The first world map of underground fungal networks reveals a hidden 68 quadrillion-mile superhighway that helps maintain life on Earth and retailer carbon in the soil.
Beneath forests, grasslands, wetlands, and even many agricultural fields lies an unlimited underground fungal community that helps plants and performs an vital function in the world carbon cycle. Scientists have now created the first world maps displaying the place these networks are situated and the way a lot of them exist throughout the planet.
The analysis, revealed in the journal Science, focuses on arbuscular mycorrhizal fungi, generally referred to as AM fungi. Alongside the research, researchers launched an interactive visualization that reveals the immense scale of this hidden organic infrastructure. The new maps are anticipated to assist scientists and policymakers determine areas the place these fungal networks are flourishing and the place they might be in danger.
Among the research’s key findings:
- Global topsoils comprise about ~110 quadrillion kilometers of arbuscular mycorrhizal fungal community, which consists of microscopic tubular buildings known as hyphae. That distance is sort of a billion occasions the distance from Earth to the Sun.
- Grassland ecosystems comprise an estimated ~40% of Earth’s arbuscular mycorrhizal fungal infrastructure.
- Areas predicted to have particularly dense networks embody the flooded grasslands of South Sudan, Florida’s Everglades, and the Tibetan plateau.
- AM fungal networks transfer an estimated ~4 billion tons of CO2e into soils every year (equal to 11% of all human-related carbon dioxide emissions).
- Large-scale croplands are predicted to have community densities which are roughly ~50% decrease on common. Researchers be aware that further work is required to know how particular farming practices have an effect on fungal well being, however decreased community density might restrict a soil’s potential to retailer carbon, recycle vitamins, and stand up to environmental stress.
(*68*)Network structure of fungal mycelium. Mycelial structure varies throughout strains and species. Networks imaged at the AMOLF biophysics institute in Amsterdam. Credit: Corentin Bisot – VU Amsterdam, AMOLF Justin Stewart – SPUNMapping Earth’s Hidden Fungal Infrastructure
Arbuscular mycorrhizal fungi kind mutually useful partnerships with ~70% of plant species worldwide. Plants supply the fungi with carbon produced through photosynthesis, while the fungi provide water and nutrients in return.
These underground networks function as living infrastructure that supports ecosystems and helps transfer carbon into soils. Although researchers previously mapped global patterns of underground fungal biodiversity and created a digital resource called the Underground Atlas to identify likely biodiversity hotspots, no study had attempted to estimate and visualize the physical density and global distribution of AM fungal networks themselves.
To build the new maps, scientists compiled data from more than 16,000 soil cores collected around the world. They then used machine-learning models that incorporated environmental information from deserts, forests, tundra, and other ecosystems to estimate network density in regions that had not been directly sampled.
The team also collaborated with the Physics of Behavior group at the research institute AMOLF. Using robotic imaging, researchers analyzed more than 300,000 living AM fungal hyphae grown in laboratory conditions to help calibrate their models.
Based on these combined datasets, the researchers estimate that AM fungal networks span ~110 quadrillion kilometers globally and contain about 300 megatons of carbon (4-6x the mass of all living humans).
“It is hard to overstate the importance and enormity of these fungi,” said lead author Dr. Justin Stewart, with the Society for the Protection of Underground Networks (SPUN). “There could be up to 10 meters (32 feet) of mycorrhizal network in just a teaspoon of soil.”
A Hidden System Moving Carbon and Nutrients
Scientists often compare mycorrhizal networks to a planetary circulatory system because they transport carbon, water, and nutrients through underground ecosystems.
In healthy soils, these fungal networks can expand the effective reach of plant roots by as much as 100 times and supply more than 80 percent of a plant’s phosphorus needs.
“With the emergence of new technologies in high-resolution imaging, machine-learning and robotics, we are starting to reveal what has long been hidden under our feet,” said co-lead author, Dr. Corentin Bisot, an AMOLF biophysicist. “We are learning how the complex bodies of network-forming fungi transport nutrients and help regulate the climate.”
To help communicate the findings, the researchers partnered with award-winning data visualization designer Moritz Stefaner to create the Mycorrhizal Infrastructure Map.
The project offers the most detailed view yet of Earth’s fungal infrastructure, with estimates calculated for every 1 km2 of terrestrial land where sufficient data were available (excluding ice caps and areas lacking enough data to predict). The underlying data have also been made publicly available so governments and other decision-makers can begin monitoring the health of these critical underground communities.
Following Carbon Through Underground Networks
Several members of the research team previously published a Nature cover story examining how mycorrhizal fungi and plants form highly efficient biological trading networks that exchange carbon and nutrients.
That earlier work measured carbon movement through fungal transport systems at speeds reaching 120 um/sec (if one were inside the network, these speeds would feel like ~400km/hr).
The new study expands that work by helping researchers understand how these flows of carbon and nutrients operate at a planetary scale.
Threats to Fungal Networks
The findings also highlight potential risks to these underground systems.
The study predicts that mycorrhizal network densities in croplands are roughly half those found in wild ecosystems. Researchers also found that wild grasslands contain approximately ~40% of the world’s arbuscular mycorrhizal biomass.
At the same time, grasslands remain among the least-protected ecosystems on Earth and are being converted to agricultural land at four times the rate of forests.
The results support previous research by SPUN scientists showing that 95% of biodiversity hotspots for arbuscular mycorrhizal fungi lie outside protected areas.
For evolutionary biologist Dr. Toby Kiers, Executive Director of SPUN, these findings could help improve climate policy.
“Fungi have been ignored in climate and conservation for too long. Now is the time to change that trajectory.”
Kiers was recently named a MacArthur Fellow and received the Tyler Prize, often referred to as the “Nobel Prize for the Environment,” for her work on plant-fungal systems.
A Vast Underground World Still Largely Unknown
Despite revealing the extraordinary scale of Earth’s fungal networks, the researchers emphasize that much remains to be discovered.
“Mycorrhizal fungi have shaped life on Earth for hundreds of millions of years, but we still understand too little about how the infrastructure of these living transport systems is distributed across the planet,” added co-author and biologist Dr. Merlin Sheldrake. “This study is an exciting step towards understanding how this planetary circulatory system operates and suggests ways that we can better work with fungi to help address many of the unfolding challenges of our times, from food security to climate change.”
The study provides the most comprehensive estimate yet of the extent of AM fungal networks worldwide. At the same time, it highlights large regions that have not yet been sampled, underscoring how much of this vast underground world remains unexplored.
Reference: “Global density and biomass of arbuscular mycorrhizal fungal networks” by Justin D. Stewart, Corentin Bisot, Rachael I. M. Cargill, Michael E. Van Nuland, Heidi-Jayne Hawkins, Loreto Oyarte Galvez, Malin Klein, Marije van Son, Victoria Terry, Louis Paré, Claudia Banchini, Franck Stefani, Felix Kahane, Kai-Kai Lin, Renato K. Braghiere, Katie J. Field, Nadejda A. Soudzilovskaia, Jinsu Elhance, Vasilis Kokkoris, Merlin Sheldrake, James T. Weedon, Thomas S. Shimizu, Stuart West and E. Toby Kiers, 11 June 2026, Science.
DOI: 10.1126/science.adu4373
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