3D Printing Greener Buildings Using Local Soil

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The construction industry is currently facing two major challenges: the demand for sustainable infrastructure and the need to repair deteriorating buildings, bridges and roads. While concrete is the material of choice for many construction projects, it has a large carbon footprint, resulting in high waste and energy expenditure. Researchers report progress toward a sustainable building material made from local soil, using a 3D printer to create a load-bearing structure. For example, construction projects using extruded layers of concrete have highlighted the potential of additive manufacturing for building structures quickly and cheaply. However, concrete manufacturing is responsible for approximately 7% of carbon dioxide emissions according to the International Energy Agency, and cannot be recycled. An advantage to using local soil in construction is that the materials would not need to be manufactured and transported to the building site, reducing both costs and environmental damage. Banerjee and Bajpayee also say that additive manufacturing with soil could one day be used beyond Earth, to create settlements on the moon or even Mars.

Soil is typically classified by the layers of materials it comprises, beginning with the top organic layer where plants grow and ending at the hard bedrock of the earth’s crust. Beneath the initial organic layer is clay, which gives soil its plastic, moldable character that the researchers capitalized on in their project.

The researchers began by collecting soil samples from a colleague’s backyard and tailoring the material with a new environmentally friendly additive so that it would bind together and be easily extruded through the 3D printer. Because soils vary greatly by location, their aim was to have a chemistry “toolkit” that could transform any type of soil into printable building material. From there Bajpayee built small-scale test structures, cubes measuring two inches on each side, to see how the material performed when extruded into stacked layers.

The next step was to ensure that the mixture is load bearing, meaning that it will stand up to the weight of the layers but also other materials used in construction such as rebar and insulation. To help with this, the researchers strengthened the clay mixture by “zippering” the microscopic layers on its surface to prevent it from absorbing water and expanding, which would compromise the printed structure. With this method, the researchers showed that the material could hold twice as much weight as the unmodified clay mixture.

Next, the team plans to improve the soil’s load-bearing capabilities in order to scale up their test structures and get as close to a replacement for concrete as possible. In addition, they are gathering data to see whether these 3D printed structures are as environmentally friendly as they envision, especially in terms of carbon footprint and recycling potential. Once they have a better picture of the chemistry, functionality and feasibility of building with local soils, they plan to further explore how this technology can be used beyond our own planet.

The researchers acknowledge support and funding from the X-Grants Program at Texas A&M University.