|
|
|
|
|
| Straw layer burial to alleviate salt stress in silty loam soils: Impacts of straw forms |
| ZHANG Hong-yuan*, LU Chuang*, PANG Huan-cheng, LIU Na, ZHANG Xiao-li, LI Yu-yi#br# |
Institute of Agricultural Resources and Regional Planning, Chinese Academy of Agricultural Sciences, Beijing 100081, P.R.China
|
|
|
|
|
Abstract Salt stress can be alleviated by straw layer burial in the soil, but little is known of the appropriate form of the straw layer for optimal regulation of soil water and salinity because of the uncontrollability of field tests. Here, the following four straw forms with compaction thickness of 5 cm buried 40–45 deep were studied: no straw layer (CK), segmented straw (SL, 5 cm in length), straw pellet (SK), and straw powder (SF). The three straw forms (SL, SK and SF) significantly delayed the infiltration of irrigation water down the column profile by 71.20–134.3 h relative to CK and the migration velocity of the wetting front under SF was the slowest. It took longer for the wetting front to transcend SK than SL but shorter for it to reach the bottom of soil column after water crossed the straw layer. Compared with CK, the average volumetric water content in the 0–40 cm soil layer increased by 6.45% under SL, 1.77% under SK and 5.39% under SF. The desalination rates at the 0–40 and 0–100 cm soil layers increased by 5.85 and 3.76% under SL, 6.64 and 1.47% under SK and 5.97 and 4.82% under SF. However, there was no significant difference among straw forms in the 0–40 cm soil layer. Furthermore, the salt leaching efficiency (SLE, g mm–1 h–1) above the 40 cm layer under SL was 0.0097, being significantly higher than that under SF (0.0071) by 37.23%. Salt storage under SL, SK and SF in the 40–45 cm layer accounted for 4.50, 16.92 and 7.43% of total storage in the 1-m column profile. Cumulative evaporation under SL and SF decreased significantly by 41.20 and 49.00%, with both treatments having the most significant inhibition of salt accumulation (resalinization rate being 36.06 and 47.15% lower than CK) in the 0–40 cm soil layer. In conclusion, the different forms of straw layers have desalting effects under high irrigation level (446 mm). In particular, SL and SF performed better than SK in promoting deep salt leaching and inhibiting salt accumulation on the soil surface. However, SL was simpler to implement and its SLE was higher. Therefore, the segmented 5 cm straw can be recommended as an optimum physical form for establishing a straw layer for managing saline soils for crop production.
|
|
Received: 27 September 2018
Accepted:
|
| Fund: This research was funded by the National Natural Science Foundation of China (31471455 and 31871584) and the National Key Research and Development Program of China (2016YFC0501302). |
|
Corresponding Authors:
Correspondence LI Yu-yi, Tel: +86-10-82105057, E-mail: liyuyi@caas.cn
|
| About author: ZHANG Hong-yuan, E-mail: zhanghongyuan0429@163.com; * These authors contributed equally to this study. |
Cite this article:
ZHANG Hong-yuan, LU Chuang, PANG Huan-cheng, LIU Na, ZHANG Xiao-li, LI Yu-yi.
2020.
Straw layer burial to alleviate salt stress in silty loam soils: Impacts of straw forms. Journal of Integrative Agriculture, 19(1): 265-276.
|
Akudago J A, Nishigaki M, Chegbeleh L P, Komatsu M, Alim M A. 2009. Capillary cut design for soil-groundwater salinity control. Journal of the Faculty of Environmental Science and Technology Okayama University, 14, 17–22.
Aubertin M, Cifuentes E, Apithy S A, Bussire B, Molson J, Chapuis R P. 2009. Analyses of water diversion along inclined covers with capillary barrier effects. Canadian Geotechnical Journal, 46, 1146–1164.
Barter-Lennard E G. 2002. Restoration of saline land through revegetation. Agricultural Water Management, 53, 213–226.
Bao S D. 2000. Soil Agrochemical Analysis. China Agricultural Press, Beijing. p. 178–200. (in Chinese)
Bernadiner M G. 1998. A capillary microstructure of the wetting front. Transport in Porous Media, 30, 251–265.
Chhabra R, Thakur N P. 1998. Lysimeter study on the use of biodrainage to control waterlogging and secondary salinization in (canal) irrigated arid/semi-arid environment. Irrigation and Drainage Systems, 12, 265–288.
Cao J S, Liu C M, Zhang W J, Guo Y L. 2012. Effect of integrating straw into agricultural soils on soil infiltration and evaporation. Water Science and Technology, 65, 2213–2218.
Cook H F, Valdes G S B, Lee H C. 2006. Mulch effects on rainfall interception, soil physical characteristics and temperature under Zea mays L. Soil and Tillage Research, 91, 227–235.
Deng Z Y, Wang Q, Zhang Q, Wang R Y, Bai H Z,Wang J S, Xu J F. 2011. Impact of soil water storage capacity and water consumption on water productivity of spring wheat in the dry-farming area on the Loes Plateau of Gansu Province. Journal of Glaciology and Geocryology, 33, 425–430. (in Chinese)
Goyeau B, Lhuillier D, Gobin D, Velarde M G. 2003. Momentum transport at a fluid-porous interface. International Journal of Heat and Mass Transfer, 46, 4071–4081.
Guo G, Araya K, Jia H, Zhang Z, Ohomiya K, Matsuda J. 2006. Improvement of salt-affected soils, Part 1: Interception of capillarity. Biosystems Engineering, 94, 139–150.
