Soil Physical Properties Dec 18, 2025

Learning Outcomes

By the end of this week, students will be able to:

• Identify sand, silt, and clay by feel and by lab test.
• Explain how soil texture affects water, nutrients, and roots.
• Distinguish between different soil structures and their implications.
• Calculate soil texture class using the jar test and texture triangle.

Part 1 – Soil Texture: Sand, Silt, and Clay Sand: Largest particles; gritty feel; drains quickly; poor nutrient retention.

Largest Particles

This refers to sand, which makes up the coarsest fraction of soil. Compared to silt and clay, sand particles are much larger in size, which means they have less surface area relative to their volume. Because of their size, they don’t pack tightly together, leaving lots of open space between particles. This open structure influences nearly all of sand’s other properties.

Gritty Feel

Sand is easy to identify by touch. When you rub it between your fingers, it feels rough and gritty, unlike the smooth, flour-like texture of silt or the sticky, plastic-like feel of clay. This gritty texture is why sandy soils are often easy to dig and cultivate, but also why they don’t hold water or nutrients well.

Drains Quickly

The large spaces (or pores) between sand particles allow water to move through very rapidly. While this prevents waterlogging, it also means that plants in sandy soils can dry out faster, especially during hot weather. This quick drainage is both a benefit (reducing risk of root rot) and a challenge (making irrigation more frequent).

Poor Nutrient Retention

Because sand has relatively little surface area and low ability to hold onto ions, it cannot retain nutrients well. Essential minerals like nitrogen, potassium, and magnesium can easily leach out of sandy soils with rainfall or irrigation. This means sandy soils are often naturally less fertile and require careful management, such as adding organic matter, mulching, or using slow-release fertilizers, to keep them productive.

Silt: Medium-sized particles; smooth, flour-like feel; moderate drainage and fertility.

Medium-Sized Particles

Silt falls right between sand and clay in particle size. It’s not as large and coarse as sand, but not nearly as fine and sticky as clay. This “in-between” size gives silt its unique properties—balancing some of the strengths and weaknesses of the other two soil fractions.

Smooth, Flour-Like Feel

When you rub silt between your fingers, it feels soft, silky, and almost like baking flour. Unlike sand, it doesn’t feel gritty, and unlike clay, it doesn’t cling and form sticky ribbons. This smooth texture is one of the easiest ways to identify silt in a soil sample.

Moderate Drainage

Silty soils hold more water than sandy soils because the smaller particles pack closer together, reducing pore space. However, they still drain better than clay soils, which can become waterlogged. This balance means silty soils can retain moisture well enough for plants but don’t usually stay soggy for long periods.

Moderate Fertility

Because silt particles are smaller than sand, they provide more surface area to hold nutrients. This makes silty soils more fertile than sandy soils, though not quite as nutrient-retentive as clay. Many river valleys with rich agricultural traditions—like the Nile or the Mississippi—owe their productivity to silty soils deposited by floods.

Clay: Smallest particles; sticky when wet, hard when dry; holds water and nutrients but drains poorly. Smallest Particles

Clay consists of the tiniest soil particles—so small they can’t be seen with the naked eye and often require a microscope to view properly. Because of their minuscule size, clay particles have an enormous surface area compared to their volume. This makes them highly active in terms of chemistry and water retention, but also leads to unique challenges.

Clay soil changes dramatically depending on its moisture level. When wet, it feels sticky, heavy, and pliable, almost like modeling clay. It clings to tools, shoes, and hands. But when it dries, it hardens into a dense, compacted surface that can form cracks. These extremes make clay tricky to work with, especially for gardeners and farmers.

Holds Water and Nutrients

Because of its fine texture and immense surface area, clay excels at holding water and nutrients. Its negatively charged particles attract and retain positively charged nutrients like calcium, potassium, and magnesium. This makes clay-rich soils among the most fertile types, capable of supporting crops for long periods without frequent fertilization.

