Fang Huan, Zhou Hu, Norton Gareth J, Price Adam H, Raffan Annette C, Mooney Sacha J, Peng Xinhua, Hallett Paul D
1State Key Laboratory of Soil and Sustainable Agriculture, Institute of Soil Sciences, Chinese Academy of Sciences, No.71 East Beijing Road, Nanjing, 210008 China.
2University of Chinese Academy of Sciences, No.19A Yuquan Road, Beijing, 100049 China.
Plant Soil. 2018;430(1):233-243. doi: 10.1007/s11104-018-3715-5. Epub 2018 Jun 29.
Alternate wetting and drying (AWD) saves water in paddy rice production but could influence soil physical conditions and root growth. This study investigated the interaction between contrasting rice genotypes, soil structure and mechanical impedance influenced by hydraulic stresses typical of AWD.
Contrasting rice genotypes, IR64 and deeper-rooting Black Gora were grown in various soil conditions for 2 weeks. For the AWD treatments the soil was either maintained in a puddled state, equilibrated to -5 kPa (WET), or dried to -50 kPa and then rewetted at the water potential of -5 kPa (DRY-WET). There was an additional manipulated macropore structure treatment, i.e. the soil was broken into aggregates, packed into cores and equilibrated to -5 kPa (REPACKED). A flooded treatment (puddled soil remained flooded until harvest) was set as a control (FLOODED). Soil bulk density, penetration resistance and X-ray Computed Tomography (CT) derived macropore structure were measured. Total root length, root surface area, root volume, average diameter, and tip number were determined by WinRhizo.
AWD induced formation of macropores and slightly increased soil mechanical impedance. The total root length of the AWD and REPACKED treatments were 1.7-2.2 and 3.5-4.2 times greater than that of the FLOODED treatment. There was no significant difference between WET and DRY-WET treatments. The differences between genotypes were minimal.
AWD influenced soil physical properties and some root characteristics of rice seedlings, but drying soil initially to -50 kPa versus -5 kPa had no impact. Macropores formed intentionally from repacking caused a large change in root characteristics.
干湿交替灌溉(AWD)可在水稻生产中节水,但可能影响土壤物理状况和根系生长。本研究调查了不同水稻基因型、土壤结构以及受AWD典型水力胁迫影响的机械阻抗之间的相互作用。
将不同的水稻基因型,即IR64和根系更深的黑戈拉,种植在各种土壤条件下2周。对于AWD处理,土壤要么保持在淹水状态,平衡至-5 kPa(湿润),要么干燥至-50 kPa,然后在-5 kPa的水势下重新湿润(干-湿)。还有一个额外的人工大孔隙结构处理,即把土壤破碎成团聚体,装入土芯并平衡至-5 kPa(重新装填)。设置淹水对照处理(淹水土壤一直保持淹水直至收获)(淹水)。测量了土壤容重、穿透阻力以及X射线计算机断层扫描(CT)得出的大孔隙结构。通过WinRhizo测定总根长、根表面积、根体积、平均直径和根尖数。
AWD诱导了大孔隙的形成,并使土壤机械阻抗略有增加。AWD处理和重新装填处理的总根长分别是淹水处理的1.7 - 2.2倍和3.5 - 4.2倍。湿润处理和干-湿处理之间没有显著差异。基因型之间的差异最小。
AWD影响了水稻幼苗的土壤物理性质和一些根系特征,但最初将土壤干燥至-50 kPa与-5 kPa对其并无影响。重新装填有意形成的大孔隙导致根系特征发生了很大变化。
