Across the world, designers, engineers, researchers, and artists are turning to 3D printing as a powerful tool for environmental restoration and regenerative manufacturing. Once viewed primarily as a prototyping technology, additive manufacturing is now enabling solutions that support biodiversity, rebuild fragile ecosystems, and strengthen conservation efforts in places ranging from deserts and forests to rivers and coral reefs. From prosthetic tree hollows and biodegradable shelters for young plants, these projects demonstrate how digital design and locally tailored fabrication can address ecological challenges with precision and sustainability.
Prosthetic Tree Hollows in Australia
McConnell Dowell, together with Inland Rail and researchers at the University of Melbourne, has developed and installed 18 prosthetic tree hollows to support threatened bird and mammal species in central Victoria. Designed using laser scans of natural hollows, advanced computer modelling, and innovative materials such as 3D printed wood and mycelium, the project offers a more durable and biologically appropriate alternative to traditional nest boxes. As the first initiative of its kind globally, the effort demonstrates how modern fabrication technologies can be integrated into major infrastructure projects to enhance environmental conservation. Early monitoring is already helping researchers understand species behavior, providing valuable data that can guide future large-scale habitat restoration strategies.
(Photo Credit: McConnell Dowell)
3D Printed Marine Habitat Prototype
At the World Design Congress in London, Zaha Hadid Architects and D-Shape unveiled Nereid, a digital marine habitat designed to help restore coastal ecosystems, particularly within Hong Kong’s North Lantau Marine Park. The project aims to stimulate the growth of phytoplankton and filter-feeding mollusks, which form the foundation of the marine food chain, addressing biodiversity loss driven by climate change, urbanization, and pollution. Using 3D printing with low-emission concrete and pH-neutral materials, Nereid replicates the natural textures and porosity of coral reefs, creating safe, biomimetic structures that can be installed across a variety of coastal environments.
(Photo Credit: ZHA)
TreeSoil, a 3D Printed Shelter For Future Trees
Growing a tree or plant can be much more challenging in certain regions, especially in arid areas. Their early development is fragile, so protecting them is essential. This is the idea behind the TreeSoil project. It consists of soil-based shelters created using 3D printing, specifically with a robotic arm. Developed in Israel by the Technion Material Topology Research Lab, the project aims to shield young trees from wind, sun, and other environmental factors that could hinder their growth. The shelter is made from a mixture of clay, sand, organic fibers, and cellulose. Once printed, it is left to dry naturally and then assembled around the young tree without any adhesives. This makes it fully biodegradable and able to break down over time. After the tree has matured, the shelter naturally disintegrates and its nutrients are reabsorbed into the soil.
(Photo Credit: Edo Asoulin)
Coral Reef Tiles
Archireef is restoring damaged reefs using 3D-printed terracotta tiles shaped to resemble the surfaces corals naturally settle on. The tiles have soft, curved features that give young coral fragments a steady place to attach during the early weeks when they’re most vulnerable. For the Sino Group project in Hong Kong, teams placed hundreds of these tiles across a worn stretch of seabed, creating a new foothold for corals, fish, and other marine life to move back into. Because the tiles are lightweight and modular, divers can carry and arrange them by hand, avoiding heavy equipment in an area that’s already sensitive. The approach leans into the reality of reef restoration. Recovery is slow, and the design doesn’t try to rush it. Instead, the tiles create a stable foundation so the ecosystem can rebuild gradually, one fragment at a time.
(Photo Credit: Archireef)
Les Utopies Entomologiques: Ceramic Homes for Insects and Small Wildlife
The artist Raphaël Emine completed this whimsical project to create habitats for insects and small wildlife in forests. In collaboration with the 3D printing company WASP, Emine designed the structures by taking inspiration from the natural world. They used structural patterns found in honeycomb cells, worm and spider webs, plant fractals, and geodesic mineral formations to create the little buildings. The result is a series of small architectural marvels, complete with tunnels, galleries, balconies, and corridors that give the creatures a dynamic environment to live in. Emine created two installations of these projects, one in 2023 and one in 2024, using the WASP 40100 LDM and Delta WASP 2040 Clay. These were located in the Parc Maison Blanche in Marseille, France.
(Photo Credit: Raphaël Emine via yankodesign.com)
Desert Ark Reforestation Shelters in China
Desert Ark is a project by the Chinese design studio designRESERVE that also shows how 3D printing can support environmental restoration efforts in extreme regions. Installed in the Tengger Desert in Inner Mongolia, China, the complex consists of nine 3D-printed modules made from a mix of cement and sand, designed to house volunteers working on reforestation in the area. The components are produced in an off-site facility to ensure high print quality, then transported to the desert, where they can be assembled in just two days without the need for deep excavation. Each module serves a specific purpose, such as rest, cooking, dining, or sanitation, and features a wavy design with insulated walls capable of withstanding temperatures between –30 °C and 45 °C. The modules are arranged around a central terrace equipped with a retractable canopy and solar panels, so Desert Ark provides everything necessary to support ecological work in remote environments.
(Photo Credit: Huaer Lin, Yong Hu, ATDEF team/designboom)
3D Printed Calcium Carbonate Coral Skeletons
Researchers at KAUST have developed a new 3D printing approach aimed at accelerating coral reef restoration. Instead of relying on traditional concrete or metal substrates, the team created eco-friendly calcium carbonate structures that mimic natural coral skeletons, giving coral micro-fragments a head start in growth. Their CoraPrint method uses scanned coral geometries and custom calcium carbonate resin to produce non-toxic, highly detailed supports that can be seeded with live coral fragments. Early aquarium tests show promising results, positioning this technique as a potential step forward in sustainable reef recovery. The team now plans extended field trials, which could help determine how these printed structures perform under real ocean conditions and contribute to long-term reef resilience.
(Photo Credit: KAUST/Anastasia Serin)
C‑ecology Ceramic Habitats for Rivers
Created by students at Tunghai University, the C-ecology concept proposes using 3D-printed ceramic modules to form artificial coral-reef-like ecosystems that help revitalize urban rivers. Designed to adapt to waterways of various sizes, these eco-friendly structures create habitats for aquatic species while improving circulation and supporting ecological balance. Already recognized as a nominee for the 2022 Green Concept Award, the student team is now in the planning stages to bring the concept to real-world river environments, showcasing how additive manufacturing can drive innovative, sustainable urban water solutions. If implemented successfully, the system could serve as a scalable model for cities seeking nature-based solutions to restore biodiversity in heavily modified or polluted waterways.
(Photo Credit: Tunghai University / Green Project Award)
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