5 Rammed Earth in Modern Construction

Image of a rammed earth wall in a modern construction.
A rammed earth wall forming part of the entrance building to the Eden Project in Dorset, England. Photograph by Andrew Dunn, 17 September 2005.

Introduction

Rammed earth, also known as ‘pise de terre’ or simply ‘pise’, is a construction technique used for building walls using raw materials such as earth, chalk, lime, or gravel. It is an ancient method that has been passed down through generations and is still in use today due to its sustainable properties and unique aesthetic appeal. The technique involves compacting dampened soil into an externally supported frame or mold, creating a solid, sturdy wall.

The use of rammed earth in architecture traces back thousands of years, with evidence found globally in diverse cultures and climates, from ancient China and the Middle East to the Mediterranean and even Native American structures in the Southwest United States. It thrived in regions where wood was scarce, but soil was abundant. Rammed earth’s prevalence declined during industrialization as concrete and steel became the preferred materials. However, a resurgence has been seen in recent years due to growing interest in sustainable and low-impact building practices. Today, both developing and developed countries appreciate the benefits of rammed earth for its eco-friendliness, aesthetic appeal, and thermal mass properties.

Properties and Benefits of Rammed Earth

Thermal Mass

Rammed earth boasts exceptional thermal mass, meaning it can absorb, store, and release heat over time. This property allows rammed earth buildings to naturally regulate indoor temperatures, staying cool in the summer and warm in the winter. The walls accumulate heat from the sun during the day and release it slowly at night, reducing the need for artificial heating and cooling systems, which contributes to energy efficiency and cost savings.

Sustainability

The sustainability of rammed earth is rooted in its raw materials: earth, clay, and sometimes a small amount of concrete for stabilization. These are often locally sourced, reducing transportation energy and promoting local economies. Furthermore, rammed earth construction produces minimal waste and does not require energy-intensive processes. The resulting structures are fully recyclable, aligning with circular economy principles.

Durability

Despite its humble composition, rammed earth is remarkably durable. Properly constructed and maintained rammed earth walls can last for hundreds, even thousands, of years – as evidenced by ancient structures still standing today. They are resistant to fire and pests, and when stabilized, can withstand weather and seismic activity. These durable qualities make rammed earth an excellent choice for long-term, resilient architecture.

Aesthetics

Surface detail of a rammed earth wall. Photograph by Andrew Dunn, 17 September 2005.
Surface detail of a rammed earth wall. Photograph by Andrew Dunn, 17 September 2005.

Rammed earth structures possess a unique aesthetic appeal. The method’s layer-by-layer construction often results in distinctive horizontal striations on the wall surfaces, akin to geological formations. The color and texture of the walls reflect the local soil, connecting the building to its immediate environment. This organic, earthy aesthetic is both timeless and versatile, complementing various architectural styles. Whether left exposed or finished with plasters or sealants, rammed earth walls contribute an unmatched tactile and visual quality to buildings.

Historical Overview of Rammed Earth in Architecture

Ancient Structures and Civilizations

Rammed earth was a significant building method in various ancient civilizations. In China, the Great Wall incorporated rammed earth in its construction, with sections dating back to the Ming Dynasty still standing today. Romans adopted this method in the Mediterranean, as evidenced by structures such as the Servian Walls. In the Americas, Native American tribes like the Pueblo people constructed multistory dwellings using similar earth-compaction techniques.

The Middle Ages

During the Middle Ages, rammed earth remained a popular construction method, especially in regions lacking timber or stone resources. In Europe, Spain and France witnessed a surge in pise structures. In Africa, the grand mosque of Djenné in Mali, a UNESCO World Heritage Site, stands as a testament to the endurance of this method, even though it follows a slightly different technique called adobe.

The Industrial Age and Rammed Earth Decline

With the Industrial Age’s onset, rammed earth’s popularity waned. Rapid urbanization, the rise of quicker and seemingly more efficient construction methods, and the availability of materials like steel, concrete, and brick led to its decline. The manual labor intensity of traditional rammed earth methods could not compete with the new, mechanized techniques, leading to a decrease in its usage in many parts of the world.

The Revival in the 20th Century

The late 20th century saw a revival of interest in rammed earth, spurred by a growing recognition of its environmental benefits and aesthetic qualities. Architects and builders started to explore and adapt rammed earth to modern construction standards, using technological advancements to overcome previous limitations. The use of soil stabilizers, mechanized ramming, and engineered formworks revitalized this ancient method, demonstrating its relevance in sustainable and contemporary architecture.

The Science Behind Rammed Earth

Soil Composition and Selection

The first step in rammed earth construction involves choosing the right soil composition. Ideally, the soil should have a balanced mix of sand, gravel, silt, and a small percentage of clay, typically around 10-15%. Clay acts as a natural binder, while the larger particles provide structure. Some builders add a small amount of cement or lime to the soil for extra stability. The selected soil should be free of organic materials to prevent decomposition within the wall. The soil’s source, color, and composition will significantly affect the final appearance and performance of the rammed earth wall.

