Your search keyword '"Richard P, Phillips"' showing total 8 results

1. Root‐derived inputs are major contributors to soil carbon in temperate forests, but vary by mycorrhizal type

Author

Adrienne B. Keller, Matthew E. Craig, Richard P. Phillips, Edward R. Brzostek, and Joshua B. Fisher

Subjects

0106 biological sciences, Nitrogen, Ecology, 010604 marine biology & hydrobiology, Flux, Soil carbon, Forests, Plant litter, Biology, Plant Roots, 010603 evolutionary biology, 01 natural sciences, Carbon, Trees, Soil, Agronomy, Mycorrhizae, Dominance (ecology), Arbuscular mycorrhizal, Temperate rainforest, Soil Microbiology, Ecology, Evolution, Behavior and Systematics

Abstract

Roots promote the formation of slow-cycling soil carbon (C), yet we have a limited understanding of the magnitude and controls on this flux. We hypothesised arbuscular mycorrhizal (AM)- and ectomycorrhizal (ECM)-associated trees would exhibit differences in root-derived C accumulation in the soil, and that much of this C would be transferred into mineral-associated pools. We installed δ13 C-enriched ingrowth cores across mycorrhizal gradients in six Eastern U.S. forests (n = 54 plots). Overall, root-derived C was 54% greater in AM versus ECM-dominated plots. This resulted in nearly twice as much root-derived C in putatively slow-cycling mineral-associated pools in AM compared to ECM plots. Given that our estimates of root-derived inputs were often equal to or greater than leaf litter inputs, our results suggest that variation in root-derived soil C accumulation due to tree mycorrhizal dominance may be a key control of soil C dynamics in forests.

Published

2021

2. Drought legacies are dependent on water table depth, wood anatomy and drought timing across the eastern US

Author

Justin T. Maxwell, Steven A. Kannenberg, Richard P. Phillips, Neil Pederson, Loïc D'Orangeville, and Darren L. Ficklin

Subjects

0106 biological sciences, Ecology, Water table, Climate Change, 010604 marine biology & hydrobiology, Carbon uptake, Water, Climate change, Edaphic, Forests, Wood, 010603 evolutionary biology, 01 natural sciences, Droughts, Trees, Forest ecology, Dendrochronology, Environmental science, Soil properties, Groundwater, Temperate rainforest, Ecology, Evolution, Behavior and Systematics

Abstract

Severe droughts can impart long-lasting legacies on forest ecosystems through lagged effects that hinder tree recovery and suppress whole-forest carbon uptake. However, the local climatic and edaphic factors that interact to affect drought legacies in temperate forests remain unknown. Here, we pair a dataset of 143 tree ring chronologies across the mesic forests of the eastern US with historical climate and local soil properties. We found legacy effects to be widespread, the magnitude of which increased markedly in diffuse porous species, sites with deep water tables, and in response to late-season droughts (August-September). Using an ensemble of downscaled climate projections, we additionally show that our sites are projected to drastically increase in water deficit and drought frequency by the end of the century, potentially increasing the size of legacy effects by up to 65% and acting as a significant process shaping forest composition, carbon uptake and mortality.

Published

2018

3. Feedbacks between plant N demand and rhizosphere priming depend on type of mycorrhizal association

Author

Elena Shevliakova, Benjamin N. Sulman, Duncan N. L. Menge, Chiara Medici, Richard P. Phillips, and Edward R. Brzostek

Subjects

0106 biological sciences, chemistry.chemical_classification, Rhizosphere, 010504 meteorology & atmospheric sciences, Ecology, Nitrogen, Soil organic matter, Soil carbon, Biology, 01 natural sciences, Trees, Soil, Nutrient, Agronomy, chemistry, Mycorrhizae, Organic matter, Ecosystem, Soil microbiology, Ecology, Evolution, Behavior and Systematics, Soil Microbiology, 010606 plant biology & botany, 0105 earth and related environmental sciences, Woody plant

Abstract

Ecosystem carbon (C) balance is hypothesised to be sensitive to the mycorrhizal strategies that plants use to acquire nutrients. To test this idea, we coupled an optimality-based plant nitrogen (N) acquisition model with a microbe-focused soil organic matter (SOM) model. The model accurately predicted rhizosphere processes and C-N dynamics across a gradient of stands varying in their relative abundance of arbuscular mycorrhizal (AM) and ectomycorrhizal (ECM) trees. When mycorrhizal dominance was switched - ECM trees dominating plots previously occupied by AM trees, and vice versa - legacy effects were apparent, with consequences for both C and N stocks in soil. Under elevated productivity, ECM trees enhanced decomposition more than AM trees via microbial priming of unprotected SOM. Collectively, our results show that ecosystem responses to global change may hinge on the balance between rhizosphere priming and SOM protection, and highlight the importance of dynamically linking plants and microbes in terrestrial biosphere models.

