Tree and forest functioning in an enriched CO<sub>2</sub> atmosphere

Saxe, Henrik; Ellsworth, David S.; Heath, James E.

doi:10.1046/j.1469-8137.1998.00221.x

Cited by 701 publications

(667 citation statements)

References 238 publications

Supporting

Mentioning

597

Contrasting

Unclassified

Order By: Relevance

“…This is in contrast to the positive effect of [CO # ] on coarse roots relative to fine roots found by Overdieck (1993) for F. sylvatica. With regard to water relations, a more relevant measure is perhaps the ratio of fine root (considered as functional root ; Barton, 1997) to assimilating area (Saxe et al, 1998). High [CO # ] significantly increased this ratio for F. sylvatica in the present study suggesting an increased ability to absorb water per unit leaf area.…”

Section: Effects On Plant Dimensionssupporting

confidence: 52%

Effects of tree size and temperature on relative growth rate and its components of Fagus sylvatica seedlings exposed to two partial pressures of atmospheric [CO₂]

Bruhn¹,

Leverenz²,

Saxe³

2000

New Phytologist

Self Cite

View full text Add to dashboard Cite

Growth responses of two provenances of European beech (Fagus sylvatica) were studied. The seedlings were grown in closed‐top chambers at four temperature regimes (−2.9 °C below ambient, ambient, +2.3 °C and +4.8 °C above ambient) in combination with two CO2 partial pressures (40 Pa and 74 Pa). Growth was followed by making destructive harvests c. every 25 d from germination in early June to senescence in late September. Allocation patterns were significantly affected by the temperature regimes. However, changes in dry matter allocation and morphology associated with the different treatments at a given time were mostly a result of differences in tree size. Temperature regimes only had a significant effect on the relative growth rate, RGR, at the beginning of the experiment. In contrast to temperature, high [CO2] increased RGR throughout the experiment when compared with plants of equal size. As the trees increased in size net assimilation rate, NAR, decreased but the effect of [CO2] on both NAR and RGR had a tendency to increase. Increases in NAR caused by elevated [CO2] were partly counteracted by reductions in the leaf area ratio, LAR. Reductions in LAR were caused by concomitant reductions in specific leaf area, SLA, whereas the level of [CO2] did not significantly affect leaf weight ratio, LWR, nor other dry weight ratios. The interactions between temperature and [CO2] are highly dependent on whether they are expressed as instantaneous values for plants at a common age or instantaneous values at a common size (and thereby extracting the effects of ontogenetic drift). When comparing instantaneous values at common sizes, the positive effect of [CO2] on RGR increased with plant size in every temperature regime. This also occurred in every temperature regime when comparing plants of equal age but the response to [CO2] was less. The effect of [CO2] on RGR was dependent on growth temperature. The positive effects of elevated [CO2] on RGR were less than the positive effect on photosynthesis. The two provenances did not differ significantly in the response of RGR to [CO2] which is in agreement with measurements of photosynthesis.

show abstract

Section: Effects On Plant Dimensionssupporting

confidence: 52%

Effects of tree size and temperature on relative growth rate and its components of Fagus sylvatica seedlings exposed to two partial pressures of atmospheric [CO₂]

Bruhn¹,

Leverenz²,

Saxe³

2000

New Phytologist

Self Cite

View full text Add to dashboard Cite

show abstract

“…Trees at high altitudes are also particularly sensitive to CO 2 enrichment, because they live in an atmosphere of lower partial pressure of CO 2 (Hattenschwiler et al, 2002). The current literature indicates a significantly larger average long-term biomass increment under elevated carbon dioxide for Pinaceae than for deciduous trees in studies not involving stress components (Saxe et al, 1998). New data on the effects of changing CO 2 on the evolution of the vegetation in Tibet are needed to evaluate the impact of decreasing atmospheric CO 2 levels on the studied flora.…”

Section: Discussionmentioning

confidence: 78%

A late Eocene palynological record of climate change and Tibetan Plateau uplift (Xining Basin, China)

