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jems H, maleki S, nasiri A, derikvand S. Evaluation and investigation of the effect of desert dust on quantitative and qualitative yield of Thomson oranges. Journal of Spatial Analysis Environmental Hazards 2023; 10 (1) :41-56
URL: http://jsaeh.khu.ac.ir/article-1-3366-en.html
1- , abuzarnasiri@gmail.com
Abstract:   (2044 Views)
1- Introduction
Desert dust is formed under the influence of the special weather and environmental conditions of desert areas, enter the atmosphere. Localized hurricanes caused by ground air instability and sweeping dry deserts clear silt and sand particles enter the atmosphere from the surface. Ecologically as well as physically desert dust Effects such as pulmonary heart disease, disruption of plant physiological circulation, and erosion of growing structures include heavy metals deposited on soil surfaces, water surfaces, and canopies Plant surfaces that cause chemical changes and physiological damage to environmental ecosystems. Difficult Metal generally refers to a group of metal elements with a specific gravity of 6g/cm3 or more. Atomic weight greater than 50 g. Heavy metals important from an environmental point of view Cadmium, arsenic, cobalt, vanadium, zinc, mercury, iron, manganese, nickel, lead, chromium, copper, that do not decompose naturally. In addition, the long life of heavy metals is also considered. In the studies that have investigated the effect of dust on citrus fruits, it has been very few and even garden plants have been done on a case-by-case and limited basis. Citrus and especially oranges are one of the important and economic garden products in Iran, which are cultivated in tropical areas with mild and cold winters. Khuzestan plain, especially Dezful, is one of the poles of citrus and orange cultivation. But in Khuzestan, it is under the influence of many environmental stresses, which can be mentioned as drought stress and air pollution in the region. The rising trend of the phenomenon of desert dust in recent years has been shown as a danger and its effect on the environmental health and economy of the region is very severe, and the most damage has been reported to the agricultural sector. Although the damage caused by micro-pollens to the agricultural sector is expressed as an economic figure, the effect on plants, especially citrus fruits, remains unknown. Although researchers have studied the effect of fine dust on sugarcane, grapes, legumes, nectarines and peaches in Iran, India and Pakistan, the effect of fine dust on vegetative traits and orange fruit has not been investigated in Khuzestan. Considering that the first step in controlling the effect of air pollution on plants and horticultural crops is to know how it affects the plant, on this basis, the main goal of the current research is to reveal and evaluate the effect of micro-pollens. Desert is on vegetative and reproductive characteristics of Thomson orange in Dezful.


2- Methodology
In order to evaluate the effect of desert pollen on the quantitative and qualitative yield of orange fruit, Thomson variety, a field experiment in the form of randomized complete block design with four treatments and three replications was carried out in Dezful in 2018-2019. The treatments included 1) road dust and desert fine dust, 2) desert fine dust, 3) washing after the occurrence of fine dust and 4) control away from fine dust. The chemical and functional characteristics of the trees were measured after applying the treatments, which included chlorophylls a and b, relative water content of the leaves, number of fruits, diameter and weight of the fruit, soluble solids of the fruit and the final yield of the tree.

3- Results
The results showed that chlorophyll a decreased by 21% and 11%, respectively, in the road dust and desert fine dust treatments compared to the control. Chlorophyll b also decreased to the same amount compared to the control. The diameter of the fruit also decreased by 20% in the desert dust treatment compared to the control. The number of fruits per tree also decreased by 22 and 20% in the treatments of pollen and fine desert dust compared to the control. In the product yield of each tree, in the treatments of road dust combined with desert fine dust and the second treatment, which was only desert fine dust, it decreased by 22 and 17 percent, respectively, compared to the control. Tukey's mean comparison showed that the difference of all quantitative and qualitative characteristics between the treatments was significant and Desert dust has a negative and decreasing effect on the yield of Thomson orange trees; However, washing the trees after the occurrence of micro-pollen removed the effects of micro-pollen on the performance of trees and it even increased compared to the control; So, washing increased the yield of oranges by 40, 35, and 12 percent compared to the first and second treatments of road dust and fine dust, as well as the control.