Drains Poorly The very trait that gives clay its strength—tiny, tightly packed particles—also creates its biggest weakness. Water moves slowly through clay, and poor drainage can lead to soggy, airless conditions where plant roots struggle to breathe. During heavy rains, clay can quickly become waterlogged, stressing or even drowning plants if not managed properly.

• Key Point: Soil texture affects water retention, nutrient availability, and root penetration.

Soil Texture Affects Water Retention

The size and arrangement of soil particles determine how much water the soil can hold and how quickly it drains.

• Sandy soils drain rapidly, leaving plants thirsty if not irrigated often.
• Clay soils hold water tightly, which can drown roots in soggy conditions.
• Silty soils strike a middle ground, holding enough moisture for plants without becoming waterlogged as quickly.

Soil Texture Affects Nutrient Availability

Nutrients in soil are carried in water and often cling to particle surfaces.

• Sand, with its large particles and limited surface area, can’t hold onto nutrients well—fertility is often low unless organic matter is added.
• Clay, with its immense surface area and charged particles, holds nutrients tightly, making it rich but sometimes slow to release.
• Silt provides moderate nutrient-holding capacity, often resulting in naturally fertile soils, especially in river valleys.

Soil Texture Affects Root Penetration

Roots must push through soil to find water and nutrients, and texture greatly influences their journey.

• Sandy soils are loose, allowing roots to grow freely and deeply, though they may struggle to find enough water.
• Clay soils can be dense and compacted, making root penetration difficult, especially when dry.

Silty soils are generally easier for roots to explore, supporting strong, widespread growth

Part 2 – Soil Structure

• Definition: How soil particles (sand, silt, clay) are arranged into aggregates (“peds”).
• Types of Structure:
• Granular (good for roots & water, found in topsoil).
• Blocky (common in subsoils).
• Platy (compacted soils, poor infiltration).
• Prismatic/Columnar (vertical cracking, often in clays).
• Key Point: Good structure allows air & water to flow; poor structure = compaction & erosion.

Part 3 – Porosity & Bulk Density

Porosity: Percentage of soil volume that is pore space (air + water).

• Macropores: Drain water quickly, allow oxygen in.
• Micropores: Hold water for roots.
• Bulk Density: Mass of dry soil per unit volume (g/cm³).
• Loose, well-structured soil = low bulk density.
• Compacted soil = high bulk density.
• Impact on Plants:
• High porosity/low density = deep roots, good drainage.
• Low porosity/high density = restricted roots, poor drainage, oxygen stress.

Part 4 – Synthesis & Application

• Soil texture = ingredients.
• Soil structure = recipe.
• Porosity & bulk density = the quality of the final bread (soft vs. brick).
• Farmers, landscapers, and gardeners must manage texture (can’t change it easily) and improve structure (through compost, cover crops, reduced tillage).

Case Example:

• A sandy soil lawn vs. a clay-heavy farm.
• How each handles rainfall differently.
• How organic matter changes both for the better.

Interactive Fun

Title: Soil Texture by Jar Test

Objective: Determine the proportion of sand, silt, and clay in collected soil samples.

Materials Needed:

• Soil samples (from Week 1 or new ones)
• Clear quart jars with lids
• Water
• Dish soap (few drops to disperse particles)
• Ruler
• Lab notebooks

Procedure:

1. Place soil in jar (about 1/3 full).
2. Add water and a few drops of dish soap.
3. Shake vigorously for 5 minutes.
4. Set jar down and let soil settle.

• Sand settles in 1 minute.
• Silt settles in 1–2 hours.
• Clay may take 24–48 hours.

1. Measure thickness of each layer to calculate % sand, % silt, % clay.
2. Use USDA Soil Texture Triangle to determine soil classification (e.g., sandy loam, silty clay).

Interactive Report Prompt:

• Record measurements of each soil layer.
• Calculate percentages and classify soil type.

Discuss how the soil type would affect water infiltration, nutrient holding, and plant choice