Evaluating Ecohydrological Theories of Woody Root Distribution in the Kalahari

Bhattachan, Abinash; Tatlhego, Mokganedi; Dintwe, K.; O'Donnell, F. C.; Caylor, K. K.; Okin, Gregory S.; Perrot, Danielle; Ringrose, Susan; D’Odorico, Paolo

doi:10.1371/journal.pone.0033996

Cited by 36 publications

(24 citation statements)

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“…This disagreement can be resulted from several reasons. First, despite the large spatial scale in our study and other similar studies in dry regions [10], [11], [42], the climatic variations in these studies represent only a small fraction of the global climatic variations that are considered in global meta-analyses [12], [17]. Therefore, the differences in ecosystem-specific results and global syntheses reflect different ecological scales.…”

Section: Discussionmentioning

confidence: 70%

“…The biomass in dry and warm sites may not be sufficient to support frequent fires, whereas sites with more precipitation may have high fire frequencies due to more frequent lightning ignitions and available biomass fuels. As hypothesized by Bhattachan et al [42], high allocation to belowground due to the need for additional storage as the risk of fire increases may be an important life-history strategy for sites with high percipitation and high fire frequencies.…”

Section: Discussionmentioning

confidence: 88%

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Biomass and Its Allocation in Relation to Temperature, Precipitation, and Soil Nutrients in Inner Mongolia Grasslands, China

Kang

Dai

et al. 2013

PLoS ONE

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AimUnderstanding and predicting ecosystem functioning such as biomass accumulation requires an accurate assessment of large-scale patterns of biomass distribution and partitioning in relation to climatic and soil environments.MethodsWe sampled above- and belowground biomass from 26 sites spanning 1500 km in Inner Mongolian grasslands, compared the difference in aboveground, belowground biomass and below-aboveground biomass ratio (AGB, BGB, and B/A, respectively) among meadow steppe, typical steppe, and desert steppe types. The relationships between AGB, BGB, B/A and climatic and soil environments were then examined.ResultsWe found that AGB and BGB differed significantly among three types of grasslands while B/A did not differ. Structural equation model analyses indicated that mean annual precipitation was the strongest positive driver for AGB and BGB. AGB was also positively associated with soil organic carbon, whereas B/A was positively associated with total soil nitrogen.ConclusionsThese results indicated that precipitation positively influence plant production in Inner Mongolian grasslands. Contrary to the prediction from the optimal partitioning hypothesis, biomass allocation to belowground increased with soil total nitrogen, suggesting that more productive sites may increase belowground allocation as an adaptive strategy to potentially high fire frequencies.

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Section: Discussionmentioning

confidence: 70%

Section: Discussionmentioning

confidence: 88%

Biomass and Its Allocation in Relation to Temperature, Precipitation, and Soil Nutrients in Inner Mongolia Grasslands, China

Kang

Dai

et al. 2013

PLoS ONE

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“…Following the method of Bhattachan et al (2012) for analyzing the depth distribution of roots in biomass sampling pits, we fit a cumulative exponential distribution of root biomass abundance with depth to the individual root systems…”

Section: Discussionmentioning

confidence: 99%

“…It is the only site with sufficient biomass to support a fire regime, burning once every 5-10 years (Bhattachan et al 2012). The dominant woody species are Acacia mellifera, Acacia erioloba, Rhigozum trichotomum, and Boscia albitrunca.…”

Section: Study Sites and Species Excavatedmentioning

confidence: 99%

A quantitative description of the interspecies diversity of belowground structure in savanna woody plants

et al. 2015

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2015. A quantitative description of the interspecies diversity of belowground structure in savanna woody plants. Ecosphere 6(9):154. http:// dx.Abstract. The relative importance of resource competition and disturbance in limiting woody cover is one of the most basic questions in savanna ecology. Modeling approaches that seek to address this question are limited in their ability to accurately represent resource competition, which occurs belowground, by the limited detail of existing data on root system structure. Using compressed air, we excavated individual trees and shrubs and mapped their coarse roots on a three-dimensional grid system up to 1.5 m depth. We excavated four woody savanna species at three sites spanning a climate gradient on the Kalahari Transect in southern Africa and determined functions to describe the distribution of root biomass within the root systems. Overall, most of the variation in both large-scale and small-scale characteristics of root system structure was related to species. The species excavated fell into two groups that coexisted across the climate gradient. Acacia mellifera and Terminalia sericea had straight roots in a laterally extensive system that was shallow relative to the aggregate root profile for woody plants at the sites. Boscia albitrunca and Ochna pulchra had sinuous roots that were mostly concentrated beneath the canopy and were more prevalent in deep than near-surface soil layers, departing from the conventional model of decreasing root abundance with depth. Based on our results, we suggest a reframing of the theoretical characterization of the root zone used in modeling approaches to consider diversity within the woody plant community.

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“…Crassulacean acid metabolism plants are predominant in arid and semiarid environments (Withgott, ; Ogburn & Edwards, ), and thus, we parameterize this model with respect to environmental conditions with low (λ = 0.2/day and h = 5 mm) and moderate (λ = 0.2/dayand h = 10 mm) total rainfall amounts. Because this study investigates the facilitation or competition of CAM plants by woody plants, we assume that the growing seasons of trees and CAM plants coincide and last 210 days each year (e.g., Bhattachan et al, ). CAM plants typically have very shallow roots (e.g., Franco & Nobel, , ; Ogburn & Edwards, ), and thus, the root depth of CAM plants is taken to be constant ( Z 1 = 10 cm) in all the simulations.…”

Section: Methodsmentioning

confidence: 99%

From facilitative to competitive interactions between woody plants and plants with crassulacean acid metabolism (CAM): The role of hydraulic descent

D’Odorico

2016

Ecohydrology

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Woody plants may facilitate the establishment of seedlings with crassulacean acid metabolism (CAM) by ameliorating the abiotic environment through an increase in soil water availability. Because of the low transpiration rate in shallow‐rooted CAM plants and the consequently high soil water contents in the shallow soil, deep‐rooted trees in tree–CAM associations could perform hydraulic descent transporting water from wetter shallow soil to drier deep soil in arid environments. It remains unclear, however, whether a high rate of hydraulic descent can turn the facilitation of CAM plants by woody plants into competition. In this study, we develop a mechanistic model to investigate the facilitation of shallow‐rooted CAM plants by deep‐rooted woody plants in the access to soil water resources along a rainfall gradient. The model results show that in the case of low‐to‐moderate root overlap woody plants could facilitate CAM plants in access to soil water; this effect is mainly induced by the reduction in evaporation from the soil surface due to shading. Both shading and hydraulic descent decrease (or hydraulic lift increases) along a rainfall gradient, thereby favoring facilitation. Investment in deep roots by woody plants is usually thought to increase niche differentiation with shallow‐rooted plants, thereby reducing the competition and promoting species coexistence. This study indicates that deep root development could also favor competition through the mechanism of hydraulic descent, thereby changing our understanding of the role of root depth in niche differentiation between shallow and deep‐rooted plants.

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Evaluating Ecohydrological Theories of Woody Root Distribution in the Kalahari

Cited by 36 publications

References 70 publications

Biomass and Its Allocation in Relation to Temperature, Precipitation, and Soil Nutrients in Inner Mongolia Grasslands, China

Biomass and Its Allocation in Relation to Temperature, Precipitation, and Soil Nutrients in Inner Mongolia Grasslands, China

A quantitative description of the interspecies diversity of belowground structure in savanna woody plants

From facilitative to competitive interactions between woody plants and plants with crassulacean acid metabolism (CAM): The role of hydraulic descent

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