The Ramming Process

Picture showing manual ramming of earth in metallic shutters. Photo taken in Sinai, Egypt.
Picture showing manual ramming of earth in metallic shutters. Photo taken in Sinai, Egypt. Image by Moshirah.

The ramming process is key to achieving a sturdy and durable rammed earth structure. It involves placing a damp mixture of soil into a formwork or mold, which is then compacted layer by layer using manual or pneumatic rammers. Each layer, typically about 15-20 cm thick when loose, is compacted down to around half its original height. This compaction process increases the soil’s density and, consequently, its strength and durability.

Curing and Strength

After ramming, the formwork is removed, revealing a solid wall that must then be left to cure. During the curing period, which can range from a few weeks to several months, depending on the climate, the wall continues to harden and gain strength. This is a crucial phase in the construction process, as premature loading or exposure to harsh weather conditions can damage the structure. The addition of stabilizers like cement can reduce the curing time and increase the overall strength of the wall.

Natural Insulation

While rammed earth has a high thermal mass, its insulative properties are relatively low. This means that while it can store and slowly release heat, it isn’t as efficient at preventing heat transfer through the wall. However, in temperate climates or when combined with passive solar design principles, this can be beneficial, keeping buildings cool in the summer and warm in the winter. In extreme climates, an insulation layer may be added within a rammed earth wall or on the exterior to improve its thermal performance. Despite this, the natural temperature regulation provided by rammed earth can greatly reduce reliance on artificial heating and cooling systems, thereby promoting energy efficiency.

Rammed Earth Construction Process

Site Preparation

Before construction begins, the site must be prepared. This includes removing vegetation and topsoil and ensuring the ground is level. The foundation is then laid, which can be made from a variety of materials, including concrete, stone, or stabilized rammed earth. The foundation must be deep enough to avoid frost heave in colder climates and provide a sturdy base for the walls. Furthermore, consideration is given to the site’s drainage to avoid water pooling near the base of the walls, which could lead to erosion or damage over time.

Mixing and Preparation of Rammed Earth

The soil, once selected, is thoroughly mixed with water until it reaches the right consistency for ramming – firm enough to hold shape but pliable enough to compact. If stabilizers such as cement or lime are used, they are mixed in during this step. The mix is then tested for compactability and strength. The preparation of the rammed earth mix is crucial as it influences the durability and overall performance of the final structure.

Ramming and Construction

Formworks are set up on top of the foundation and filled with the prepared soil mix. These formworks are rigid, reusable structures that hold the earth in place during ramming and provide the shape and finish of the walls. The soil is added in layers and compacted until it reaches about half of its loose thickness. Once a layer is thoroughly compacted, another layer is added and the process is repeated until the wall or section reaches the desired height. After each section is complete, the formwork is removed, moved along, and the process begins again.

Finishing and Curing

Upon completing the ramming process, the walls are left to cure. During this time, the walls continue to harden and gain strength. The length of the curing process can vary from a few weeks to several months, depending on the climate and the specific composition of the earth mix. After curing, the walls may be finished with a variety of treatments to enhance durability or aesthetics, such as applying a breathable sealer to protect against moisture or a clay plaster to add color. The finish can also leave the walls exposed to display the unique layers and textures created during the ramming process. The end result is a durable, sustainable structure with a distinctive aesthetic appeal.

Case Studies of Rammed Earth Structures

Residential Buildings

Rammed earth has seen a resurgence in residential construction due to its environmental benefits and aesthetic appeal. For example, the Casa Caldera is a notable example of using rammed earth in modern architecture. This unique off-grid house, designed by DUST, is located in the harsh desert of Arizona. The structure was built primarily with local materials, using rammed earth as the main component. The 945 sq ft house demonstrates how rammed earth provides excellent thermal mass, helping to mitigate the extreme desert temperatures. The earthen walls absorb heat during the day and release it at night, helping to maintain a stable indoor temperature. The house’s minimalist design perfectly showcases the beauty of raw rammed earth, blending the structure into the surrounding landscape. It’s a testament to sustainable and contextually aware design, showing how a building can be both eco-friendly and aesthetically pleasing. The house demonstrates how modern technologies can augment the traditional rammed earth technique, resulting in a sustainable, luxurious residence.

Public and Institutional Buildings

Desert Cultural Centre - main entry with rammed earth wall and hills of the Okanagan Desert behind.
Desert Cultural Centre – main entry with rammed earth wall and hills of the Okanagan Desert behind.

Rammed earth is not limited to residential use; it is also being adopted in public and institutional buildings. An example is the Nk’Mip Desert Cultural Centre in British Columbia, Canada. The building uses two-foot-thick rammed earth walls to create a natural cooling system essential in the desert environment. The design takes advantage of the inherent thermal mass properties of rammed earth, and the exterior showcases the beautiful stratified layers created by the technique.

Noteworthy International Examples

Internationally, rammed earth is being utilized to create stunning architectural examples. One notable project is the Great Wall of Western Australia, designed by Luigi Rosselli Architects. This large-scale rammed earth wall stretches over half a kilometer and contains twelve earth-covered residences designed to maintain stable indoor temperatures in the harsh Australian climate.

