Foliar physiology of yellow-poplar ( Liriodendron tulipifera L.) exposed to O 3 and elevated CO 2 over five seasons.

Rebbeck, Joanne; Scherzer, Amy J.; Loats, Ken V.

doi:10.1007/s00468-003-0302-y

Cited by 10 publications

(6 citation statements)

References 51 publications

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“…When the O 3 effect is combined with the [CO 2 ] scenario, the O 3 -induced reductions are limited to 2-3% of GPP (calculations not shown). This attenuation of the O 3 response is consistent with experimental observations on a number of hardwood species (Broadmeadow et al, 1999;Karnosky et al, 2003;Rebbeck et al, 2004).…”

Section: Relative Importance Of Single Environmental Variablessupporting

confidence: 90%

Importance of changing CO₂, temperature, precipitation, and ozone on carbon and water cycles of an upland‐oak forest: incorporating experimental results into model simulations

Hanson

Wullschleger

Norby

et al. 2005

Global Change Biology

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Observed responses of upland-oak vegetation of the eastern deciduous hardwood forest to changing CO 2 , temperature, precipitation and tropospheric ozone (O 3 ) were derived from field studies and interpreted with a stand-level model for an 11-year range of environmental variation upon which scenarios of future environmental change were imposed. Scenarios for the year 2100 included elevated [CO 2 ] and [O 3 ] ( 1 385 ppm and 1 20 ppb, respectively), warming ( 1 4 1C), and increased winter precipitation ( 1 20% November-March). Simulations were run with and without adjustments for experimentally observed physiological and biomass adjustments.Initial simplistic model runs for single-factor changes in CO 2 and temperature predicted substantial increases ( 1 191% or 508 g C m À2 yr À1 ) or decreases (À206% or À549 g C m À2 yr À1 ), respectively, in mean annual net ecosystem carbon exchange (NEE a % 266 AE 23 g C m À2 yr À1 from 1993 to 2003). Conversely, single-factor changes in precipitation or O 3 had comparatively small effects on NEE a (0% and À35%, respectively). The combined influence of all four environmental changes yielded a 29% reduction in mean annual NEE a . These results suggested that future CO 2 -induced enhancements of gross photosynthesis would be largely offset by temperature-induced increases in respiration, exacerbation of water deficits, and O 3 -induced reductions in photosynthesis. However, when experimentally observed physiological adjustments were included in the simulations (e.g. acclimation of leaf respiration to warming), the combined influence of the year 2100 scenario resulted in a 20% increase in NEE a not a decrease. Consistent with the annual model's predictions, simulations with a forest succession model run for gradually changing conditions from 2000 to 2100 indicated an 11% increase in stand wood biomass in the future compared with current conditions. These model-based analyses identify critical areas of uncertainty for multivariate predictions of future ecosystem response, and underscore the importance of long term field experiments for the evaluation of acclimation and growth under complex environmental scenarios.

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Section: Relative Importance Of Single Environmental Variablessupporting

confidence: 90%

Importance of changing CO₂, temperature, precipitation, and ozone on carbon and water cycles of an upland‐oak forest: incorporating experimental results into model simulations

Hanson

Wullschleger

Norby

et al. 2005

Global Change Biology

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“…In general, increased growth under exposure to elevated CO 2 in most plants is caused by increased photosynthetic rates, individual leaf area, leaf area duration, and water‐use efficiency (Isebrands et al , 2001; Riikonen et al , 2004). O 3 inhibits growth by decreasing stomatal conductance and photosynthesis (Barnes et al , 1995; Kull et al , 1996; Noormets et al , 2001; Rebbeck et al , 2004), the amount and activity of ribulose‐1,5‐bisphosphate carboxylase/oxygenase (Rubisco) (Oksanen & Saleem, 1999; Noormets et al , 2001), and leaf surface area (Isebrands et al , 2001), and by inducing accelerated senescence of leaves (Kull et al , 1996; Riikonen et al , 2004). Studies of the combined effects of elevated CO 2 and O 3 show variable responses on photosynthesis (Barnes et al , 1995; Kull et al , 1996; Eichelmann et al , 2004; Rebbeck et al , 2004; Riikonen et al , 2005).…”

