🧭 Overview
🧠 One-sentence thesis
Runoff and water erosion involve a sequence of processes—excess water generation, surface storage, detachment, transport, and deposition—that can cause harmful soil loss on cropland but may also be harnessed for beneficial water harvesting in water-scarce regions.
📌 Key points (3–5)
- Two mechanisms for excess water: infiltration-excess (delivery rate exceeds infiltration) vs saturation-excess (soil is saturated and cannot accept more water).
- Three stages of erosion: detachment (by raindrop impact, aggregate breakdown, or runoff scouring), transport (sheet, rill, or gully erosion), and deposition (when flow velocity decreases).
- Common confusion—sheet vs rill vs gully erosion: sheet erosion is uniform and often unnoticed; rill erosion forms small shallow channels that can be tilled; gully erosion creates deep channels that cannot be crossed or removed by tillage.
- Particle behavior paradox: fine sand (0.2–0.5 mm) is most easily detached, but clay particles, once suspended, remain in suspension even at very low flow velocities.
- Why it matters: runoff reduces crop water availability, erodes fertile topsoil, pollutes surface water, but can also be captured for irrigation; erosion models help predict and manage these impacts.
💧 How excess water and runoff are generated
💧 Two pathways to excess water
The excerpt identifies two conceptual reasons for excess water on the soil surface:
Infiltration-excess overland flow: the soil is unsaturated but the rate of water delivery to the surface exceeds the infiltration rate into the soil.
Saturation-excess overland flow: the soil is saturated (or satiated) and cannot accept any more water.
- Both pathways lead to water accumulating on the surface, but the underlying cause differs.
- Don't confuse: infiltration-excess happens even when the soil is not fully saturated; saturation-excess requires the soil to be completely saturated.
🛑 Surface storage capacity delays runoff
- Even after excess water is generated, runoff does not begin immediately.
- The soil surface is never perfectly smooth; roughness creates a finite surface storage capacity—the volume of excess water per unit area that can be retained on the surface.
- Runoff only begins once this storage capacity is exceeded.
- Example: small depressions and bumps on a field hold water before it starts flowing downhill.
🌊 The three stages of water erosion
🔨 Detachment: how soil particles break free
Detachment: the separation of soil particles from the bulk soil body.
Three mechanisms cause detachment:
- Raindrop impact: raindrops strike the soil surface and dislodge particles.
- Aggregate breakdown upon wetting: soil aggregates disintegrate when wetted.
- Scouring force of surface runoff: flowing water exerts force that detaches particles.
What controls detachment rate:
- Degree of surface cover (vegetation, plant residues, or other protective covers)
- Soil strength (stronger soil resists detachment)
- Rainfall intensity (higher intensity increases raindrop impact)
- Velocity of surface runoff (faster flow exerts more scouring force)
🚚 Transport: patterns of water and sediment movement
Once detached, soil particles (sediment) are transported across the surface. The excerpt describes three distinct patterns:
| Erosion type | Characteristics | Practical implications |
|---|
| Sheet erosion | Water flow and soil erosion distributed relatively uniformly across the surface | Insidious—can go unnoticed for years; the excerpt describes a case where >30 cm of topsoil was lost, effectively destroying productive capacity |
| Rill erosion | Water and sediment concentrate in small, shallow channels | Rills can be removed using tillage and are easily crossed with field equipment |
| Gully erosion | Rills deepen and widen to form gullies | Gullies cannot be removed by tillage and cannot be easily crossed with equipment |
- Don't confuse rills and gullies: the key distinction is whether tillage can remove them and whether equipment can cross them.
🏔️ Gravity-driven erosion on slopes
- Other types of water-related erosion are driven by gravity acting on wet soil along hillslopes, gullies, and streambanks.
- When soil becomes thoroughly wetted:
- The weight of the soil body increases
- Soil strength decreases
- Risk of gradual soil creep, sudden slumps, and potentially devastating landslides increases
- Example: the excerpt mentions a 7.6 magnitude earthquake in El Salvador on January 13, 2001, that triggered a massive landslide killing ~585 people; wet soil was thought to be a key contributing factor.
📦 Deposition: where sediment settles
Sediment deposition: the final stage of the erosion process, typically initiated by a decrease in flow velocity.
- Deposition is a major issue affecting streams, reservoirs, and coastal areas.
- It is also one of the primary drivers of dramatic spatial variability in alluvial soils.
- Sediment control is an important management concern in agriculture, construction, and engineering.
- The excerpt notes that deposition can be approximated using Stokes' Law (a formula from earlier in the text).
📊 The Hjulström-Sundborg diagram: particle behavior in flowing water
📊 What the diagram shows
Hjulström-Sundborg diagram: a diagram summarizing the behavior of particles in a stream or river, showing relationships between particle size and the tendency to be eroded, transported, or deposited at different current velocities.