Hoorn

Straathof

Abels

et al. 2012

Palaeogeography, Palaeoclimatology, Palaeoecology

120

103

View full text Add to dashboard Cite

General rightsIt is not permitted to download or to forward/distribute the text or part of it without the consent of the author(s) and/or copyright holder(s), other than for strictly personal, individual use, unless the work is under an open content license (like Creative Commons). Disclaimer/Complaints regulationsIf you believe that digital publication of certain material infringes any of your rights or (privacy) interests, please let the Library know, stating your reasons. In case of a legitimate complaint, the Library will make the material inaccessible and/or remove it from the website. Please Ask the Library: http://uba.uva.nl/en/contact, or a letter to: Library of the University of Amsterdam, Secretariat, Singel 425, 1012 WP Amsterdam, The Netherlands. You will be contacted as soon as possible. Climate models suggest that Asian paleoenvironments, monsoons and continental aridification were primarily governed by tectonic uplift and sea retreat since the Eocene with potential contribution of global climate changes. However, the cause and timing of these paleoenvironmental changes remain poorly constrained. The recently well-dated continental mudflat to ephemeral saline lake sedimentary succession, situated in the Xining Basin at the northeastern margin of the Tibetan Plateau (NW China), provides a unique opportunity to develop additional proxy successions in this area that are placed accurately in time. Here, a palynological record from this succession is reported. High abundances of desert and steppe-desert taxa such as Ephedripites and Nitrariadites/Nitraripollis are found, which can be differentiated by the presence of broad leaved deciduous forest taxa in the lower part of the section (particularly up to 36.4 Ma; magnetochron C16r), and a sudden increase of Pinaceae (Pinuspollenites, Piceaepollenites and Abiespollenites) which is dated at 36.1 Ma (C16n.2n). Coexistence Approach (CoA) indicates that from 39.9 to 36.4 Ma (C17n.1n) regional climate was warm and wet, while from 36.4 to 33.5 Ma (C16n.2n-C13r) climate tends to be cooler and drier. The data indicate that paleoenvironmental and palynological changes on the NE part of the Tibetan Plateau resulted from a combination of long-term tectonic uplift forcing and long-and short-term climate changes. The increase of taxa such as Piceaepollenites and Abiespollenites indicates not only a cooling and drying trend prior to the Eocene/Oligocene (E/O) boundary, but also the existence of high altitude mountain habitats in the periphery of the Xining Basin. The sudden Pinaceae event correlates closely in time with a marked aridification step as viewed from the lithology of the Xining Basin that was linked to the sea retreat out of the Tarim Basin.

show abstract

“…This is expected because CO 2 is a substrate for Rubisco, and higher CO 2 levels increase CO 2 : O 2 ratios, which reduces photorespiration (Saxe et al 1998;Curtis & Wang 1998). While most of these experiments have occurred in pots, and often using temperate species, increased growth has been demonstrated in situ for tropical tree seedlings (Wü rth et al 1998a).…”

Section: (I) Carbon Dioxide Effects On Light-use Efficiencymentioning

confidence: 99%

“…The general response of plants to this increase may be an increase in resource-use efficiency, especially higher rates of photosynthesis, which improves light-use efficiency, and decreasing stomatal conductance and transpiration, which improves water-use efficiency. In addition, any acclimation of photosynthesis to higher CO 2 concentrations would reduce key enzyme usage, notably Rubisco, increasing whole-plant nutrient-use efficiency (Drake et al 1997;Saxe et al 1998). We discuss the potential effects of rising CO 2 concentrations on light-use efficiency, water-use efficiency and nutrient-use efficiency in turn.…”

Section: (D ) Climatic Extremes/el Niñ O-southernmentioning

confidence: 99%

Fingerprinting the impacts of global change on tropical forests

Lewis

Malhi

Phillips

2004

Phil. Trans. R. Soc. Lond. B

221

252

View full text Add to dashboard Cite

Recent observations of widespread changes in mature tropical forests such as increasing tree growth, recruitment and mortality rates and increasing above-ground biomass suggest that 'global change' agents may be causing predictable changes in tropical forests. However, consensus over both the robustness of these changes and the environmental drivers that may be causing them is yet to emerge. This paper focuses on the second part of this debate. We review (i) the evidence that the physical, chemical and biological environment that tropical trees grow in has been altered over recent decades across large areas of the tropics, and (ii) the theoretical, experimental and observational evidence regarding the most likely effects of each of these changes on tropical forests. Ten potential widespread drivers of environmental change were identified: temperature, precipitation, solar radiation, climatic extremes (including El Niñ oSouthern Oscillation events), atmospheric CO 2 concentrations, nutrient deposition, O 3 /acid depositions, hunting, land-use change and increasing liana numbers. We note that each of these environmental changes is expected to leave a unique 'fingerprint' in tropical forests, as drivers directly force different processes, have different distributions in space and time and may affect some forests more than others (e.g. depending on soil fertility). Thus, in the third part of the paper we present testable a priori predictions of forest responses to assist ecologists in attributing particular changes in forests to particular causes across multiple datasets. Finally, we discuss how these drivers may change in the future and the possible consequences for tropical forests.

show abstract

Tree and forest functioning in an enriched CO₂ atmosphere

Cited by 701 publications

References 238 publications

Effects of tree size and temperature on relative growth rate and its components of Fagus sylvatica seedlings exposed to two partial pressures of atmospheric [CO₂]

Effects of tree size and temperature on relative growth rate and its components of Fagus sylvatica seedlings exposed to two partial pressures of atmospheric [CO₂]

A late Eocene palynological record of climate change and Tibetan Plateau uplift (Xining Basin, China)

Fingerprinting the impacts of global change on tropical forests

Contact Info

Product

Resources

About

Tree and forest functioning in an enriched CO2 atmosphere

Cited by 701 publications

References 238 publications

Effects of tree size and temperature on relative growth rate and its components of Fagus sylvatica seedlings exposed to two partial pressures of atmospheric [CO2]

Effects of tree size and temperature on relative growth rate and its components of Fagus sylvatica seedlings exposed to two partial pressures of atmospheric [CO2]

A late Eocene palynological record of climate change and Tibetan Plateau uplift (Xining Basin, China)

Fingerprinting the impacts of global change on tropical forests

Contact Info

Product

Resources

About

Tree and forest functioning in an enriched CO₂ atmosphere

Effects of tree size and temperature on relative growth rate and its components of Fagus sylvatica seedlings exposed to two partial pressures of atmospheric [CO₂]

Effects of tree size and temperature on relative growth rate and its components of Fagus sylvatica seedlings exposed to two partial pressures of atmospheric [CO₂]