Section: Introductionmentioning

confidence: 99%

“…O 3 inhibits growth by decreasing stomatal conductance and photosynthesis (Barnes et al , 1995; Kull et al , 1996; Noormets et al , 2001; Rebbeck et al , 2004), the amount and activity of ribulose‐1,5‐bisphosphate carboxylase/oxygenase (Rubisco) (Oksanen & Saleem, 1999; Noormets et al , 2001), and leaf surface area (Isebrands et al , 2001), and by inducing accelerated senescence of leaves (Kull et al , 1996; Riikonen et al , 2004). Studies of the combined effects of elevated CO 2 and O 3 show variable responses on photosynthesis (Barnes et al , 1995; Kull et al , 1996; Eichelmann et al , 2004; Rebbeck et al , 2004; Riikonen et al , 2005). CO 2 has been reported to ameliorate the adverse effects of O 3 in Betula pendula and Liliodendron tulipifera (Eichelmann et al , 2004; Rebbeck et al , 2004; Riikonen et al , 2004, 2005).…”

Section: Introductionmentioning

confidence: 99%

Wood properties of two silver birch clones exposed to elevated CO₂ and O₃

Kostiainen

Jalkanen

Kaakinen

et al. 2006

Global Change Biology

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Effects of elevated carbon dioxide (CO 2 ) and ozone (O 3 ) on wood properties of two initially 7-year-old silver birch (Betula pendula Roth) clones were studied after a fumigation during three growing seasons. Forty trees, representing two fast-growing clones (4 and 80), were exposed in open-top chambers to the following treatments: outside control, chamber control, 2 Â ambient [CO 2 ], 2 Â ambient [O 3 ] and 2 Â ambientAfter the 3-year exposure, the trees were felled and wood properties were analyzed. The treatments affected both stem wood structure and chemistry. Elevated [CO 2 ] increased annual ring width, and concentrations of extractives and starch, and decreased concentrations of cellulose and gravimetric lignin. Elevated O 3 decreased vessel percentage and increased cell wall percentage in clone 80. In vessel percentage, elevated CO 2 ameliorated the O 3 -induced decrease. In clone 4, elevated O 3 decreased nitrogen concentration of wood. The two clones had different wood properties. In clone 4, the concentrations of extractives, starch, soluble sugars and nitrogen were greater than in clone 80, while in clone 80 the concentrations of cellulose and acid-soluble lignin were higher. Clone 4 also had slightly longer fibres, greater vessel lumen diameter and vessel percentage than clone 80, while in clone 80 cell wall percentage was greater. Our results show that wood properties of young silver birch trees were altered under elevated CO 2 in both clones, whereas the effects of O 3 depended on clone.

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“…Conversely, empirical studies using manipulative experiments largely suggest that wood biomass will not increase under the future combination of these forcings. For example, several studies investigating the interactions between elevated O 3 and CO 2 using chambers and FACE technology have found no net change in tree photosynthesis and growth (Karnosky et al, ; Loats & Rebbeck, ; Rebbeck et al, ) and decreases in stem biomass (Karnosky et al, ), results which are supported by a meta‐analysis (Wittig et al, ). While no empirical studies look at the combination of all the forcings considered here, the results of CLM4.5 simulations imply that increases in wood production may not keep pace with increased demand without targeted management strategies.…”

Section: Discussionmentioning

confidence: 91%

Changes in Wood Biomass and Crop Yields in Response to Projected CO₂, O₃, Nitrogen Deposition, and Climate

