Overstory Community Composition and Elevated Atmospheric CO2 and O3 Modify Understory Biomass Production and Nitrogen Acquisition

Bandeff, Janet M.; Pregitzer, Kurt S.; Loya, Wendy M.; Holmes, William E.; Zak, Donald R.

doi:10.1007/s11104-005-5930-0

Cited by 17 publications

(16 citation statements)

References 35 publications

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“…Light is also generally considered to be one of the most important determinants of succession and composition of understorey plant communities (Canham, Finzi, Pacala, & Burbank, ; Facelli & Pickett, ; Reich, Frelich, Voldseth, Bakken, & Adair, ; Valladares & Niinemets, ). At Aspen FACE, for instance, eCO 2 was reported to have indirectly affected understorey species competition via increased tree canopy area and an associated reduction in light availability (Awmack et al., ; Bandeff et al., ). However, this was not the case in our study as there was no evidence that soil moisture (Figure ; Pathare et al., ), canopy leaf area or understorey light availability differed between CO 2 treatment (Duursma et al., ; Figure ).…”

Section: Discussionmentioning

confidence: 99%

“…For example, eCO 2 accelerated succession from an herbaceous‐ to a woody‐plant dominated community in a sweetgum plantation (Oak Ridge FACE) after 10 years of CO 2 fumigation (Belote, Weltzin, & Norby, ; Sanders, Belote, & Weltzin, ; Souza, Belote, Kardol, Weltzin, & Norby, ). In contrast, there was no evidence of a CO 2 effect on the relative abundance of contrasting PFGs in the understorey of a mixed aspen, birch and maple plantation following 2–6 years of CO 2 treatment at Aspen FACE (Awmack, Mondor, & Lindroth, ; Bandeff, Pregitzer, Loya, Holmes, & Zak, ) nor in a pine plantation at Duke FACE following 15 years of CO 2 fumigation (Kim, Oren, & Qian, ). Moreover, whilst the majority of large‐scale and long‐term eCO 2 studies have been conducted in Europe or USA in young plantations where nitrogen (N) is the primary limiting nutrient for plant growth (e.g.…”

Section: Introductionmentioning

confidence: 99%

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ElevatedCO₂concentrations reduce C₄cover and decrease diversity of understorey plant community in aEucalyptuswoodland

et al. 2018

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Compared to tree responses to elevated (e)CO2, little attention has been paid to understorey plant community responses in forest ecosystem studies, despite their critical role in nutrient cycling and the regeneration of overstorey species. Here, we present data on understorey responses from a 3‐year Free‐Air CO2 Enrichment experiment in a native, phosphorus‐limited Eucalyptus woodland in Australia (EucFACE). We conducted repeat surveys of the understorey plant community from 2012 to 2016, recording cover at the species level. Three years of eCO2 significantly decreased the diversity (Shannon‐Weaver; −30%) and species richness (−15%; c. −1 species per 4 m2 plot) of graminoid species, and the cover of C4 graminoids in both dominant (−38%) and subordinate (−48%) groups, relative to ambient conditions, leading to a significantly lower graminoid C4:C3 ratio (−59%) in the understorey plant community. The ratio of C4:C3 graminoids was negatively associated with soil nitrogen (N) availability suggesting that previously reported eCO2‐associated increases in N availability may contribute to (or be a consequence of) shifts in the composition of the graminoid community at the study site. There was, however, no effect of eCO2 on the diversity of forb species, which represented the most species‐rich functional group but only c. 1% of the understorey biomass. Synthesis. Our results suggest that eCO2 influences competition between C4 and C3 graminoid species both directly and indirectly via increasing N availability. The shift towards lower C4:C3 ratios and enhanced dominance by C3 species with their generally higher tissue N concentrations could further change soil nutrient availability and potentially accelerate community succession. Thus, eCO2 has altered the diversity and composition of the understorey plant community in this woodland, with the potential for cascading consequences for trophic interactions and ecosystem function.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

ElevatedCO₂concentrations reduce C₄cover and decrease diversity of understorey plant community in aEucalyptuswoodland

et al. 2018

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“…This effect is consistent with an earlier increase in the production of fine roots, which are ephemeral, under elevated O 3 in this community (Pregitzer et al ., ). Aside from this community × O 3 interaction, it is notable that none of the other previously observed treatment effects on fine root, groundcover, and leaf production (King et al ., ; Bandeff et al ., ; Pregitzer et al ., ; Talhelm et al ., , Table S3) influenced the relationship between cumulative NPP and the quantity of C in pools other than the mineral soil because these tissues represented approximately 40% of cumulative NPP.…”

Section: Discussionmentioning

confidence: 99%

Elevated carbon dioxide and ozone alter productivity and ecosystem carbon content in northern temperate forests