Another example is the Guelmim School of Technology in Morocco, designed by Saad El Kabbaj, Driss Kettani, and Mohamed Amine Siana. The building is constructed using locally sourced rammed earth and other traditional building materials, reducing its carbon footprint and connecting it to local architectural traditions. The rammed earth walls provide excellent insulation against the desert heat, and the structure itself serves as an inspiring example of sustainable architecture in an educational setting.

Challenges and Limitations of Rammed Earth

Weather Conditions and Location

While rammed earth is a versatile building material, its suitability can depend on specific weather conditions and location. In areas with high rainfall or humidity, special considerations and protective measures must be taken to prevent erosion or damage from moisture penetration. Similarly, additional structural reinforcement may be needed in areas prone to earthquakes. Furthermore, rammed earth relies heavily on the presence of suitable soil. In places where appropriate soil is not readily available, the cost and environmental impact of transporting it can negate some of the material’s sustainability benefits.

Material Availability and Quality

The availability and quality of the soil used in rammed earth construction can pose a challenge. A precise mix of sand, silt, clay, and possibly gravel is required for the best results. If the local soil does not naturally meet these requirements, amendments must be made. In addition, inconsistencies in soil composition can lead to variations in the structural properties and color of the rammed earth, which could affect the overall aesthetics and performance of the finished structure.

Skilled Labor

Rammed earth construction is a labor-intensive process that requires a skilled workforce. The preparation of the soil mix, setting of the formwork, ramming, and curing all need careful attention to detail to ensure the final structure is strong and durable. Despite advances in technology that have mechanized some aspects of the process, much of the work still requires hands-on craftsmanship. This can limit the speed of construction and increase costs compared to more conventional building methods. Furthermore, a lack of trained professionals in this method can pose a challenge to its broader adoption.

The Future of Rammed Earth in Architecture

Technological advancements are continuously shaping the future of rammed earth in architecture. Innovations in soil stabilization methods, formwork design, and ramming equipment have already improved rammed earth structures’ efficiency, strength, and durability. Developments in digital design and manufacturing technologies could potentially further streamline the design and construction process, reducing the need for manual labor and increasing precision. There’s also ongoing research in areas like seismic performance, thermal insulation improvements, and the incorporation of recycled materials into rammed earth mixtures.
The increasing awareness of the environmental impacts of the built environment is prompting a return to natural, locally sourced building materials, and rammed earth is a prime candidate. As sustainability becomes more central to architectural design and construction practices, the demand for materials like rammed earth, which boasts a low carbon footprint and high energy efficiency, is likely to rise. Rammed earth’s aesthetic appeal and unique tactile qualities can also offer an architectural language that speaks to sustainability and connection with the natural world.
While rammed earth is currently seen more often in high-end custom homes and unique public buildings, there’s potential for broader adoption in mainstream construction. As the benefits of rammed earth become more widely understood, and as techniques continue to evolve, it could become a more common choice for sustainable, resilient, and aesthetically pleasing buildings. Challenges such as labor costs, construction speed, and building code acceptance need to be addressed for this to occur. Yet, with increasing interest in green building strategies and sustainable living, the future looks promising for the widespread use of rammed earth in architecture.

Conclusion

This chapter has explored rammed earth as a sustainable and aesthetically pleasing construction technique, tracing its ancient roots to its modern adaptations. We have examined the unique properties and benefits of rammed earth, discussed its scientific basis, and illustrated its applications in diverse architectural projects. We have also acknowledged the challenges it poses and considered its future prospects in architecture.

The importance of rammed earth in sustainable architecture cannot be overstated. As we grapple with environmental challenges and strive to create a more sustainable built environment, techniques, like rammed earth, offer viable and attractive solutions. With its minimal environmental impact, excellent thermal performance, and aesthetic appeal, rammed earth presents a compelling case for locally sourced, low-impact, and durable construction. Its resurgence in contemporary architecture speaks to the enduring value of this age-old technique, marking it as an important player in the future of sustainable design and construction.

References:

1. Houben, H., & Guillaud, H. (1994). Earth Construction: A Comprehensive Guide. ITDG.
2. Keable, R. (2005). Rammed Earth: Design and Construction Guidelines. BRE Press.
3. McHenry, P. G. (1984). Adobe and Rammed Earth Buildings: Design and Construction. University of Arizona Press.
4. Minke, G. (2006). Building with Earth: Design and Technology of a Sustainable Architecture. Birkhäuser Architecture.
5. Moorhead, I. (2012). Rammed Earth: An Overview of a Sustainable Building Practice. Available at ResearchGate.
6. Walker, P., Keable, R., Martin, J., & Maniatidis, V. (2005). Rammed Earth: Design and Construction Guidelines. IHS BRE Press.
7. Watson, D., & Labs, K. (1983). Climatic Building Design: Energy-Efficient Building Principles and Practices. McGraw-Hill.

Please note that these are primarily book references. If you need peer-reviewed articles or web resources, those would need to be identified separately. As I’m an AI with a cutoff knowledge in 2021, it’s suggested to explore the most recent developments and studies in the field.