Frost Heaves & Connecticut Stone Walls

Why are there so many historic stone walls weaving through Connecticut forests? When 18th-century farmers cleared the land, they discovered a never-ending supply of glacial rocks. Even after clearing a field, more rocks would magically appear the next spring. This simulation models frost heaving—the mechanical weathering process where water freezes, expands by 9%, and pushes rocks upward through the soil cycle after cycle.

NGSS HS-ESS2-5: Plan and conduct an investigation of the properties of water and its effects on Earth materials and surface processes (e.g., expansion of water as it freezes).

🤔 Make Your Prediction

Connecticut's glacial soil is full of buried rocks. Water expands by about 9% when it freezes into ice. Before you start the simulation, predict how many freeze-thaw cycles (years) it will take for the first buried rock to reach the surface. Consider: what role do soil moisture, soil type, and winter severity play?

Your prediction (years):

Soil Cross-Section

Years Passed: 0

Season: Summer
Temp: 20 °C
Soil Moisture: Medium

Rocks Harvested: 0

Speed: 1x

Environmental Variables

Soil Moisture 60%

0% (Dry) 100% (Saturated)

Winter Severity Moderate

Very Mild Arctic

Soil Type Silt/Loam

Sand Silt Clay Mystery ?

Ice Lens Close-Up

The Physics of Frost Heaving

Unlike almost all other substances, water expands by about 9% when it freezes into ice.

During a New England winter, the freezing front penetrates the soil. Water migrates toward the cold front and freezes, forming ice lenses under rocks. Because water expands, these ice lenses physically lift the rocks upward.

In spring, the ice melts. The cavity left beneath the rock fills with fine soil particles, preventing the rock from falling back down. Over many freeze-thaw cycles, rocks migrate entirely to the surface!

Data: Rock Displacement Over Time

Data Log

Year	Season	Frost Depth	Surface Rocks	Soil Type