Talhelm

Pregitzer

Kubiske

et al. 2014

Global Change Biology

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Three young northern temperate forest communities in the north-central United States were exposed to factorial combinations of elevated carbon dioxide (CO2) and tropospheric ozone (O3) for 11 years. Here, we report results from an extensive sampling of plant biomass and soil conducted at the conclusion of the experiment that enabled us to estimate ecosystem carbon (C) content and cumulative net primary productivity (NPP). Elevated CO2 enhanced ecosystem C content by 11%, whereas elevated O3 decreased ecosystem C content by 9%. There was little variation in treatment effects on C content across communities and no meaningful interactions between CO2 and O3. Treatment effects on ecosystem C content resulted primarily from changes in the near-surface mineral soil and tree C, particularly differences in woody tissues. Excluding the mineral soil, cumulative NPP was a strong predictor of ecosystem C content (r2 = 0.96). Elevated CO2 enhanced cumulative NPP by 39%, a consequence of a 28% increase in canopy nitrogen (N) content (g N m−2) and a 28% increase in N productivity (NPP/canopy N). In contrast, elevated O3 lowered NPP by 10% because of a 21% decrease in canopy N, but did not impact N productivity. Consequently, as the marginal impact of canopy N on NPP (ΔNPP/ΔN) decreased through time with further canopy development, the O3 effect on NPP dissipated. Within the mineral soil, there was less C in the top 0.1 m of soil under elevated O3 and less soil C from 0.1 to 0.2 m in depth under elevated CO2. Overall, these results suggest that elevated CO2 may create a sustained increase in NPP, whereas the long-term effect of elevated O3 on NPP will be smaller than expected. However, changes in soil C are not well-understood and limit our ability to predict changes in ecosystem C content.

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“…Similarly, consistent with higher photosynthesis, elevated CO 2 in a L. styraciflua plantation increased aboveground biomass of understory vegetation by 25% (60% for woody saplings only) after 10 years of CO 2 enrichment, with the contribution of woody species increasing over time (Souza et al ., ). However, such CO 2 ‐induced response was not detected in stands of aspen ( Populus tremuloides ) and mixed aspen‐birch ( Betula papyrifera ) overstory (Aspen FACE; Bandeff et al ., ). At that site, both above‐ and belowground biomass of red clover ( Trifolium pratense ) decreased due to lower light levels under elevated CO 2 (Awmack et al ., ).…”

Section: Introductionmentioning

confidence: 98%

Response to CO₂ enrichment of understory vegetation in the shade of forests

Kim

Oren

Qian

2016

Global Change Biology

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Responses of forest ecosystems to increased atmospheric CO2 concentration have been studied in few free-air CO2 enrichment (FACE) experiments during last two decades. Most studies focused principally on the overstory trees with little attention given to understory vegetation. Despite its small contribution to total productivity of an ecosystem, understory vegetation plays an important role in predicting successional dynamics and future plant community composition. Thus, the response of understory vegetation in Pinus taeda plantation at the Duke Forest FACE site after 15-17 years of exposure to elevated CO2 , 6-13 of which with nitrogen (N) amendment, was examined. Aboveground biomass and density of the understory decreased across all treatments with increasing overstory leaf area index (LAI). However, the CO2 and N treatments had no effect on aboveground biomass, tree density, community composition, and the fraction of shade-tolerant species. The increases of overstory LAI (~28%) under elevated CO2 resulted in a reduction of light available to the understory (~18%) sufficient to nullify the expected growth-enhancing effect of elevated CO2 on understory vegetation.

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Overstory Community Composition and Elevated Atmospheric CO2 and O3 Modify Understory Biomass Production and Nitrogen Acquisition

Cited by 17 publications

References 35 publications

ElevatedCO₂concentrations reduce C₄cover and decrease diversity of understorey plant community in aEucalyptuswoodland

ElevatedCO₂concentrations reduce C₄cover and decrease diversity of understorey plant community in aEucalyptuswoodland

Elevated carbon dioxide and ozone alter productivity and ecosystem carbon content in northern temperate forests

Response to CO₂ enrichment of understory vegetation in the shade of forests

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Overstory Community Composition and Elevated Atmospheric CO2 and O3 Modify Understory Biomass Production and Nitrogen Acquisition

Cited by 17 publications

References 35 publications

ElevatedCO2concentrations reduce C4cover and decrease diversity of understorey plant community in aEucalyptuswoodland

ElevatedCO2concentrations reduce C4cover and decrease diversity of understorey plant community in aEucalyptuswoodland

Elevated carbon dioxide and ozone alter productivity and ecosystem carbon content in northern temperate forests

Response to CO2 enrichment of understory vegetation in the shade of forests

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ElevatedCO₂concentrations reduce C₄cover and decrease diversity of understorey plant community in aEucalyptuswoodland

ElevatedCO₂concentrations reduce C₄cover and decrease diversity of understorey plant community in aEucalyptuswoodland

Response to CO₂ enrichment of understory vegetation in the shade of forests