Hu S J, Kang S Z, Song Y D, Tian C Y, Pan Y, Li Y. 2004. Variation of phreatic evaporation and its calculation method in Tarim River basin in Xingjiang. Transactions of the Chinese Society of Agricultural Engineering, 20, 49–53. (in Chinese)
Huo L, Pang H C, Zhao Y G, Wang J, Lu C, Li Y Y. 2017. Buried straw layer plus plastic mulching improves soil organic carbon fractions in an arid saline soil from Northwest China. Soil and Tillage Research, 165, 286–293.
Kasteel R, Garnier P, Vachier P, Coquet Y. 2007. Dye tracer infiltration in the plough layer after straw incorporation. Geoderma, 137, 360–369.
Konukcu F, Cowing J W, Rose D A. 2006. Dry drainage: A sustainable solution to water logging and salinity problems in irrigation areas. Agriculture Water Management, 83, 1–12.
Lei T W, Issac S, Yuan P J, Huang X F, Yang P L. 2001. Strategic considerations of efficient irrigation and salinity control on Hetao Plain in Inner Mongolia. Transactions of the Chinese Society of Agricultural Engineering, 17, 48–52. (in Chinese)
Li J G, Pu L J, Han M F, Zhu M, Zhang R S, Xiang Y Z. 2014. Soil salinization research in China: Advances and prospects. Journal of Geographical Sciences, 24, 943–960.
Meng L X, Gao J M, Ma T, Yan Z L. 2011. Analysis of pore structure on carbon powder of hemp straw. Advanced Materials Research, 177, 640–642.
Mulumba L N, Lal R. 2008. Mulching effects on selected soil physical properties. Soil and Tillage Research, 98, 106–111.
Niu W Q, Zou X Y, Liu J J, Zhang M Z, Lv W, Gu J. 2016. Effects of residual plastic film mixed in soil on water infiltration, evaporation and its uncertainty analysis. Transactions of the Chinese Society of Agricultural Engineering, 32, 110–119. (in Chinese) ?
Qadir M, Schubert S, Ghafoor A, Murtaza G. 2001. Amelioration strategies for sodic soils: A review. Land Degradation and Development, 12, 357–386.
Qian T W, Huo L J, Zhao D Y. 2010. Laboratory investigation into factors affecting performance of capillary barrier system in unsaturated soil. Water Air and Soil Pollution, 206, 295–306.
Rooney D J, Brown K W, Thomas J C. 1998. The effectiveness of capillary barriers to hydraulically isolate salt contaminated soils. Water, Air, and Soil Pollution, 104, 403–411.
Sakaguchi A T, Nishimura T, Kato M. 2005. The effect of entrapped air on the quasi-saturated soil hydraulic conductivity and comparison with the unsaturated hydraulic conductivity. Vadose Zone Journal, 4, 139–144.
Sonnleitner R, Lorbeer E, Schinner F. 2003. Effects of straw, vegetable oil and whey on physical and microbiological properties of a chernozem. Applied Soil Ecology, 22, 195–204.
Tu A G. 2017. Advances in water infiltration and solute transport in layered soil. Acta Agriculture Universitatis Jiangxiensis, 39, 818–825. (in Chinese)
Walter M T, Kim J S, Stenhuis T S, Parlange J Y, Heilig A, Braddock R D, Selker J S, Boll J. 2000. Funneled flow mechanisms in a sloping layered soil: Laboratory investigations. Water Resources Research, 36, 841–849.
Wang Y, Li F, Rong X, Song H, Chen J. 2017. Remediation of petroleum-contaminated soil using bulrush straw powder, biochar and nutrients. Bulletin of Environmental Contamination and Toxicology, 98, 1–8.
Wang Z, Feng H. 2009. Study on the influence of different straw-returning manners on soil structure and characters of soil water evaporation. Transactions of the Chinese Society of Agricultural Engineering, 23, 224–228. (in Chinese)
Yang H, Rahardjo H, Leong E C, Fredlund D G. 2004. A study of infiltration on three sand capillary barriers. Canadian Geotechnical Journal, 41, 629–643.
Zhao Y G, Li Y Y, Wang J, Pang H C, Yan L. 2016. Buried straw layer plus plastic mulching reduces soil salinity and increases sunflower yield in saline soils. Soil and Tillage Research, 155, 363–370.
Zhao Y G, Li Y Y, Hu X L, Wang J, Pang H C. 2013. Effects of plastic mulching and deep burial of straw on dynamics of soil water and salt in micro-plot field cultivation. Acta Pedologica Sinica, 50, 1129–1137. (in Chinese)
Zheng J, Wang Y,Cai H J, Li Z J. 2014. Soil-water characteristic curves of soil with plant additive and analyses of the fitting models. Transactions of the Chinese Society for Agricultural Machinery, 45, 107–112. (in Chinese)
Zheng J, Wang Y,Cai H J, Zhang E J, Sun Y X. 2016. Experimental investigation into effects of maize leaf and straw fragments on soil water infiltration characteristics in furrow irrigation. Journal of Drainage and Irrigation Machinery Engineering, 34, 66–72. (in Chinese) |
| No Suggested Reading articles found! |
|
|
Viewed |
|
|
|
Full text
|
|
|
|
|
Abstract
|
|
|
|
|
Cited |
|
|
|
|
| |
Shared |
|
|
|
|
| |
Discussed |
|
|
|
|
