In Northwest China, potatoes are cultivated on double-rows of each ridge which is mulched with plastic film, and the film is covered with some of soil. While effective in retaining soil moisture, this technique can render the potato seedlings prone to be burned if they are not released from the plastic film in time. In this study, the model of convective heat transfer of potato ridge under solar radiation and atmospheric radiation is established by the Fluent software. The processes of the heat transfer of potato ridge was simulated for a certain day, and the temperature distribution in the potato ridge was monitored over time. The temperature distribution of soil in the growth layer of potato plants was analyzed under different thickness and widths of the covering soil on the film. The results showed that with the increase of covering soil thickness and width, the time for soil at different depth to reach the peak-temperature was delayed, and the daily temperature change of soil where the different depths layer of potato plants growth was reduced. At that time, a binary regression equation of offset temperature was constructed by using the Response Surface Method. The best parameter combination for covering soil on the plastic film is a thickness of 50 mm and a width of 280 mm in the cold and arid areas of Northwest China. However, the offset temperature (PT) first decreased and then almost remained unchanged with the increase of covering soil thickness. Considering the operational efficiency and power consumption of soil covering devices in the field, the unchanged width of the covering soil is 200 mm. The field experiments have shown that a 50 mm thick of soil covering is beneficial for the growth of potato plants and a 200 mm width of soil covering is beneficial for the growth of potato plants. The height of potato plants was 21 cm, and the natural emergence rate of potatoes was 95.8% on June 9, 2024. The environment of soil covered could provide theoretical support for the mechanized planting of potatoes.
Key words: potato growth; plastic mulching; soil covered with film; temperature distribution; natural emergence rate
DOI: 10.25165/j.ijabe.20241704.8357

Citation: Liu Q D, Sun W, Wang Y M, Wang J L, Che X L. Simulation of temperature distribution in double-row potato ridges mulched with plastic film covered with soil. Int J Agric & Biol Eng, 2024; 17(4): 185–197.

potato growth; plastic mulching; soil covered with film; temperature distribution; natural emergence rate

Zhang C H, Kong J Y, Tang M, Lin W, Ding D Y, Feng H. Improving maize growth and development simulation by integrating temperature compensatory effect under plastic film mulching into the AquaCrop model. The Crop Journal, 2023; 11(5): 1559–1568.

Deng M J, Wang Q J, Tao W H, Wang Z T, Cao J J. Development Model for Improving the Quality and Efficiency of Modern Agriculture in the Arid Region of Northwest China. Strategic Study of CAE, 2023; 25(4): 59–72.

Dai H L, Qin S H, Zhang J L, Wang D, Wanng C L, Chen L. Effects of plastic film and ridge-furrow cropping patterns on growth and yield of potato in semiarid areas. Agricultural Research in the Arid Areas, 2012; 30(5): 56–60. (in Chinese)

Zhang X C, Guo J, Ma Y F, Yu X F, Hou H Z, Wang H L, et al. Effects of vertical rotary subsoiling with plastic mulching on soil water availability and potato yield on a semiarid Loess plateau, China. Soil & Tillage Research, 2020; 199: 104591.

Qin S H, Zhang J L, Dai H L, Wang D, Li D M. Effect of ridge-furrow and plastic-mulching planting patterns on yield formation and water movement of potato in a semi-arid area. Agricultural Water Management, 2014; 131: 87–94.

Yang L S, Wang C, He P H, An Y X. Optimum thickness of covering soil on plastic films of potato cultivation in Northwest China. Journal of Agriculture, 2016; 6(7): 60–63.

Yang Z N, Tang J J, Zhang L F. A Study on self-puncture effect of different crops in sub-soil planting with film mulching. Agricultural Research in the Arid Areas. 2012; 30(5): 61–65. (in Chinese)

Tang J J, Zhang J, Duan Y F, Li D, Zhang L F. Study on the effect of automatic film breaking of eight crops. Chinese Agricultural Science Bulletin, 2011; 27(12): 244–248. (in Chinese).

Chen J B, Zhang Z T, Hao B W, Liu H Y, Duan W W. Effect of film mulching soil on the growth of film mulched potato in dry farming. Bulletin of Agricultural Science and Technology, 2013; 4: 55–58.

Li M J, Liu Y, Zhou Y Y, Zeng L Q. Effects of different film mulching and mulching methods on potato economic properties and yield. Tillage and Cultivation, 2013; 37–38. (in Chinese)

Sun W, Wu J M, Shi L R, Zhao W Y, Zhang H, Liu X L, et al. Mechanized full furrow and ridge cultivation method of dry potato, 2016; CN201410482464.0.

Wang Y J, Xie Z K, Sukhdev S M, Cecil L V, Zhang Y B, Wang J N. Effects of rainfall harvesting and mulching technologies on water use efficiency and crop yield in the semi-arid Loess Plateau. Agricultural Water Management, 2009; 96(3): 374–382.

