Litcius/Paper detail

A continental scale analysis reveals widespread root bimodality

Mingzhen Lu, Sili Wang, Avni Malhotra, Shersingh Joseph Tumber‐Dávila, Samantha R. Weintraub, Michael McCormack, Xingchen Wang, Robert B. Jackson

2025Nature Communications12 citationsDOIOpen Access PDF

Abstract

An improved understanding of root vertical distribution is crucial for assessing plant-soil-atmosphere interactions and their influence on the land carbon sink. Here, we analyze a continental-scale dataset of fine roots reaching 2 meters depth, spanning from Alaskan tundra to Puerto Rican forests. Contrary to the expectation that fine root abundance decays exponentially with depth, we found root bimodality at ~20% of 44 sites, with secondary biomass peaks often below 1 m. Root bimodality was more likely in areas with low total fine root biomass and was more frequent in shrublands than grasslands. Notably, secondary peaks coincided with high soil nitrogen content at depth. Our analyses suggest that deep soil nutrients tend to be underexploited, while root bimodality offers plants a mechanism to tap into deep soil resources. Our findings add to the growing recognition that deep soil dynamics are systematically overlooked, and calls for more research attention to this deep frontier in the face of global environmental change. This study shows that many plants form a second, deeper root layer underground, enabling access to nutrient-rich deep soil. This previously unnoticed rooting pattern adds to the growing recognition that deep soil dynamics are overlooked.

Topics & Concepts

BimodalityScale (ratio)Root (linguistics)BiologyEvolutionary biologyGeographyCartographyPhysicsGalaxyPhilosophyLinguisticsQuantum mechanicsGeology and Paleoclimatology ResearchPlant nutrient uptake and metabolismSoil Carbon and Nitrogen Dynamics
A continental scale analysis reveals widespread root bimodality | Litcius