PROGRESS ANALYSIS AND OUTLOOK OF DONGYING BASE
Volume 2, Issue 1, Pp 6-13, 2024
DOI: 10.61784/wjafs240139
Author(s)
Soundar Mallik
Affiliation(s)
Research Centre on Agriculture and Environment, CREA-AA, Rome, Italy.
Corresponding Author
Soundar Mallik
ABSTRACT
The Yellow River Delta is an important ecological functional area in my country and a key area for achieving national food security. This article reviews the recent research progress of Ludong University’s Dongying base for the high-quality development of modern agriculture integrating industry and education, and analyzes several important research issues surrounding ecological protection and high-quality development in the Yellow River Delta from the perspectives of food security and ecological environment protection, pointing out These are the scientific challenges that need to be overcome, and the prospects for major research areas such as comprehensive management and efficient utilization of saline-alkali soil are prospected.
KEYWORDS
Dongying Base; Yellow River Triangle; Comprehensive management of saline-alkali land; Ecological protection; High-quality agricultural development
CITE THIS PAPER
Soundar Mallik. Progress analysis and outlook of dongying base. World Journal of Agriculture and Forestry Sciences. 2024, 2(1): 6-13. DOI: 10.61784/wjafs240139.
REFERENCES
[1] Yang Jinsong, Yao Rongjiang, Wang Xiangping. Research on saline soils in China: history, current situation and prospects. Journal of Soil Science, 2021: 1-21. http://kns.cnki.net/kcms/detail/32.1119.P.20211112.0951.002.html.
[2] Yang Jinsong, Yao Rongjiang. Management and efficient agricultural utilization of saline-alkali lands in my country. Proceedings of the Chinese Academy of Sciences, 2015, 30: 162-170.
[3] Peng Xinhua, Wang Yunqiang, Jia Xiaoxu. Progress and prospects in the main fields of soil physics in China in the new era. Journal of Soil Science, 2020, 57 (5): 1071-1087.
[4] HU QL, ZHAO Y, HU X. Effect of saline land reclamation by constructing the “Raised Field-Shallow Trench” pattern on agroecosystems in Yellow River Delta. Agricultural Water Management, 2021: 107345. https://doiorg/10.1016/j.agwat.2021.107345.
[5] SWALLOW MJB, O'SULLIVAN G. Biomimicry of vas-cular plants as a means of saline soil remediation. Science of Total Environment, 2019, 655: 84-91.
[6] Geng Qiming, Yan Huihui, Yang Jinze. Evaluation of the soil improvement effect of open ditch and hidden pipe drainage projects on saline-alkali land development. Soil Bulletin, 2019, 50(3): 617-624.
[7] ZHAO Y, QI J, HU QL. The “Groundwater Benefit Zone”, proposals, contributions and new scientific issues//Soil Science-Emerging Technologies, Global Perspectives and Applications, IntechOpen, (2021-11-13). http://dx. doi. org/10. 5772/intechopen. 100299.
[8] Liu Haiman, Guo Kai, Li Xiaoguang. Effects of plastic film covering on water and salt dynamics of coastal saline soil under salt water irrigation conditions in spring. Chinese Journal of Ecological Agriculture, 2017, 25(12): 1761-1769.
[9] GUO K, LIU X. Infiltration of meltwater from frozen saline water located on the soil can result in reclamation of a coastal saline soil. Irrigation Science, 2015, 33 (6): 441-452.
[10] Lei Hongjun, Zang Ming, Zhang Zhenhua. Effects of circulating aeration pressure and active agent concentration on water vapor transmission in drip irrigation belts. Journal of Agricultural Engineering, 2014, 30(22): 63-69.
[11] Yang Jinsong, Yao Rongjiang, Wang Xiangping. Ecological management and ecological industry development model of saline-alkali land in the Hetao Plain. Acta Ecologica Sinica, 2016, 36 (22): 7059-7063.
[12] ROZEMA J, FLOWERS T. Crops for a salinized world. Science, 2008, 322(5907): 1478-1480.
[13] Zhao Zhenyong, Zhang Ke, Wang Lei. The desalination effect of halophytes on heavily saline soil. Chinese Desert, 2013, 33(5): 1420-1425.
[14] ZHENG H, WANG X, CHEN L. Enhanced growth of halophyte plants in biochar-amended coastal soil: roles of nutrient availability and rhizosphere microbial modulation. Plant Cell & Environment, 2018, 41 (3): 517-532.
[15] KUMARI A, JHA B. Engineering of a novel gene from a halophyte: potential for agriculture in degraded coastal saline soil. Land Degradation & Development, 2019, 30(6): 595-607.
[16] XIAO L, YUAN G, FENG L. Soil properties and the growth of wheat ( Triticum aestivum L.) and maize (Zea mays L.) in response to reed (phragmites communis) biochar use in a salt-affected soil in the Yellow River Delta. Agriculture, Ecosystems & Environment, 2020, 303: 107124.
[17] ROCHESTER IJ. Phosphorus and potassium nutrition of cotton: interaction with sodium. Crop and Pasture Science, 2010, 61(10): 825-834.
[18] XIE WP, YANG JS, YAO RJ. Spatial and temporal variability of soil salinity in the Yangtze River estuary using electromagnetic induction. Remote Sensing, 2021, 13(10): 1875.
[19] Chen Junying, Wang Xintao, Zhang Zhitao. Upscaling soil salinization monitoring method based on UAV-satellite remote sensing. Journal of Agricultural Machinery, 2019, 50(12): 161-169.
[20] SIM UNEK J, VAN GENUCHTEN MT, SEJNA M. Recent developments and applications of the HYDRUS computer software packages. Vadose Zone Journal, 2016, 15(7): 1-25.
[21] YAO RJ, YANG JS, WANG XP. Improving soil salinity simulation by assimilating electromagnetic in-duction data into HYDRUS model using ensemble Kal-man filter. Journal of Environmental Informatics, 2021, http://www.jeionline.org/index.php?journal=mys&page=article&op=view&path%5B%5D=202100451.
[22] Wang Quanjiu, Shan Yuyang. Research progress on brackish water irrigation and soil water and salt regulation. Journal of Agricultural Machinery, 2015, 46(12): 117-126.
[23] HATFIELD J L, SAUER T J, CRUSE R M. Soil: the forgotten piece of the water, food, energy nexus. Advance in Agronomy, 2017, 143: 1-1446.