- Based on work by researchers at the University of Uppsala in Sweden.
- Both axes have a logarithmic scale.
- The diagram depicts the three stages of water erosion (detachment/erosion, transport, deposition) as a function of flow velocity for different particle sizes.
🔍 Key insights from the diagram
Sand-sized particles (1 mm):
- Detachment requires roughly 20 cm/s flow velocity.
- Once detached, the particle remains in suspension and is transported until flow velocity drops below 10 cm/s.
- This means transport can continue at lower velocities than required for detachment.
Most erodible particle size:
- Sand-size particles in the range 0.2–0.5 mm (fine to medium sand) have the lowest detachment velocity and are thus most erodible.
- Why? The excerpt explains that for smaller particles (silt and clay), attractive and adhesive forces between particles increase as particle size decreases, making them harder to detach.
Clay-sized particles:
- Once detached and suspended, clay particles will not be deposited but will remain in suspension indefinitely, even at flow velocities as low as 0.1 cm/s.
- This explains why clay can travel long distances in water and why streams remain turbid long after flow slows.
⚠️ Paradox to remember
- Don't confuse detachment ease with transport behavior: fine sand is easiest to detach, but clay, once detached, stays suspended longest.
- Larger particles settle quickly when flow slows; clay does not.
🧮 Predicting runoff: the Curve Number Method
🧮 Core hypothesis
The Curve Number Method is an empirical model developed by the USDA Soil Conservation Service (now NRCS) in the 1950s.
Core hypothesis: The ratio of actual precipitation retained by the landscape during a rainfall event (F) to the potential maximum retention (S) equals the ratio of runoff (Q) to total precipitation minus initial abstraction (P – I_a).
In words: F divided by S equals Q divided by (P minus I_a).
🔢 How the method works
- F: amount of precipitation retained during the event
- S: potential maximum retention for that landscape
- Q: amount of runoff
- P: total precipitation amount
- I_a: initial abstraction (water that does not contribute to runoff or retention, typically estimated as 20% of S, i.e., I_a = 0.2S)
The excerpt provides a rearranged formula (Eq. 7-2) that is only valid for P > I_a.
Curve Number (CN):
- An empirical number between 0 and 100 selected based on the hydrologic characteristics of the landscape.
- Used to calculate S (in inches) via a formula (Eq. 7-3).
- Curve numbers for a wide variety of circumstances are available (the excerpt provides a link).
- Units of S, P, I_a, and Q must be the same; unit conversion can be applied as needed.
📈 Adjustments and refinements
- Procedures exist for adjusting CN values based on initial soil moisture conditions:
- Lower values for drier conditions
- Higher values for wetter conditions
- Research has indicated that setting the initial abstraction to 5% rather than 20% of S results in more accurate runoff predictions, but this change also requires revising the existing CN values.
🆚 Empirical vs mechanistic models
| Model type | Curve Number Method (empirical) | Mechanistic models (e.g., WEPP) |
|---|
| Approach | Based on empirical relationships and a simple hypothesis | Simulate underlying mechanisms of soil water balance and overland flow |
| Data requirements | Curve number based on landscape characteristics | Detailed information about weather, rainfall patterns, soil properties, topography, land use |
| What it predicts | Runoff amount | Runoff and associated soil erosion; can include spatial information and simulate overland flow convergence |
| Example | Curve Number Method | USDA Water Erosion Prediction Project (WEPP) model |
- The excerpt mentions that the WEPP model development was led by the National Soil Erosion Research Laboratory of the USDA Agricultural Research Service, with over 200 contributors.
🌍 Why runoff and erosion matter: onsite and offsite effects
❌ Harmful effects on cropland
Runoff from cropland is typically undesirable because it results in:
- Reduced water availability for the crop: water leaves the field instead of infiltrating.
- Erosion of fertile topsoil: the most productive soil layer is lost.
- Pollution of surface water bodies: sediment, phosphorus, and other contaminants are carried into streams, lakes, and rivers.
Example: the excerpt describes runoff and water erosion from a corn (maize) field in Iowa, USA, with harmful onsite and offsite effects.
✅ Beneficial uses: water harvesting
In contrast, runoff from uncultivated or impervious areas can sometimes be beneficial when captured and stored for later use.
Water harvesting strategies: capturing and storing runoff for later use.
- May be key solutions to meeting critical water challenges in:
- Developing regions such as sub-Saharan Africa
- Major metropolitan areas in arid or semi-arid regions of developed nations (e.g., Sydney, Australia)
- Example: the excerpt describes a runoff-harvesting pit in Uganda used to irrigate bananas, cassava, corn, and vegetables.
🌊 Influence on surface water
- Runoff is one of the main sources of water to surface water bodies.
- Any soil or water management practices that influence runoff are likely to influence surface water quantity and quality.
- This connection makes runoff management critical for both agricultural productivity and environmental protection.