Abstract
Background and aims
Root niche partitioning among trees/shrubs and grasses facilitates their coexistence in savannas, but little is known regarding root distribution patterns of co-occurring woody plants, and how they might differ on contrasting soils.
Methods
We quantified root distributions of co-occurring shrubs to 2 m on argillic and non-argillic soils.
Results
Root biomass in the two shrub communities was 3- to 5- fold greater than that in the grassland community. Prosopis glandulosa, the dominant overstory species was deep-rooted, while the dominant understory shrub, Zanthoxylum fagara, was shallow-rooted (47% vs. 25% of root density at depths >0.4 m). Shrubs on argillic soils had less aboveground and greater belowground mass than those on non-argillic soils. Root biomass and density on argillic soils was elevated at shallow (< 0.4 m) depths, whereas root density of the same species on non-argillic soils were skewed to depths >0.4 m. Root density decreased exponentially with increasing distance from woody patch perimeters.
Conclusions
Belowground biomass (carbon) pools increased markedly with grassland-to-shrubland state change. The presence/absence of a restrictive barrier had substantial effects on root distributions and above- vs. belowground biomass allocation. Differences in root distribution patterns of co-occurring woody species would facilitate their co-existence.
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Acknowledgements
This research was supported by NSF grant BSR-9109240, NASA grant NAGW-2662, NSF Doctoral Dissertation Improvement Grant DEB/DDIG-1600790, USDA/NIFA Hatch Project 1003961. Yong Zhou was supported by a Sid Kyle Graduate Merit Assistantship from the Department of Ecosystem Science and Management and a Tom Slick Graduate Research Fellowship from the College of Agriculture and Life Sciences, Texas A&M University. Stephen Watts was supported by a Regents’ Fellowship from the Office of Graduate and Professional Studies at Texas A&M University. We thank Rob Flinn and Dr. Stephen Zitzer for identification of woody plants and assistance with fieldwork; Dr. Lynn Loomis of USDA/NRCS for help with soil descriptions; and, Dr. Mike Longnecker of Department of Statistics at Texas A&M for help with statistical analyses. Several undergraduate students also contributed to the project, including Keith Beatty, Brian Hays, James Loughlin, Patty Mentch, Wesley Roark, and Marcus Simpson. Assistance with on-site logistics at the La Copita Research Area was provided by David and Stacy McKown.
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Zhou, Y., Watts, S.E., Boutton, T.W. et al. Root density distribution and biomass allocation of co-occurring woody plants on contrasting soils in a subtropical savanna parkland. Plant Soil 438, 263–279 (2019). https://doi.org/10.1007/s11104-019-04018-9
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DOI: https://doi.org/10.1007/s11104-019-04018-9