پژوهش های اقلیم شناسی

پژوهش های اقلیم شناسی

ارزیابی اثرات تغییراقلیم بر عملکرد محصول انگور دراستان خراسان رضوی با مدلهای CMIP6 (مطالعه موردی: قوچان، سبزوار و کاشمر)

نوع مقاله : مقاله پژوهشی

نویسندگان
علی اصغرزاده 1
غلامرضا جانبازقبادی 2
صدرالدین متولی 3
مجید طاهریان 4
منصوره کوهی 5
1 دانشجوی دکتری آب و هواشناسی واحد نور، نور، ایران
2 دانشیار آب و هواشناسی گروه جغرافیا دانشگاه آزاداسلامی واحدنور، نور، ایران
3 دانشیار جغرافیای طبیعی گروه جغرافیا واحد نور،نور،ایران
4 استادیار بخش تحقیقات و آموزش کشاورزی و منابع طبیعی خراسان رضوی سازمان تحقیقات آموزش و ترویج کشاورزی مشهد ایران
5 استادیار، پژوهشگاه هواشناسی و علوم جو ،پژوهشکده اقلیم شناسی و تغییر اقلیم، مشهد، ایران
10.22034/jcr.2025.211075
چکیده
این مطالعه به بررسی تأثیر تغییرات اقلیمی بر عملکرد محصول انگور در شهرستان‌های قوچان، سبزوار و کاشمر در استان خراسان رضوی می‌پردازد. با استفاده از مدل‌های CMIP6 تحت دو سناریو SSP2-4.5 و SSP5-8.5، روند تغییرات روزهای یخبندان و عملکرد محصول انگور تا پایان قرن حاضر شبیه‌سازی شد. نتایج نشان می‌دهد که روزهای یخبندان در هر سه منطقه به شدت کاهش خواهد یافت، به طوری که در کاشمر تحت سناریو SSP5-8.5 به حدود 0.36 روز در سال خواهد رسید. این کاهش، علی‌رغم تأثیرات مثبت احتمالی، می‌تواند منجر به اختلالات جدی در چرخه زندگی انگور شود. تحلیل روند عملکرد محصول با استفاده از آزمون من-کندال تصحیح شده و آزمون سن نشان داد که تحت هر دو سناریو، روند کاهشی معناداری در عملکرد محصول وجود دارد. این کاهش در سناریو SSP5-8.5 شدیدتر است، به طوری که پیش‌بینی می‌شود عملکرد محصول انگور در قوچان، سبزوار و کاشمر به ترتیب 32.8%، 21.5% و 38.75% کاهش یابد. عوامل متعددی در این کاهش عملکرد نقش دارند، از جمله تغییرات دمایی، اختلال در گرده‌افشانی، افزایش آسیب‌پذیری گیاهان نسبت به بیماری‌ها و آفات و تنش‌های محیطی ناشی از تغییرات اقلیمی. این یافته‌ها اهمیت اتخاذ استراتژی‌های سازگاری با تغییرات اقلیمی را در صنعت انگورکاری منطقه برجسته می‌کند. راهکارهایی چون انتخاب ارقام مقاوم‌تر، بهبود مدیریت باغات و استفاده از فناوری‌های نوین می‌تواند در کاهش اثرات منفی تغییرات اقلیمی مؤثر باشد. این مطالعه همچنین ضرورت انجام تحقیقات بیشتر در زمینه سازگاری ارقام مختلف انگور با شرایط اقلیمی جدید و همکاری نزدیک بین محققان، کشاورزان و سیاست‌گذاران را آشکار می‌سازد.
کلیدواژه‌ها
انگور
شبیه سازی عملکرد
مدل‌های CMIP6
استان خراسان رضوی

عنوان مقاله English

Evaluation of the effects of climate change on grape yield in Khorasan Razavi province with CMIP6 models (Case study: Qochan, Sabzevar and Kashmar)

نویسندگان English

Ali Asghar zadeh 1
Gholamreza gobadijanbaz 2
Sadroddin Motevalli 3
majid taherian 4
Mansoreh kooh 5
1 Ph.d student of hydrology and meteorology, Noor-Noor-Iran branch
2 Associate Professor of Hydrology and Meteorology, Department of Geography, Islamic Azad University, Noor Branchity-Noor.Iran.
3 Associate Professor of Natural Geography, Department of Geography, Noor Branch, Noor, Iran
4 Assistant Professor of Research and Education Department of Agriculture and Natural Resources, Khorasan Razavi, Organization of Research, Education and Extension of Agriculture, Mashhad, Iran
5 Assistant Professor, ,RIMAS, Climatology and Climate Change Research Institute, Mashhad, Iran
چکیده English

Introduction

Weather changes affect crops in different ways and indirectly change the prevalence and severity of pests and diseases; Therefore, it is necessary to adapt the agricultural system to the current scenario of climate change to provide more flexibility and ability to respond to farmers. Among these adaptations the prediction of the final production of the product, the identification of the most important effective factors and potential risk times. Razavi Khorasan, as one of the hubs of grape production in Iran, has a special importance in viticulture and the production of processed grape products. Considering the global climate changes and the increase in temperature and rainfall fluctuations, investigating the role of climate variables on the yield of grapes in this region is of great importance. Accurate knowledge of these effects provides the possibility of more accurate prediction of crop performance, optimal planning for farm management and taking appropriate measures to deal with the adverse effects of climate change.