Zhang S L, Lövdahl L, Grip H, Jansson P-E, Tong Y A. Modelling the effects of mulching and fallow cropping on water bal-ance in the Chinese Loess Plateau. Soil and Tillage Research, 2007; 93(2): 283–298.

Wang H L, Zhang X C, Yu X F, Ma Y F, Hou H Z. Effect of using black plastic film as mulch on soil temperature and moisture and potato yield. Acta Ecologica Sinica, 2016; 36: 5215–5226. (in Chinese)

Tang Y F, Gao S M, Wang Y H, Zhang X C. Soil water and thermal effects of different mulching and planting methods and their influences on yield in dryland potato production. Agricultural Research in the Arid Areas, 2013; 31: 1–7, 13. (in Chinese)

Li Y, Wang W Y, Men Q, Zhong X C, Xie X W. Field characters of soil temperature under the wide plastic-mulch. Transactions of the Chinese Society of Agricultural Engineering, 2001; 17(3): 32–36. (in Chinese)

Wang Y M, Sun W, Zhang Y H. Simulation of soil temperature field of potato ridge sowing with white film mulch and soil covering the seed band. American Journal of Potato Research, 2020; 97: 405–419.

Yang J B, Cai Z Y, Yang X, Xing R, Meng L H, Li Y H. Observation and modeling study of the influence of aerosol radiation effect on meteorology and environment. China Environmental Science, 2023; 43(1); 38–51. (in Chinese)

Wan Z W, Wang W, Lv H, Qiu P Y, Li Y Z, Lu Y. Comparison between CMIP6 and CMIP5 models in simulating historical spatiotemporal variations in radiation budgets at the top of atmosphere and the surface. Climate Change Research, 2022; 18(4): 468–481. (in Chinese)

Pan Y, Guo J, Li Y, Zhang J H, Ding X L. Characteristics of increasing temperature in soils with plastic mulching. Research of Soil and Water Conservation, 2002; 9(2): 130–134. (in Chinese)

Wen Z, Shi L C, Ren Y R. Fluent fluid computing application tutorial. Beijing: Tsinghua University Press, 2009; 456p. (in Chinese)

Wu H J, Zhu D S, Zhang L Z, Sun J L. Numerical simulation of flow and cooling performance of the earth-air heat exchangers. Acta Energiae Solaris Sinica, 2006; 27: 78–82. (in Chinese)

Zhang Q, Sun Z X, Wang S. Analysis of variation regularity of land-surface physical quantities over Dingxi Region of the Loess Plateau. Chinese Journal of Geophysics, 2011; 54(7): 1727–1737. (in Chinese)

Zhang Y L. Mechanism and simulation of soil water and heat transport in potato field under drip irrigation with plastic-film mulch. PhD dissertation. Beijing: China Agricultural University, 2017; 117 p.

Jiang H F, Wen D Y, Li N, Ding Y, Xiao J. A new simulation method for the diurnal variation of temperature—sub-sine simulation. Meteorology and Disaster Reduction Research, 2010; 33(3): 61–65. (in Chinese)

Wang T X, Liu Z C, Lu J. Experimental study on coefficient of thermal conductivity and specific volume heat of loess. Rock and Soil Mechanics, 2007; 28(4): 655–658. (in Chinese)

He L Q, Ding L X. Fundamentals of thermophysical calculation of solar buildings. Hefei: University of Science and Technology of China Press, 2011; 137 p. (in Chinese)

Du J W, Chen Z, Zhou H Y, Tao G J. Hull thermal deformation prediction method based on HOTTEL solar radiation model. Marine Technology, 2020(1): 1–6. (in Chinese)

Ma H Y, Li G Q, An X H, Wang Z H, Bai X F. Optimal thickness and period of soil-coverage on plastic film of potato. Chinese Potato Journal, 2015, 29(2): 85–87. (in Chinese)

Gao H H, Liu H J, Gao W C; Liu Q, Qian C R, Jin T et al. The suitability of crop plastic film mulching technology and its application on spring maize in northeast China. Transactions of the CSAE, 2021; 37(22): 95–107.

Lan X M, Chai S X, Coulter J A, Cheng H B, Chang L, Huang C X, et al. Maize straw strip mulching as a replacement for plastic film mulching in maize production in a semiarid region. Sustainability, 2020; 12: 6273.

Li R F, Ma J J, Sun X H, Guo X H, Zheng L J. Simulation of soil water and heat flow under plastic mulching and different ridge patterns. Agriculture, 2021; 11(11): 1099.

Shi R J, Zhao W Y, Dai F, Song X F, Zhao Y M, Wang F. Simulation of lnteraction between air flow field and soil seedbed covering on whole plastic film mulching on double ridges. Transactions of the CSAM, 2022; 53(11): 40–51.