| 1. |
- Barth, Sabine, 1974, et al.
(författare)
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Water-Use-Efficiency of Forests Exposed to Elevated Carbon Dioxide and/or Elevated Tropospheric Ozone
- 2009
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Ingår i: 8th International Carbon Dioxide Conference, Jena Germany, 13-19 September 2009.
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Konferensbidrag (övrigt vetenskapligt/konstnärligt)abstract
- Effects of a 40-50% increase of ambient CO2 and O3, alone and in combination, on pure aspen and mixed aspen-birch forests were examined in the free air CO2-O3 enrichment experiment near Rhinelander, Wisconsin, USA (Aspen FACE). These atmospheric conditions represent the prediction for 2050. Trees exposed to elevated CO2 showed a significant increase in tree size, leave area index (LAI) and fine root production, while elevated O3 reduced tree size and LAI but not fine root biomass after 7 years of exposure (King et al. 2005). Measurements of sap flux and yearly stem wood production were made in 2004 and 2006, after >6 years of experimental treatments and after steady-state LAI had been reached. Water use efficiency (WUE) was determined as a function of yearly stem wood production and sap flux during the active growing seasons, between DOY 168-249.
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| 2. |
- Uddling, Johan, 1972, et al.
(författare)
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Leaf and canopy conductance in aspen and aspen-birch forests under free-air enrichment of carbon dioxide and ozone
- 2009
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Ingår i: Tree Physiology. - : Oxford University Press (OUP). - 0829-318X .- 1758-4469. ; 29:11, s. 1367-1380
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Tidskriftsartikel (refereegranskat)abstract
- Increasing concentrations of atmospheric carbon dioxide (CO2) and tropospheric ozone (O-3) have the potential to affect tree physiology and structure, and hence forest feedbacks on climate. Here, we investigated how elevated concentrations of CO2 (+ 45%) and O-3 (+ 35%), alone and in combination, affected conductance for mass transfer at the leaf and canopy levels in pure aspen (Populus tremuloides Michx.) and in mixed aspen and birch (Betula papyrifera Marsh.) forests in the free-air CO2-O-3 enrichment experiment near Rhinelander, Wisconsin (Aspen FACE). The study was conducted during two growing seasons, when steady-state leaf area index (L) had been reached after > 6 years of exposure to CO2- and O-3-enrichment treatments. Canopy conductance (g(c)) was estimated from stand sap flux, while leaf-level conductance of sun leaves in the upper canopy was derived by three different and independent methods: sap flux and L in combination with vertical canopy modelling, leaf C-13 discrimination methodology in combination with photosynthesis modelling and leaf-level gas exchange. Regardless of the method used, the mean values of leaf-level conductance were higher in trees growing under elevated CO2 and/or O-3 than in trees growing in control plots, causing a CO2 x O-3 interaction that was statistically significant (P <= 0.10) for sap flux-and (for birch) C-13-derived leaf conductance. Canopy conductance was significantly increased by elevated CO2 but not significantly affected by elevated O-3. Investigation of a short-term gap in CO2 enrichment demonstrated a + 10% effect of transient exposure of elevated CO2-grown trees to ambient CO2 on g(c). All treatment effects were similar in pure aspen and mixed aspen-birch communities. These results demonstrate that short-term primary stomatal closure responses to elevated CO2 and O-3 were completely offset by long-term cumulative effects of these trace gases on tree and stand structure in determining canopy- and leaf-level conductance in pure aspen and mixed aspen-birch forests. Our results, together with the findings from other long-term FACE experiments with trees, suggest that model assumptions of large reductions in stomatal conductance under rising atmospheric CO2 are very uncertain for forests.
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| 3. |
- Uddling, Johan, 1972, et al.
(författare)
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Sap flux in pure aspen and mixed aspen-birch forests exposed to elevated concentrations of carbon dioxide and ozone
- 2008
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Ingår i: Tree Physiology. - 0829-318X. ; 28:8, s. 1231-1243
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Tidskriftsartikel (refereegranskat)abstract
- Elevated concentrations of atmospheric carbon dioxide ([CO2]) and tropospheric ozone ([O-3]) have the potential to affect tree physiology and structure and hence forest water use, which has implications for climate feedbacks. We investigated how a 40% increase above ambient values in [CO2] and [O-3], alone and in combination, affect tree water use of pure aspen and mixed aspen-birch forests in the free air CO2-O-3 enrichment experiment near Rhinelander, Wisconsin (Aspen FACE). Measurements of sap flux and canopy leaf area index (L) were made during two growing seasons, when steady-state L had been reached after more than 6 years of exposure to elevated [CO2] and [O-3]. Maximum stand-level sap flux wits not significantly affected by levated [O-3], but was increased by 18% by elevated [CO2] averaged across years, communities and O-3 regimes. Treatment effects were similar in pure aspen and mixed aspen-birch communities. Increased tree water use in response to elevated [CO2] was related to positive CO2 treatment effects on tree size and L (+40%). Tree water use was not reduced by elevated [O-3] despite strong negative O-3 treatment effects on tree size and L (-22%). Elevated [O-3] predisposed pure aspen stands to drought-induced Sap flux reductions, whereas increased tree water use in response to elevated [CO2] did not result in lower soil water content in the upper soil or decreasing sap flux relative to control values during dry periods. Maintenance of soil water content in the upper soil in the elevated [CO2] treatment was at least partly a function of enhanced soil water-holding capacity, probably a result of increased organic matter content from increased litter inputs. Our findings that larger trees growing in elevated [CO2] used more water and that tree size, but not maximal water use, was negatively affected by elevated [O-3] suggest that the long-term cumulative effects on stand Structure may be more important than the expected primary stomatal Closure responses to elevated [CO2] and [O-3] in determining stand-level water use under possible future atmospheric conditions.
