Building an armor stone retaining wall is a project that blends engineering necessity with natural aesthetics. Unlike a neatly stacked wall of uniform blocks, this structure relies on the inherent character of large, rugged stones to create a resilient and visually striking landscape feature. The core principle is simple: leverage the weight and interlocking nature of the armor stones to resist the lateral pressure of retained soil. However, the successful execution of this concept demands meticulous planning, precise execution, and a deep understanding of the forces at work.
Understanding the Purpose and Design
Before selecting a single stone, it is crucial to define the function and scale of your retaining wall. Are you managing a significant slope change on a property, or creating a modest terraced garden bed? The height of the wall directly correlates with the complexity of the construction and the necessary engineering considerations. For walls exceeding three feet, consulting a structural engineer is not just recommended; it is essential for safety and longevity. The design must account for the specific load, which includes the weight of the soil itself and any additional forces such as groundwater pressure or the incline of the land behind the wall.
The Critical Role of the Base
An unstable base is the most common reason for retaining wall failure, and with armor stone, this vulnerability is amplified. You cannot simply place heavy stones on compacted topsoil. The foundation must be a substantial, excavated trench filled with multiple layers of crushed stone. This base layer should be compacted thoroughly after each addition, creating a level and immovable platform. The depth of this base is typically a significant portion of the wall's height, often extending below the local frost line to prevent heaving during winter. Skipping this step guarantees that the wall will settle unevenly or shift over time.

Selecting and Placing the Armor Stone
The choice of stone is where the project transitions from construction to craft. "Armor stone" implies durability, so selecting dense, non-porous rock such as granite, basalt, or quarry-faced stone is paramount. These materials resist weathering and erosion far better than sedimentary rocks like limestone. When placing the stones, the goal is to create a monolithic mass that appears natural but functions as a single, unified element. This requires a deliberate effort to stagger the vertical joints, much like the pattern of bricks in a standard wall, ensuring that the structure relies on interlocking friction rather than the adhesive strength of mortar.
- Begin the placement by positioning the largest stones at the base, as they provide the primary weight and resistance.
- Tightly interlock the stones, focusing on creating a stable configuration rather than achieving a uniform face.
- Fill the core of the wall with smaller, crushed stone and angular gravel.
- Vary the positioning of stones on the face to create a visually appealing, naturalistic profile.
Drainage: The Invisible Lifeline
Water is the silent adversary of any retaining wall. Hydrostatic pressure, the force exerted by saturated soil, can overwhelm even the most robust stone construction. Therefore, a high-performance drainage system is non-negotiable. This typically involves installing a perforated drainage pipe behind the wall, positioned at the base within the crushed stone layer. The pipe collects groundwater and directs it away from the structure, significantly reducing the pressure on the stone wall. Without this system, water has nowhere to go but through the wall, leading to cracks, bulging, or total collapse.
| Component | Purpose | Recommended Material |
|---|---|---|
| Crushed Stone Base | Provides stable foundation and drainage | 3/4-inch crushed stone or gravel |
| Retaining Wall Stone | Provides structural mass and aesthetic | Granite, Basalt, or Quarry-Faced Stone |
| Core Fill | Stabilizes the wall and adds mass | Angular crushed stone #57 |
| Drainage Pipe | Relieves hydrostatic pressure | 4-inch perforated PVC with fabric wrap |
| Backfill | Provides drainage and compaction | Clean angular gravel |
The Backfill and Finishing Touches
Once the wall is assembled and the drainage pipe is in place, the backfill process begins. This involves shoveling layers of clean, angular crushed stone into the space behind the wall. As you add each layer, it must be compacted with a plate compactor or a hand tamper. This compaction is vital because it transforms the loose stone into a solid mass that actively pushes back against the wall, counteracting the pressure of the retained soil. Continue this process of placing stone and compacting it until you reach the desired height, ensuring the backfill is slightly below the top of the wall stones to allow for the final capstone installation.

The final phase involves installing the capstones. These top stones act like a lid, sealing the top of the wall and preventing soil from washing into the core. They should be thick, flat, and heavy enough to resist displacement. Dry stack the capstones by applying a layer of mortar or simply by ensuring they are tightly interlocked and set in place. A properly installed capstone provides a clean, finished edge to the wall and protects the integrity of the structure beneath. With the capstones in place, the wall is complete, offering years of service while enhancing the natural beauty of the landscape.

![How To Build a Dry Stack Stone Wall and Backfill with Soil [Video]](https://i.pinimg.com/originals/1e/19/ce/1e19ce4415c1809dea100059a81b36ab.jpg)





