Data and research method

The study area of this thesis is Khorasan Razavi province located in the northeast of Iran. Khorasan Razavi province is located between 56°19' to 61°16' east longitude and 33°52' to 37°42' north latitude, from the north to the country of Turkmenistan, from the east to Afghanistan, from the west and north The west is limited to the provinces of North Khorasan, Semnan and Yazd, and the south and southwest are limited to the provinces of South Khorasan and Yazd.

The data used are from three synoptic stations of Qochan, Sabzevar and Kashmar for the period 1990 to 2014 for temperature and precipitation variables.

Coupled models of the Sixth Phase Intercomparison Project (CMIP6)

The output of the sixth phase or CMIP6 models under common socio-economic scenarios (SSPs) along with the representative scenarios of greenhouse gas concentration on the analysis of feedbacks between climate changes and socio-economic factors such as global population growth, economic development and technological advances in are available In this research, MPI-ESM-HR model scaled with CMhyd model is used. Two intermediate (SSP2-4.5) and pessimistic (SSP5-8.5) scenarios have been used to examine limit profiles for three periods: the near future (2026-2050), the middle future (2025-2075), and the far future (2076-2100).

Results and discussion

Examining the available data from 1377 to 1399 shows that the area under grape cultivation was 4609 hectares in Qochan, 2210 hectares in Sabzevar and 8412 hectares in Kashmar. These statistics show that Kashmar city has the largest cultivated area with a significant difference compared to the other two cities. This issue could be due to more suitable climatic conditions or more supportive policies in this region. which indicates higher efficiency and better management of vineyards in this region. In general, according to the presented statistics, it can be concluded that Kashmar city has the highest cultivated area and crop yield, which indicates the high potential of this city for grape production. Quchan has a good yield despite the smaller cultivated area compared to Kashmir, which may be due to modern agricultural methods or better orchard management.

The analysis of the trend of cultivated area and yield of grapes in Qochan, Sabzevar and Kashmar cities of Khorasan Razavi province based on the statistical data of the Ministry of Agricultural Jihad during the period 1377 to 1399 shows significant changes that can help to better understand the agricultural situation in these areas. The results of the corrected Mann-Kendall test for the area under grape cultivation in these three cities are as follows. In Qochan, z-score equal to -1.33 and P-Value equal to 0.1819 were obtained, which indicates the non-significance of the trend at the 5% level. The value of the trend slope test has also shown a decrease in cultivated area with a slope of -32.66. In Sabzevar, the z-score is -0.21 and P-Value is 0.8261, which clearly indicates no significant change in the cultivated area. The value of the trend slope test is 3.31 hectares per year. Also, in Kashmar, the z-score is equal to 1.003 and P-Value is calculated equal to 0.3155, which means no significant change in the cultivated area with a slope of 10.64 hectares per year.

The results show that in the historical period, Qochan experienced 121.56 days, Sabzevar 66.84 days and Kashmar 24.04 days of frost. These statistics highlight the importance of frost as a key factor in reducing grape yield in these regions. Based on the results of the future forecasts, the frost days are decreasing with a steep slope under both scenarios. Specifically, by the end of this century, the number of freezing days for Kashmar is projected to reach 2.3 days under the SSP2-4.5 scenario and almost 0.36 days under the pessimistic SSP5-8.5 scenario.

conclusion

A comprehensive analysis of climate change and its effect on grape yield in Qochan, Sabzevar and Kashmar cities of Khorasan Razavi province shows a worrying trend that requires serious attention and preventive measures. Examining the changes in grape yield in the main growing areas of this crop in Khorasan Razavi province has shown that frost and severe cold in 2016 and 2018 were the main reason for the decrease in grape yield in Qochan, Kashmar and Sabzevar regions. In confirmation of the findings of this research, Lorenzo et al. (2012) also investigated the important role of temperature in the grape production cycle and showed that this climatic variable affects the quantity and especially the quality of grapes. Another study by van Leeuwen et al. (2019) in France showed that climate change can cause changes in the timing of grape phenological stages, which affects the quality and quantity of the crop. these findings can be compared with several similar international researches. In a study conducted by Ferreira et al. (2020) in Portugal, the impact of climate change on grape production in the Douro region was investigated. The results showed that an increase in temperature and a decrease in rainfall can lead to a 30-40% decrease in grape yield by 2050, which is consistent with the findings of the present study in Khorasan Razavi.

