In a groundbreaking study, scientists from Wageningen University & Research have achieved a significant milestone in space agriculture. Their pioneering research demonstrates that intercropping—the practice of growing different crops together—can significantly enhance plant growth on Martian soil under specific conditions. This development is crucial for securing the self-sustainability of future colonies on Mars.
Intercropping, an ancient agricultural method used on Earth for centuries, involves cultivating plants with complementary properties to support each other’s growth. This results in higher yields and more efficient use of resources such as water and nutrients. Given the limited resources available for the first Martian colonies, this approach may be vital for ensuring the sustainability of these extraterrestrial settlements.
The research team, led by astrobiologist Rebeca Gonçalves, Martian studies expert Dr. Wieger Wamelink, and agricultural systems expert Dr. Jochem Evers, conducted their experiments using peas, carrots, and tomatoes. These plants were grown in a type of Mars regolith simulant—a soil-like material created by NASA that closely matches the physical and chemical properties of real Martian soil. This simulant is also used by NASA to test rovers destined for Mars.
All three plant species thrived in the Martian regolith simulant, yielding over half a kilo of fresh produce with minimal nutrient additions. However, the most remarkable finding was that tomatoes performed significantly better when grown using intercropping techniques compared to traditional monocropping methods. The intercropped tomatoes exhibited substantial increases in both size and yield.
The success of intercropping in conserving resources could revolutionize the local production of fresh food during exploration missions. This would enhance food security and self-sustainability, essential for the independence of Martian colonies and the long-term human settlement on Mars and beyond.
Rebeca Gonçalves highlighted the broader implications of this research, stating, "An even greater aspect of this line of research is that all the technology developed for a self-sustainable colony on Mars, which includes soil regeneration techniques and the development of closed self-sufficient and self-sustainable systems, can be directly applied for the benefit of agricultural systems here on Earth."
Currently, 40% of Earth’s agricultural land has been degraded due to human activity or climate change, affecting approximately 1.5 billion people globally. Space agriculture research, such as this intercropping study, can offer critical insights into resilient agricultural practices on Earth, especially in arid and degraded soils.
The study also included a control treatment using sandy soil, which shares similar properties with degrading soils on Earth. The results were even more promising than with the Martian regolith, with intercropping significantly increasing yields for two of the three species tested and demonstrating a notable overall advantage compared to monocropping.
Gonçalves emphasized the transformative potential of this research: "I believe that this type of research holds extraordinary potential for providing out-of-the-box solutions that can significantly contribute to our joint efforts of tackling climate change and ensuring food security worldwide. If we can unlock the secret to regenerating poor soils while developing a high-yielding, self-sustainable food production system—exactly the goal of Martian agriculture research—we will have found a solution for two problems with a single strike.”
This study from Wageningen University & Research not only advances the possibilities of sustaining life on Mars but also offers promising solutions for improving agricultural practices and food security on Earth.
(Data Source: Wageningen University & Research)