4- Discussion & Conclusions
Plant growth cycle and biochemical interactions of plants show different reactions under the influence of environmental stresses. The results of previous studies indicated that fine dust and dust storms have been identified as an environmental stress for plants that have a negative effect on grapes, medicinal plants, sugarcane, nectarines, peaches and legumes. The effect of fine dust on the plant can be investigated in several characteristics and periods of plant phenology. In the first stage, the deposition of desert fine dust on the leaves of the plant causes shading and reducing the light received by the leaf pigments. Fruit formation is the most important phenological period of the plant, and the occurrence of environmental stress can affect the yield and products of the plant. The present research showed that the number of fruits in orange trees showed sensitivity to desert pollen and the settling of soil particles on orange flowers reduced the amount of fruit formation and finally the number of healthy and ripe fruits in the trees treated with road dust and Desert fine dust decreased compared to the control. Finally, the yield of control orange trees decreased by 17% and 22%, respectively, compared to desert dust and road dust treatment with desert dust. The yield of cotton plants in China decreased by about 28% compared to Desert dust. It can be concluded that although desert dust and road dust reduce the yield of Thomson orange fruit, washing it compensates for the damage and will be economical from the economic point of view.

Key words: Citrus, Photosynthetic pigments, Fruit yield, Dust, Dezful

 
Full-Text [PDF 611 kb]   (1140 Downloads)    
Type of Study: Research | Subject: Special
Received: 2023/02/12 | Accepted: 2023/06/20 | Published: 2023/10/4