Published

2017

4. Increases in the flux of carbon belowground stimulate nitrogen uptake and sustain the long-term enhancement of forest productivity under elevated CO2

Author

Seth G. Pritchard, M. Luke McCormack, Richard P. Phillips, Sharon A. Billings, Kurt S. Johnsen, John E. Drake, Kirsten S. Hofmockel, Ram Oren, Robert B. Jackson, David J. P. Moore, Emily S. Bernhardt, John Lichter, Evan H. DeLucia, Sari Palmroth, Kathleen K. Treseder, Jeffrey S. Pippen, Adrien C. Finzi, Heather R. McCarthy, William H. Schlesinger, and Anne Gallet-Budynek

Subjects

0106 biological sciences, 2. Zero hunger, Biogeochemical cycle, 010504 meteorology & atmospheric sciences, Ecology, Chemistry, Primary production, 15. Life on land, Carbon sequestration, Photosynthesis, 01 natural sciences, Carbon cycle, chemistry.chemical_compound, 13. Climate action, Carbon dioxide, Ecosystem, Nitrogen cycle, Ecology, Evolution, Behavior and Systematics, 010606 plant biology & botany, 0105 earth and related environmental sciences

Abstract

The earth’s future climate state is highly dependent upon changes in terrestrial C storage in response to rising concentrations of atmospheric CO2. Here we show that consistently enhanced rates of net primary production (NPP) are sustained by a C-cascade through the root-microbe-soil system; increases in the flux of C belowground under elevated CO2 stimulated microbial activity, accelerated the rate of soil organic matter decomposition and stimulated tree uptake of N bound to this SOM. This process set into motion a positive feedback maintaining greater C gain under elevated CO2 as a result of increases in canopy N content and higher photosynthetic N-use efficiency. The ecosystem-level consequence of the enhanced requirement for N and the exchange of plant C for N belowground is the dominance of C storage in tree biomass but the preclusion of a large C sink in the soil.

Published

2011

5. Enhanced root exudation induces microbial feedbacks to N cycling in a pine forest under long-term CO2 fumigation

Author

Emily S. Bernhardt, Richard P. Phillips, and Adrien C. Finzi

Subjects

Rhizosphere, Ecology, Soil organic matter, Soil water, Fumigation, Growing season, Soil chemistry, Biology, Nitrogen cycle, Soil microbiology, Ecology, Evolution, Behavior and Systematics

Abstract

The degree to which rising atmospheric CO(2) will be offset by carbon (C) sequestration in forests depends in part on the capacity of trees and soil microbes to make physiological adjustments that can alleviate resource limitation. Here, we show for the first time that mature trees exposed to CO(2) enrichment increase the release of soluble C from roots to soil, and that such increases are coupled to the accelerated turnover of nitrogen (N) pools in the rhizosphere. Over the course of 3 years, we measured in situ rates of root exudation from 420 intact loblolly pine (Pinus taeda L.) roots. Trees fumigated with elevated CO(2) (200 p.p.m.v. over background) increased exudation rates (μg C cm(-1) root h(-1) ) by 55% during the primary growing season, leading to a 50% annual increase in dissolved organic inputs to fumigated forest soils. These increases in root-derived C were positively correlated with microbial release of extracellular enzymes involved in breakdown of organic N (R(2) = 0.66; P = 0.006) in the rhizosphere, indicating that exudation stimulated microbial activity and accelerated the rate of soil organic matter (SOM) turnover. In support of this conclusion, trees exposed to both elevated CO(2) and N fertilization did not increase exudation rates and had reduced enzyme activities in the rhizosphere. Collectively, our results provide field-based empirical support suggesting that sustained growth responses of forests to elevated CO(2) in low fertility soils are maintained by enhanced rates of microbial activity and N cycling fuelled by inputs of root-derived C. To the extent that increases in exudation also stimulate SOM decomposition, such changes may prevent soil C accumulation in forest ecosystems.

