Water movement in the soil

Gembloux Agro-Bio Tech

14 Nov 201416:26

Summary

TLDRThis educational video script explores the dynamics of water movement in soil, emphasizing the role of potential differences and soil structure. It uses time-lapse photography to illustrate capillarity, the forces of adhesion and cohesion, and how they counteract gravity. The script also discusses the impact of soil types, such as sandy and clay loams, on water infiltration and retention. It highlights how soil layers, such as coarse sand or clay pans, can act as barriers to water flow, affecting agricultural practices and soil management. The demonstrations serve to educate on the principles of unsaturated water flow, crucial for understanding irrigation, drainage, and soil conservation in agriculture.

Takeaways

💧 Water movement in soil is driven by potential differences, with water moving from areas of high potential to low potential.
🌱 The potential at any point in soil is influenced by forces such as gravity and capillarity, which cause water to move downward or upward.
🔍 Time-lapse photography in the video demonstrates how water moves into soil, showing processes that would take hours in nature in just minutes.
📏 The model used in the video, with soil between glass plates, represents a vertical cross-section of soil and allows for visualizing water movement.
🌿 Capillarity is a key principle where water moves into dry porous materials due to the attraction of solid mineral surfaces and cohesion of water molecules.
🏺 The height to which water rises in capillary action is influenced by the closeness of surfaces and the internal tension in the water.
🌳 Soil texture greatly affects water infiltration and retention, with sandy soils allowing more rapid infiltration but less retention compared to clay soils.
🌾 Sandy soils are better for irrigated areas due to their good infiltration properties, while clay soils are more suitable for dryland farming due to their water retention.
🚧 The presence of layers such as coarse sand or fine clay in soil can significantly impact water movement, acting as barriers or check valves.
🌱 The structure of soil, including the presence of aggregates and organic matter, plays a crucial role in water infiltration and the soil's ability to support plant growth.
🌱 Proper soil management, such as maintaining good tilth and avoiding compaction, can enhance water infiltration and reduce erosion.

Q & A

What determines the movement of water in soil?
-Water movement in soil is determined by the distribution of potential within the soil profile, with water tending to move from areas of higher potential to areas of lower potential.
What happens if there is no potential difference in the soil?
-If there is no potential difference, no water movement will occur.
What are the main forces that affect water potential at any point in the soil?
-The main forces affecting water potential are gravitational and matric forces, which cause water to move downward due to gravity and upward due to the attraction of solid surfaces, known as capillarity.
How does the soil model in the video represent a real-world scenario?
-The soil model, held between glass plates, represents a vertical cross-section of soil, allowing viewers to observe water movement as it would occur in nature, albeit accelerated due to time-lapse photography.
What principle is demonstrated when water rises between two closely spaced plastic plates?
-The principle of capillarity is demonstrated, where water is pulled upward against gravity due to the adhesive forces between the plastic and water and the cohesive forces between water molecules.
Why does the height of water rise differ when plastic plates are pinched together?
-The height of water rise is greatest when the plastic plates are pinched tightly together due to the increased adhesive forces and the resulting internal tension in the water.
How does the size of soil pores affect the rate of water flow and retention?
-The finer the soil pores, the more restricted the rate of water flow, and the greater the water retention. Sandy soils have larger pores and allow for greater initial penetration, while clay soils with finer pores retain water more effectively.
What is the significance of soil texture in irrigation and agricultural practices?
-Soil texture is significant because it affects the infiltration properties and water-holding capacity, which in turn influence irrigation needs and the suitability of the soil for different agricultural practices.
How does a layer of coarse sand in soil affect water movement?
-A layer of coarse sand can act like a check valve, holding water back until the overlying soil becomes very wet, at which point it allows excess water to pass through, demonstrating the principle of unsaturated flow.
What is the impact of a fine clay layer within otherwise uniform soil?
-A fine clay layer can restrict root growth and water penetration, often leading to water table buildup above such layers. It can impose limitations on agricultural use due to its resistance to water flow and its impact on soil drainage.
How do soil aggregates and their pores influence water movement?
-Soil aggregates with large pores can transmit water readily under saturated conditions, but under unsaturated conditions, water moves into and through the soil due to the attraction of solid surfaces, with the rate of movement being restricted by the number of contacts between aggregates.