When planning a retaining wall, one of the first questions a homeowner or contractor asks is regarding the integration of mortar. Do you use mortar for retaining wall construction? The short answer is it depends, but for the vast majority of permanent, load-bearing structures, the answer is a resounding yes. Mortar is the binding agent that transforms individual stones or bricks into a cohesive, monolithic mass capable of withstanding immense lateral pressure from the soil behind it.
The Structural Role of Mortar
Unlike a dry-stacked rock wall, which relies purely on friction and interlocking shapes, a mortared retaining wall uses the mortar joints to distribute loads evenly across the entire structure. This is critical because the pressure from saturated soil exerts a horizontal force that tries to push the wall forward or downward. The mortar creates a rigid matrix that prevents individual units from sliding past one another. Without it, the wall is susceptible to settling, tilting, and ultimately failure, especially in taller installations where the hydrostatic pressure is significantly higher.
Interlocking vs. Mortar Jambs
It is a common misconception that all retaining walls must be mortared. In specific scenarios, such as low garden walls or temporary landscape structures, interlocking concrete blocks are designed to work without mortar. These systems utilize a combination of weight and friction to hold the wall in place. However, even in these cases, the use of mortar in the vertical joints (often referred to as "jumbo mortar joints") is highly recommended to increase stiffness and prevent the wall from becoming a run of distinct blocks that can separate over time.

When Mortar is Non-Negotiable
If your retaining wall exceeds three feet in height, is built close to a structure, or needs to retain significant fill, using mortar is not just a suggestion—it is an engineering requirement. Mortar provides the necessary shear strength that blocks alone cannot deliver. Furthermore, for walls that will be exposed to freezing and thawing cycles, the mortar helps seal the joints against water infiltration. Water seeping through dry joints can saturate the backfill, increasing pressure and accelerating the deterioration of the wall structure.
- Height and Load: Mortar is essential for walls over 3 feet tall or those holding dense soil.
- Vibration and Settlement: A mortared wall acts as a single unit, better resisting ground movement and vibration from nearby traffic.
- Aesthetic Integrity: Mortar creates a clean, uniform appearance that lasts, preventing the "staggered" look of dry-stack walls.
Material Compatibility and Application
Not all mortars are created equal when it comes to retaining walls. Standard Type N mortar, which is common for above-ground chimneys and brickwork, may not be sufficiently strong or flexible for underground applications. For retaining walls, masons typically specify Type S mortar. This blend contains a higher concentration of cement and is specifically engineered to withstand higher shear pressures. Additionally, the mortar should be applied consistently to ensure a full bed joint, which is vital for creating a waterproof barrier and maximizing the surface area of contact between the units.
Drainage: The Counterpart to Mortar2
While mortar provides the structural backbone, a retaining wall also requires a reliable drainage plan to relieve hydrostatic pressure. A common mistake is to mortar the entire wall solid without incorporating weep holes or a gravel backfill system. Modern retaining wall construction often involves placing a perforated drain pipe behind the wall, wrapped in a geotextile fabric, to direct water away from the structure. The mortar holds the wall up, but the drainage system ensures the water does not push the wall over.

The Verdict on Mortar Use
To directly answer the initial question: If you are building a permanent, functional retaining wall that prioritizes longevity and safety, using mortar is the standard practice. It transforms a simple stack of rocks or blocks into a engineered landscape feature. While the initial cost and complexity of mixing and laying mortar are higher than a dry-stack method, the return on investment is measured in decades of stability and resistance to the elements. Skipping mortar on a high wall is a risk that often leads to costly repairs or complete reconstruction.




