Lombardozzi

Bonan

Levis³

et al. 2018

JGR Biogeosciences

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As the world's population increases, so will the demand for food and timber resources. Though carbon dioxide (CO 2 ) fertilization and, to a lesser extent, nitrogen (N) deposition are expected to increase future resource production, changes in ozone (O 3 ) and climate have the potential to decrease production due to increased phytotoxic damage, drought, and heat stress. To determine how crop and timber production may change in the future, we use the Community Land Model version 4.5 with prognostic crops to simulate responses of wood biomass and crop yields to CO 2 , O 3 , N deposition, and climate under Representative Concentration Pathway 8.5 forcings. Generally, rising CO 2 increases wood biomass and crop yields, while projected climate change causes decreases. Small projected changes in O 3 and N deposition do not strongly affect yields, though additional research is needed on future O 3 and N deposition trends and impacts. By the end of the 21st century, global wood biomass increases by~16% due to the dominating impact of CO 2 . The positive effect of CO 2 on future crop yields is muted by the negative impacts of climate, with a~5% net global increase. Future projections suggest that rice and wheat yields typically increase under the combination of future forcings, whereas soy and corn yields are regionally variable. While short-term resource management strategies can benefit from planting heat-tolerant species and cultivars, technological advances and intensification, among other management strategies not included here, must be employed to meet the future demand for these resources.Plain Language Summary As the world's population increases, so will the demand for food and wood resources. Though these resources might increase due to the fertilizing effects of carbon dioxide (CO 2 ) and additional nitrogen (N) created by human sources, food and wood resources might decrease due to other environmental changes, like ground-level ozone (O 3 ), a toxic air pollutant, and climate, which can cause drought and heat stress. This study uses a global model to understand how food and wood resources may change in the future if there is no climate mitigation. Our results show that global wood biomass will increase by 16% and crop yields will increase by 5% at the end of the 21st century. While CO 2 increases wood biomass and crop yields, it does not always outweigh the negative effects of climate, especially for crops like soybean and corn. The future changes in O 3 and additional N were small and therefore did not change resource production very much. With the global food demand expected to increase by 65% and timber by 100%, these results suggest that resources may not increase enough to meet future demand unless additional, intensive management techniques are used, like expansion of managed area and irrigation, development of heat-and drought-tolerant crop and timber varieties, and other technological advances that can increase production in light of future environmental changes.

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Foliar physiology of yellow-poplar ( Liriodendron tulipifera L.) exposed to O 3 and elevated CO 2 over five seasons.

Cited by 10 publications

References 51 publications

Importance of changing CO₂, temperature, precipitation, and ozone on carbon and water cycles of an upland‐oak forest: incorporating experimental results into model simulations

Importance of changing CO₂, temperature, precipitation, and ozone on carbon and water cycles of an upland‐oak forest: incorporating experimental results into model simulations

Wood properties of two silver birch clones exposed to elevated CO₂ and O₃

Changes in Wood Biomass and Crop Yields in Response to Projected CO₂, O₃, Nitrogen Deposition, and Climate

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Foliar physiology of yellow-poplar ( Liriodendron tulipifera L.) exposed to O 3 and elevated CO 2 over five seasons.

Cited by 10 publications

References 51 publications

Importance of changing CO2, temperature, precipitation, and ozone on carbon and water cycles of an upland‐oak forest: incorporating experimental results into model simulations

Importance of changing CO2, temperature, precipitation, and ozone on carbon and water cycles of an upland‐oak forest: incorporating experimental results into model simulations

Wood properties of two silver birch clones exposed to elevated CO2 and O3

Changes in Wood Biomass and Crop Yields in Response to Projected CO2, O3, Nitrogen Deposition, and Climate

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Importance of changing CO₂, temperature, precipitation, and ozone on carbon and water cycles of an upland‐oak forest: incorporating experimental results into model simulations

Importance of changing CO₂, temperature, precipitation, and ozone on carbon and water cycles of an upland‐oak forest: incorporating experimental results into model simulations

Wood properties of two silver birch clones exposed to elevated CO₂ and O₃

Changes in Wood Biomass and Crop Yields in Response to Projected CO₂, O₃, Nitrogen Deposition, and Climate