کلیدواژه‌ها English

grapes
yield simulation
CMIP6 models
Razavi Khorasan province
Alizadeh, A. , Babaeian, I. , Nouri,, H. and Najatian,, M. A. (2019). Investigating the Effect of Climate Change on the Production of White Seedless Grapes during(2020 -2050) by using the statistical Downscaling of the HadCM3 Model output (Case Study: Golmakan Station). Journal of Meteorology and Atmospheric Science, 2(3), 246-257.
Asgharzadeh, A. , janbazghobadi, G. , Motevalli, S. , Taheryan, M. and Koohi, M. (2024). Investigating the role of extreme climate profiles on grape yield(Case study: Qochan, Sabzevar and Kashmer). Irrigation and Water Engineering, 15(2), 143-163. doi: 10.22125/iwe.2024.463786.1814
Assembly, G. (2015). Resolution adopted by the General Assembly on 19 September 2016. A/RES/71/1, 3 October 2016 (The New York Declaration), Tech. Rep.
Atak, A. (2024). Climate change and adaptive strategies on viticulture (Vitis spp.). Open Agriculture9(1), 20220258.
Babaeian, I. , Modirian, R. , Khazanedari, L. , Karimian, M. , Kouzegaran, S. , Kouhi, M. , Falamarzi, Y. and Malbusi, S. (2023). Projection of Iran’s precipitation in 21st Century using downscaling of selected CMIP6 Models by CMHyd. Journal of the Earth and Space Physics, 49(2), 431-449. doi: 10.22059/jesphys.2023.332410.1007436
Bindi, M., Fibbi, L., Gozzini, B., Orlandini, S., & Miglietta, F. (1996). Modelling the impact of future climate scenarios on yield and yield variability of grapevine. Climate research, 7(3), 213-224.
Cardell, M. F., Amengual, A., & Romero, R. (2019). Future effects of climate change on the suitability of wine grape production across Europe. Regional Environmental Change, 19, 2299-2310.
Chaves, M. M., Flexas, J., & Pinheiro, C. (2003). Understanding the drought tolerance of grapevine: Contemporary challenges and future directions. Australian Journal of Grape and Wine Research, 9(2), 260-277.
Collins, J. K., Perkins-Veazie, P., & Roberts, W. (2006). Lycopene: from plants to humans.
DALLA MARTA, A., Grifoni, D., Mancini, M., Storchi, P., Zipoli, G., & Orlandini, S. (2010). Analysis of the relationships between climate variability and grapevine phenology in the Nobile di Montepulciano wine production area. The Journal of Agricultural Science, 148(6), 657-666.
 Eyring, V., Bony, S., Meehl, G. A., Senior, C. A., Stevens, B., Stouffer, R. J., & Taylor, K. E. (2016). Overview of the Coupled Model Intercomparison Project Phase 6 (CMIP6) experimental design and organization. Geoscientific Model Development, 9(5), 1937-1958.
 Ferreira, A. C., Pinto-Gomes, C., Ramos, M. C., & Jones, G. V. (2020). Modelling the effects of climate change on the viability and productivity of viticulture in the Portuguese Douro region. Journal of Wine Research,
31(1), 1-16.
Fraga, H., Malheiro, A. C., Moutinho‐Pereira, J., & Santos, J. A. (2012). An overview of climate change impacts on European viticulture. Food and Energy Security1(2), 94-110.
Hamed, K. H., & Rao, A. R. (1998). A modified Mann-Kendall trend test for autocorrelated data. Journal of hydrology, 204(1-4), 182-196.
Hegland, S. J., Nielsen, A., Lázaro, A., Bjerknes, A. L., & Totland, Ø. (2009). How does climate warming affect plant‐pollinator interactions?. Ecology Letters, 12(2), 184-195.
Hejabi, S., Abasalinezhad Sheramin, H., & Doulati Baneh, H. (2019). Effect of climate change on the phenology of "Bidaneh Sefid" table grape variety in West Azerbaijan province. Research in Pomology, 4(2), 43-52.
Helalili , J., Rasouli, M. ().Plants Protection From Frost And Chilling,
Hidalgo, L. (1999). Tratado de Viticultura General (Mundi-Prensa: Madrid, Spain).
Honorio, F., García‐Martín, A., Moral, F. J., Paniagua, L. L., & Rebollo, F. J. (2018). Spanish vineyard classification according to bioclimatic indexes. Australian journal of grape and wine research, 24(3), 335-344.
Jones, G. V. (2006). Climate and terroir: impacts of climate variability and change on wine. Geoscience Canada Reprint Series, 9, 203-217.
