Amila Ljutic, Jack Moore, Genevieve Ali, Laura Van Eerd, Merrin L. Macrae, Claudia Wagner-Riddle
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引用次数: 0
摘要
土壤水分对降雨的响应是决定地形对作物生长的支持程度以及易受径流和沥滤影响的一个关键因素,但很少有研究调查农业管理如何影响这一重要的土壤功能。本研究比较了两种常见的农业土壤处理方法(覆盖作物和土壤压实)及其对降雨的土壤湿度反应。在 3 月至 11 月的温带湿润气候中,研究人员对两个生长季中的单个降雨事件进行了划分,并使用四个土壤深度(20、30、40 和 60 厘米)的原位土壤水分传感器确定了相应的土壤水分响应。结果表明,水文反应因事件类型和管理方法而异。并非所有降雨事件都会触发响应:在较浅土壤深度触发响应的降雨事件通常具有事件总降雨量较高、最大降雨强度和平均降雨强度较高的特点。相比之下,在较深土壤深度触发响应的降雨事件的特点是事件持续时间较长以及 10 天前降雨量(AR)较高。覆盖作物处理的土壤水分响应特点是,较浅深度的土壤水分初始值和峰值相对较低,但 60 厘米深度的土壤水分值较高,而对照和压实土壤处理的土壤水分响应则相反。基质流最常在降雨量大的情况下产生,与任何特定的土壤处理都没有优先关系。然而,产生垂直偏好流需要特定的条件,即两个地层的总降雨量都很高,或 Ap 地层的偏好流具有较高的 AR 值,或 Bt 地层的偏好流具有较高的降雨强度。我们的研究结果证明了利用高频率、多深度土壤水分数据进行基于事件的详细土壤水分过程分析的潜力。
Variable soil moisture responses to rainfall events in fields under different management practices
Soil moisture response to rainfall is a key factor that dictates how well a landscape can support crop growth as well as its susceptibility to water runoff and leaching, however, few studies have investigated how agricultural management impacts this important soil function. This study compares two common agricultural soil treatments (cover crops and soil compaction) and their soil moisture response to rainfall in comparison to a control. In a humid temperate climate during March to November, individual rainfall events were delineated over two growing seasons and corresponding soil moisture responses were identified using in situ soil moisture sensors at four soil depths (20, 30, 40, and 60 cm). Results suggest that hydrological responses differed with both event type and management treatment. Not all rainfall events triggered a response: those that triggered responses at shallower soil depths were typically characterized by higher total event rainfall, and higher maximum and average rainfall intensity. In contrast, rainfall events triggering responses at deeper soil depths were characterized by longer event duration as well as higher 10-day antecedent rainfall (AR). Soil moisture responses for the cover crop treatment were characterized by relatively lower initial and peak soil moisture at shallower depths but higher values at 60 cm depth, whereas soil moisture responses for the control and compacted soil treatments demonstrated the opposite. Matrix flow was most often generated for rainfall events with high magnitude and was not preferentially associated with any particular soil treatment. However, specific conditions were needed to generate vertical preferential flow, namely high total event rainfall for both horizons, or high AR for preferential flow in the Ap horizon, or high rainfall intensity for preferential flow in the Bt horizon. Our findings demonstrate the potential for detailed event-based soil water process analysis using high-frequency, multi-depth soil moisture data.
期刊介绍:
Hydrological Processes is an international journal that publishes original scientific papers advancing understanding of the mechanisms underlying the movement and storage of water in the environment, and the interaction of water with geological, biogeochemical, atmospheric and ecological systems. Not all papers related to water resources are appropriate for submission to this journal; rather we seek papers that clearly articulate the role(s) of hydrological processes.
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