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| 4. |
- Uddling, Johan, 1972, et al.
(författare)
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Stomatal O3 uptake of forest trees under rising atmospheric CO2 and tropospheric O3
- 2008
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Ingår i: Schaub M, Kaennel Dobbertin M, Steiner D (Eds) 2008. Air Pollution and Climate Change at Contrasting Altitude and Latitude. 23rd IUFRO Conference for Specialists in Air Pollution and Climate Change Effects on Forest Ecosystems. Murten, Switzerland, 7-12 Sept 2008. Abstracts. Birmensdorf, Swiss Federal Research Institute WSL. 162 pp..
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Konferensbidrag (övrigt vetenskapligt/konstnärligt)abstract
- The rise in concentrations of atmospheric CO2 ([CO2]) and tropospheric O3 ([O3]) observed in recent decades and predicted for coming decades may portend large alterations in plant canopy function. Stomata respond to increased intercellular [CO2] by partially closing, and stomatal conductance (gs) was consistently reduced by both elevated [CO2] and elevated [O3] in shorter-term experiments with plants grown in controlled environments or field chambers. Based on these findings, combined stomatal-photosynthesis models, predicting decreased gs in response to increased [CO2], have been incorporated into the third generation of land surface models that are used in general circulation models. Such models have been employed to predict improved ecosystem hydrology, increased continental runoff and reduced stomatal uptake of O3 under rising atmospheric [CO2]. The Aspen FACE experiment in Rhinelander, Wisconsin USA, offers a unique opportunity to study fully acclimated long-term tree responses to elevated [CO2] and [O3], alone and in combination, under ecologically realistic conditions. Contrary to expectations, stand-level tree water-use of pure aspen and mixed aspen-birch communities was increased under elevated [CO2] and not significantly affected by [O3] treatment after canopy closure (Uddling et al. 2008). Here, we report on treatment effects on gs estimated by three independent methods: leaf-level gas exchange, sap flux in combination with within canopy scaling, and leaf tissue stable carbon isotope composition in combination with photosynthesis modelling. Regardless of method used, gs was always lowest in the control treatment (ambient [CO2] and ambient [O3]), but the only statistically significant treatment effect was that elevated [CO2] increased carbon isotope-derived gs. These results contrast with expectations as well as reports of reduced gs in an early phase of the experiment (Noormets et al. 2001), and suggest that long-term cumulative effects on stand structure and hydraulic efficiency may be more important than expected primary stomatal closure responses to elevated [CO2] and [O3] for determining gs under possible future atmospheric conditions. Results from FACE studies with trees are reviewed with respect to gs and tree water use and it is concluded that expectations and predictions of reduced O3 sensitivity of forests under rising [CO2] are unduly optimistic.
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| 5. |
- Uddling, Johan, 1972, et al.
(författare)
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Stomatal uptake of O3 in aspen and aspen-birch forests under free-air CO2 and O3 enrichment
- 2010
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Ingår i: Environmental Pollution. - 0269-7491. ; 158:6, s. 2023-2031
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Tidskriftsartikel (refereegranskat)abstract
- Rising atmospheric carbon dioxide (CO2) may alleviate the toxicological impacts of concurrently rising tropospheric ozone (O3) during the present century if higher CO2 is accompanied by lower stomatal conductance (gs), as assumed by many models. We investigated how elevated concentrations of CO2 and O3, alone and in combination, affected the accumulated stomatal flux of O3 (AFst) by canopies and sun leaves in closed aspen and aspen-birch forests in the free-air CO2–O3 enrichment experiment near Rhinelander, Wisconsin. Stomatal conductance for O3 was derived from sap flux data and AFst was estimated either neglecting or accounting for the potential influence of non-stomatal leaf surface O3 deposition. Leaf-level AFst (AFstl) was not reduced by elevated CO2. Instead, there was a significant CO2 × O3 interaction on AFstl, as a consequence of lower values of gs in control plots and the combination treatment than in the two single-gas treatments. In addition, aspen leaves had higher AFstl than birch leaves, and estimates of AFstl were not very sensitive to non-stomatal leaf surface O3 deposition. Our results suggest that model projections of large CO2-induced reductions in gs alleviating the adverse effect of rising tropospheric O3 may not be reasonable for northern hardwood forests.
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