Published

2010

6. Roots and fungi accelerate carbon and nitrogen cycling in forests exposed to elevated CO2

Author

Emily S. Bernhardt, Ina C. Meier, A. Stuart Grandy, Kyle Wickings, Adrien C. Finzi, and Richard P. Phillips

Subjects

0106 biological sciences, Nitrogen, 01 natural sciences, Plant Roots, Carbon cycle, Carbon Cycle, Trees, chemistry.chemical_compound, Nitrogen cycle, Ecology, Evolution, Behavior and Systematics, Soil Microbiology, Rhizosphere, Ecology, Soil organic matter, Fungi, 04 agricultural and veterinary sciences, Soil carbon, 15. Life on land, Carbon Dioxide, Pinus, chemistry, Agronomy, Carbon dioxide, 040103 agronomy & agriculture, 0401 agriculture, forestry, and fisheries, Cycling, Soil microbiology, 010606 plant biology & botany

Abstract

A common finding in multiple CO(2) enrichment experiments in forests is the lack of soil carbon (C) accumulation owing to microbial priming of 'old' soil organic matter (SOM). However, soil C losses may also result from the accelerated turnover of 'young' microbial tissues that are rich in nitrogen (N) relative to bulk SOM. We measured root-induced changes in soil C dynamics in a pine forest exposed to elevated CO(2) and N enrichment by combining stable isotope analyses, molecular characterisations of SOM and microbial assays. We find strong evidence that the accelerated turnover of root-derived C under elevated CO(2) is sufficient in magnitude to offset increased belowground inputs. In addition, the C losses were associated with accelerated N cycling, suggesting that trees exposed to elevated CO(2) not only enhance N availability by stimulating microbial decomposition of SOM via priming but also increase the rate at which N cycles through microbial pools.

Published

2012

7. Increases in the flux of carbon belowground stimulate nitrogen uptake and sustain the long-term enhancement of forest productivity under elevated CO₂

Author

John E, Drake, Anne, Gallet-Budynek, Kirsten S, Hofmockel, Emily S, Bernhardt, Sharon A, Billings, Robert B, Jackson, Kurt S, Johnsen, John, Lichter, Heather R, McCarthy, M Luke, McCormack, David J P, Moore, Ram, Oren, Sari, Palmroth, Richard P, Phillips, Jeffrey S, Pippen, Seth G, Pritchard, Kathleen K, Treseder, William H, Schlesinger, Evan H, Delucia, and Adrien C, Finzi

Subjects

Nitrogen, Climate, North Carolina, Biomass, Carbon Dioxide, Nitrogen Cycle, Plant Roots, Carbon, Ecosystem, Soil Microbiology, Carbon Cycle, Trees

Abstract

The earth's future climate state is highly dependent upon changes in terrestrial C storage in response to rising concentrations of atmospheric CO₂. Here we show that consistently enhanced rates of net primary production (NPP) are sustained by a C-cascade through the root-microbe-soil system; increases in the flux of C belowground under elevated CO₂ stimulated microbial activity, accelerated the rate of soil organic matter decomposition and stimulated tree uptake of N bound to this SOM. This process set into motion a positive feedback maintaining greater C gain under elevated CO₂ as a result of increases in canopy N content and higher photosynthetic N-use efficiency. The ecosystem-level consequence of the enhanced requirement for N and the exchange of plant C for N belowground is the dominance of C storage in tree biomass but the preclusion of a large C sink in the soil.

Published

2011

8. Enhanced root exudation induces microbial feedbacks to N cycling in a pine forest under long-term CO2 fumigation

Author

Richard P, Phillips, Adrien C, Finzi, and Emily S, Bernhardt

Subjects

Soil, Nitrogen, Plant Exudates, Rhizosphere, North Carolina, Pinus taeda, Carbon Dioxide, Plant Roots, Carbon, Soil Microbiology, Trees

Abstract

The degree to which rising atmospheric CO(2) will be offset by carbon (C) sequestration in forests depends in part on the capacity of trees and soil microbes to make physiological adjustments that can alleviate resource limitation. Here, we show for the first time that mature trees exposed to CO(2) enrichment increase the release of soluble C from roots to soil, and that such increases are coupled to the accelerated turnover of nitrogen (N) pools in the rhizosphere. Over the course of 3 years, we measured in situ rates of root exudation from 420 intact loblolly pine (Pinus taeda L.) roots. Trees fumigated with elevated CO(2) (200 p.p.m.v. over background) increased exudation rates (μg C cm(-1) root h(-1) ) by 55% during the primary growing season, leading to a 50% annual increase in dissolved organic inputs to fumigated forest soils. These increases in root-derived C were positively correlated with microbial release of extracellular enzymes involved in breakdown of organic N (R(2) = 0.66; P = 0.006) in the rhizosphere, indicating that exudation stimulated microbial activity and accelerated the rate of soil organic matter (SOM) turnover. In support of this conclusion, trees exposed to both elevated CO(2) and N fertilization did not increase exudation rates and had reduced enzyme activities in the rhizosphere. Collectively, our results provide field-based empirical support suggesting that sustained growth responses of forests to elevated CO(2) in low fertility soils are maintained by enhanced rates of microbial activity and N cycling fuelled by inputs of root-derived C. To the extent that increases in exudation also stimulate SOM decomposition, such changes may prevent soil C accumulation in forest ecosystems.

Published

2010