References
1. ) آروین، عباسعلی؛ صدیقه چراغی و شهرام چراغی. 1392. بررسی تأثیر گردوغبار بر روند کمی و کیفی رشد نیشکر واریته CP57-614. مجله پژوهش‌های جغرافیای طبیعی، 45: 95-106.
2. 2) بهروزی، محمود؛ سعید بازگیر، حمید نوری، محمدعلی نجاتیان و داود اخضری. 1398. شناسایی کانون‌های گردوغبار و بررسی اثرهای آن بر برخی صفات رویشی و زایشی انگور در دشت ملایر. نشریه مهندسی اکوسیستم بیابان، 8: 72-59.
3. 3) بهروزی، محمود؛ سعید بازگیر، حمید نوری، محمدعلی نجاتیان و داود اخضری. 1396. کاهش اثر گردوخاک بر خصوصیات کمی و کیفی انگور رقم بی‌دانه سفید در اثر شستشو با دی‌اکتیل، نشریه تولیدات گیاهی، 40: 125-113.
4. 4) تراهی، عزیز و کاظم ارزانی. 1396. مطالعه اثرات گردوغبار بر گرده‌افشانی و میوه نشینی نخل خرما (Phoenix dactylifera L.). مجله تولیدات گیاهی (مجله علمی کشاورزی)، 40: 63-74.
5. 5) شهبازی، طیبه؛ محسن سعیدی، هنرمند سعید جلالی و ایرج نصرتی. 1395. بررسی اثر ریزگردها بر خصوصیات فیزیولوژیک و عملکرد ارقام مختلف گندم. فرایند و کارکرد گیاهی، 5: 195-203.
6. 6) صلاحی، برومند و محمود بهروزی. 1399. بررسی اثر ریزگردهای بیابانی بر صفات رویشی و عملکرد انگور عسکری در شیراز. نشریه تحلیل فضایی مخاطرات محیطی، 7: 152-135.
7. 7) فعله کری، حمزه؛ محمد اقبال قبادی، مختار قبادی، سعید جلالی هنرمند، و محسن سعیدی. 1396. تأثیر رسوب ریزگردها بر عملکرد و اجزاء مختلف نخود در شرایط آبیاری تکمیلی و دیم کرمانشاه. نشریه بوم‌شناسی کشاورزی، 9: 535-544.
8. 8) Abdel-Rahman, A.; M,. Ibrahim, M. M. 2012. Effect of cement dust deposition on physiological behaviors of some halophytes in the salt marshes of Red Sea. Academic Journal Biology Science, 3: 1-11. [DOI:10.21608/eajbsh.2012.17001]
9. 9) Ai, N. and K. R. Polenske. 2008. Socioeconomic impact analysis of yellow-dust storms: An approach and case study for Beijing. Economic Systems Research. 20: 187-203. [DOI:10.1080/09535310802075364]
10. 10) Alavi, M., Sharifi, M., Karimi, N. 2014. Response of chlorophyll a fluorescence, chlorophyll content, and biomass to dust accumulation stress in the medicinal plant, Plantago lanceolata L. Iran. J. Plant Physiol. 4: 1055- 1060.
11. 11) Amini, A. 2020. The role of climate parameters variation in the intensification of dust phenomenon. Natural Hazards. 102: 468-445.‌ [DOI:10.1007/s11069-020-03933-w]
12. 12) Arnon, D.I. 1975. Physiological principles of dry land crop production. In: Gupta .U.S. (Eds.), Physiological Aspects of Dry Land Farming, Oxford, pp: 3-14.
13. 13) Chaturvedi, R. K., Prasad, S., Rana, S., Obaidullah, S. M., Pandey, V., & Singh, H. 2013. Effect of dust load on the leaf attributes of the tree species growing along the roadside. Environmental Monitoring and Assessment, 185: 383-391.‌ [DOI:10.1007/s10661-012-2560-x] [PMID]
14. 14) Chauhan, A. and P. Joshi. 2010. Effect of ambient air pollutants on wheat and mustard crops growing in the vicinity of urban and industrial areas. New York Sci3 .: 52-60.
15. 15) Chen, X., Zhou, Z., Teng, M., Wang, P., Zhou, L. 2015. Accumulation of three different sizes of particulate matter on plant leaf surfaces: effect on leaf traits. Archives of Biological Sciences. 67: 1257-1267. [DOI:10.2298/ABS150325102C]
16. 16) Durrani, G., Hassan, M., Baloch, M. K., Hameed, G. 2004. Effect of traffic pollution on plant photosynthesis. Journal-Cemical Society of Pakistan. 26: 176-179. [DOI:10.4314/jext.v4i1.2733]
17. 17) Giri, S., Shrivastava, D., Deshmukh, K., & Dubey, P. 2013. Effect of air pollution on chlorophyll content of leaves. Current Agriculture Research Journal, 1: 93-98.‌ [DOI:10.12944/CARJ.1.2.04]
18. 18) Goudie, A. S. 2014. Desert dust and human health disorders. Environment international, 63: 101-113.‌ [DOI:10.1016/j.envint.2013.10.011] [PMID]
19. 19) Goudie, A. S., & Middleton, N. J. 2006. Desert dust in the global system. Springer Science & Business Media.‌
20. 20) Grainger, A. 2013. The threatening desert: controlling desertification. Routledge.‌ [DOI:10.4324/9781315066783]
21. 21) Gupta, G. P., Kumar, B., Singh, S., Kulshrestha, U. C. 2016. Deposition and Impact of Urban Atmospheric Dust on Two Medicinal Plants during Different Seasons in NCR Delhi. Aerosol and Air Quality Research. 16: 2920-2932. [DOI:10.4209/aaqr.2015.04.0272]
22. 22) Han, J., Dai, H., & Gu, Z. 2021. Sandstorms and desertification in Mongolia, an example of future climate events: a review. Environmental Chemistry Letters, 11-1.‌ [DOI:10.1007/s10311-021-01285-w] [PMID] []
