacts of CO2 emissions on agriculture: Empirical evidence from Turkey. . 2020; 33 - 43. 10.16882/derim.2020.700482
Vancouver Pakdemirli B Impacts of CO2 emissions on agriculture: Empirical evidence from Turkey. . 2020; 33 - 43. 10.16882/derim.2020.700482
IEEE Pakdemirli B "Impacts of CO2 emissions on agriculture: Empirical evidence from Turkey." , ss.33 - 43, 2020. 10.16882/derim.2020.700482
ISNAD Pakdemirli, Bekir. "Impacts of CO2 emissions on agriculture: Empirical evidence from Turkey". (2020), 33-43. https://doi.org/10.16882/derim.2020.700482
APA Pakdemirli B (2020). Impacts of CO2 emissions on agriculture: Empirical evidence from Turkey. Derim, 37(1), 33 - 43. 10.16882/derim.2020.700482
Chicago Pakdemirli Bekir Impacts of CO2 emissions on agriculture: Empirical evidence from Turkey. Derim 37, no.1 (2020): 33 - 43. 10.16882/derim.2020.700482
MLA Pakdemirli Bekir Impacts of CO2 emissions on agriculture: Empirical evidence from Turkey. Derim, vol.37, no.1, 2020, ss.33 - 43. 10.16882/derim.2020.700482
AMA Pakdemirli B Impacts of CO2 emissions on agriculture: Empirical evidence from Turkey. Derim. 2020; 37(1): 33 - 43. 10.16882/derim.2020.700482
Vancouver Pakdemirli B Impacts of CO2 emissions on agriculture: Empirical evidence from Turkey. Derim. 2020; 37(1): 33 - 43. 10.16882/derim.2020.700482
IEEE Pakdemirli B "Impacts of CO2 emissions on agriculture: Empirical evidence from Turkey." Derim, 37, ss.33 - 43, 2020. 10.16882/derim.2020.700482
ISNAD Pakdemirli, Bekir. "Impacts of CO2 emissions on agriculture: Empirical evidence from Turkey". Derim 37/1 (2020), 33-43. https://doi.org/10.16882/derim.2020.700482