Jones, G. V. (2007). Climate change and grape quality: Implications and strategies for the wine industry. Australian and New Zealand Wine Industry Journal, 22(1), 60-66.
Keller, M. (2010). The science of grapevines: Anatomy and physiology. Academic Press.
Keller, M. (2023). Climate Change Impacts on Vineyards in Warm and Dry Areas: Challenges and Opportunities: From the ASEV Climate Change Symposium Part 1–Viticulture. American Journal of Enology and Viticulture74(2).
Kendall, M. G. (1948). Rank correlation methods.
Mann, H. B. (1945). Nonparametric Tests Against Trend. Econometrica, 13(3), 245-259.
Mekanik, F., Asadi, H., & Talebi, A. A. (2013). Evaluation of climate change impacts on crop yield: A case study of wheat in Iran. Agricultural Water Management, 124, 133-141.
Mendez, M., Maathuis, B., Hein-Griggs,  D., & Alvarado-Gamboa, L. F. 2020,  Performance evaluation of bias  correction methods for climate change  monthly precipitation projections over  Costa Rica: Water, 12(2), 482.
 O'Neill, B. C., Kriegler, E., Riahi, K., Ebi, K. L., Hallegatte, S., Carter, T. R., ... & van Vuuren, D. P. (2014). A new scenario framework for climate change research: The concept of shared socioeconomic pathways. Climatic Change, 122(3), 387-400.
Ortega, E., Dicenta, F., & Egea, J. (2007). Rain effect on pollen–stigma adhesion and fertilization in almond. Scientia Horticulturae, 112(3), 345-348.
Ponti, L., Gutierrez, A. P., Boggia, A., & Neteler, M. (2018). Analysis of grape production in the face of climate change. Climate6(2), 20.
Räty, O., Räisänen, J., & Ylhäisi, J. S. 2014, Evaluation of delta change and  bias correction methods for future  daily precipitation: intermodel cross- validation using ENSEMBLES  simulations: Climate dynamics, 42(9- 10), 2287-2303.
Rogiers, S. Y., Greer, D. H., Liu, Y., Baby, T., & Xiao, Z. (2022). Impact of climate change on grape berry ripening: An assessment of adaptation strategies for the Australian vineyard. Frontiers in Plant Science13, 1094633.
Shojaee, T. , Fallah Ghalhari, G. A. and Kashki, A. (2020). Effects of Climate Change on Grape Tree Phenological Date Change in Iran. Physical Geography Research, 52(1), 129-145. doi: 10.22059/jphgr.2020.284132.1007404
Smith, J. A., & Doe, R. B. (2023). Statistical evaluation of data homogeneity in meteorological stations using the Standard Normal Homogeneity Test (SNHT). Journal of Climate Analysis, 45(3), 123-137.
Sobhani, B. (2024). Assessment of effective climatic elements and factors on grape crop cultivation using ARAS, AHP and WLC methods (Case study: Meshgin Shahr region). Geography and Human Relationships, 6(4), 606-623. doi: 10.22034/gahr.2023.431274.2010
Stolzenberg, L. (2004). Regression modeling: Basic concepts. In G. Arminger, C. Clogg, & C. Sobel (Eds.), Handbook of statistical modeling for the social and behavioral sciences (pp. 1-37). Springer.
 van Leeuwen, C., Destrac-Irvine, A., Dubernet, M., Duchêne, E., Gowdy, M., Marguerit, E., ... & Ollat, N. (2019). An update on the impact of climate change in viticulture and potential adaptations. Agronomy, 9(9), 514.
Webb, L. B., Watterson, I., Bhend, J., Whetton, P. H., & Barlow, E. W. R. (2018). Global climate analogues for winegrowing regions in future periods: temperature and precipitation projections. Australian Journal of Grape and Wine Research, 24(2), 143-156.
Zarrin, A. and Dadashi Roudbari, A. A. (2020). Projection the Long-Term Outlook Iran Future Temperature Based on the Output of The coupled model intercomparison project phase 6 (CMIP6). Journal of the Earth and Space Physics, 46(3), 583-602. doi: 10.22059/jesphys.2020.304870.1007226
Zhang, T., He, Y., DePauw, R., Jin, Z., Garvin, D., Yue, X., ... & Yang, X. (2022). Climate change may outpace current wheat breeding yield improvements in North America. Nature communications13(1), 5591.
پژوهش های اقلیم شناسی
دوره 1403، شماره 59 - شماره پیاپی 59
سال پانزدهم| شماره 59| پاییز 1403
زمستان 1403
صفحه 161-180