23. 23) Hatami, Z., Rezvani Moghaddam, P., Rashki, A., Mahallati, M. N., & Habibi Khaniani, B. 2018. Effects of desert dust on yield and yield components of cowpea (Vigna unguiculata L.). Archives of Agronomy and Soil Science. 64: 1446-1458. [DOI:10.1080/03650340.2018.1440081]
24. 24) Leghari, S. K., Zaid, M. A., Sarangzai, A. M., Faheem, M., & Shawani, G. R. 2014. Effect of road side dust pollution on the growth and total chlorophyll contents in Vitis vinifera L.(grape). African Journal of Biotechnology. 13: 11.‌ [DOI:10.5897/AJB12.2652]
25. 25) Mandre, M., J. Klõšeiko and K. Ots. 2000. The effect of cement dust on the growth, content of nutrients and carbohydrates in various organs of five conifer species. Baltic For. 6: 16-23.
26. 26) Missanjo, E., Ndalama, E., Sikelo, D., Kamanga-Thole, G 2015. Quarry dust emission effects on tree species diversity in Chongoni forest Reserve and vegetation characteristics in adjacent villages, Dedza, Malawi. International Journal of Information and Review. 2: 511-515.
27. 27) Price, M. V., Waser, N. M., Lopez, D. A., Ramírez, V. D., & Rosas, C. E. 2021. Predispersal seed predation obscures the detrimental effect of dust on wildflower reproduction. International Journal of Plant Sciences, 182: 277-285.‌ [DOI:10.1086/713440]
28. 28) Rai, P. K. and L. L. Panda. 2014. Leaf dust deposition and its impact on biochemical aspect of some roadside plants of Aizawl, Mizoram, North East India. International Research Journal of Environment Sciences. 3: 14-19.
29. 29) Ramanathan, R., Jeyakavitha, T., Jeganathan, M2006 .. Impact of cement dust on Azadirachta in Dica leaves- A measure of air pollution in and around ARIYALUR. Journal of Industrial Pollution Control. 22 , 2: 285-288.
30. 30) Shah, K., ul Amin, N., Ahmad, I., & Ara, G. 2018. Impact assessment of leaf pigments in selected landscape plants exposed to roadside dust. Environmental Science and Pollution Research, 25: 23055-23073.‌ [DOI:10.1007/s11356-018-2309-3] [PMID]
31. 31) Sharma, S. B. and B. Kumar. 2015. Effects of stone crusher dust pollution on growth performance and yield status of gram (Cicer arietinum L.). International Journal of Current Microbiology and Applied Sciences. 4: 971-979.
32. 32) Sharma, S. B. and B. Kumar. 2016. Effects of stone crusher dust pollution on growth performance and yield status of rice (Oryza sativa. L). Int. J. Curr. Microbiol. App. Sci 5: 796-806. [DOI:10.20546/ijcmas.2016.505.080]
33. 33) Sivakumar, M. V. 2005. Impacts of sand storms/dust storms on agriculture. In Natural disasters and extreme events in agriculture. 159-177. [DOI:10.1007/3-540-28307-2_10]
34. 34) Smith, W. H. 1977. Removal of atmospheric particulates by urban vegetation: implications for human and vegetative health. The Yale journal of biology and medicine, 50: 2, 185.‌
35. 35) Soleimani, Z., Teymouri, P., Boloorani, A. D., Mesdaghinia, A., Middleton, N., & Griffin, D. W. 2020. An overview of bioaerosol load and health impacts associated with dust storms: A focus on the Middle East. Atmospheric Environment, 223: 117-187.‌ [DOI:10.1016/j.atmosenv.2019.117187]
36. 36) Solgi, E., Keramaty, M., & Solgi, M. 2020. Biomonitoring of airborne Cu, Pb, and Zn in an urban area employing a broad leaved and a conifer tree species. Journal of Geochemical Exploration, 208: 126-106.‌ [DOI:10.1016/j.gexplo.2019.106400]
37. 37) Wang, Q., Feng, J., Huang, Y., Wang, P., Xie, M., Wan, H., ... & Yu, L. 2020. Dust-retention capability and leaf surface micromorphology of 15 broad-leaved tree species in Wuhan. Acta Ecologica Sinica, 40: 213-222.‌ [DOI:10.5846/stxb201808241808]
38. 38) Younis, U. 2013. Dust interception capacity and alteration of various biometric and biochemical attributes in cultivated population of Ficus carica L. J. Pharm. Biol. Sci.(IOSR-JPBS), 6: 35-42. [DOI:10.9790/3008-0643542]
39. 39) Zhu, J., Yu, Q., Zhu, H., He, W., Xu, C., Liao, J., ... & Su, K. 2019. Response of dust particle pollution and construction of a leaf dust deposition prediction model based on leaf reflection spectrum characteristics. Environmental Science and Pollution Research, 26: 36764-36775.‌ [DOI:10.1007/s11356-019-06635-4] [PMID]
40. 40) Zia-Khan, S., Spreer, W., Pengnian, Y., Zhao, X., Othmanli, H., He, X., & Müller, J. 2015. Effect of dust deposition on stomatal conductance and leaf temperature of cotton in northwest China. Water, 7: 116-131 [DOI:10.3390/w7010116]

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