Erica VanEss scite author profile

Erica VanEss

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Whole-seedling biomass allocation, leaf area, and tissue chemistry for Douglas-fir exposed to elevated CO₂ and temperature for 4 years

Olszyk¹,

Johnson²,

Tingey³

et al. 2003

Can. J. For. Res.

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Douglas-fir (Pseudotsuga menziesii (Mirb.) Franco) seedlings were grown under ambient or elevated (ambient + 180 µmol·mol -1 ) CO 2 and ambient or elevated (ambient + 3.5°C) temperature in outdoor, sunlit chambers with a field soil. After 4 years, seedlings were harvested and measured for leaf area, leaf, fine root (<1 mm diameter), and structural (buds, branches, stems, main root, and lateral roots >1 mm in diameter) dry masses, and leaf and fine root C/N ratio, percent sugar, and percent cellulose. Elevated CO 2 did not affect biomass production or allocation for any plant organ but increased specific leaf mass, leaf C/N ratio, and percent sugar and decreased the ratio of leaf area to structural weight and leaf percent cellulose. Elevated temperature tended to reduce biomass allocation to leaves and leaf sugar concentration. Fine root percent sugar tended to increase with elevated temperature but only at elevated CO 2 . Therefore, for Douglas-fir seedlings growing under naturally limiting soil moisture and nutrition conditions, elevated CO 2 and temperature may have little impact on biomass or leaf area except for reduced specific leaf mass with elevated CO 2 and reduced biomass allocation to leaves with elevated temperature. However, both elevated CO 2 and temperature may alter leaf chemistry.Résumé : Des semis de douglas (Pseudotsuga menziesii (Mirb.) Franco) ont été exposés à une concentration ambiante ou élevée (ambiante + 180 µmol·mol -1 ) de CO 2 et à une température ambiante ou élevée (ambiante + 3,5°C) à l'extérieur, à la lumière du soleil, dans des chambres contenant un sol provenant du terrain. Après 4 ans, les semis ont été récoltés et les mesures suivantes ont été effectuées : la surface foliaire, la masse sèche du feuillage, des racines fines (<1 mm de diamètre) et des éléments structuraux (bourgeons, branches, tige, racine principale et racines secondaires >1 mm de diamètre), le rapport C/N du feuillage et des racines fines ainsi que le pourcentage de sucres et de cellulose. La concentration élevée de CO 2 n'a pas influencé la production de biomasse ni l'allocation dans aucune partie du plant. Elle a par contre augmenté la masse spécifique du feuillage, le rapport C/N et le pourcentage de sucres dans les feuilles et diminué le rapport entre la surface foliaire et la masse des éléments structuraux ainsi que le pourcentage de cellulose dans les feuilles. La température élevée a eu tendance à réduire l'allocation de la biomasse vers le feuillage ainsi que la concentration des sucres dans les feuilles. Le pourcentage de sucres dans les racines fines a eu tendance à augmenter à la température élevée mais seulement lorsque la concentration de CO 2 était élevée. Par consé-quent, pour les semis de douglas qui croissent dans des conditions naturelles où l'humidité du sol et les nutriments sont limités, une température et une concentration en CO 2 élevées auraient peu d'impact sur la biomasse ou la surface foliaire à l'exception d'une diminution de la masse spécifique du feuillage avec une concentration éle...

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Elevated temperature but not elevated CO₂ affects long-term patterns of stem diameter and height of Douglas-fir seedlings

Olszyk¹,

Wise²,

VanEss³

et al. 1998

Can. J. For. Res.

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Global climatic change may impact forest productivity, but data are lacking on potential effects of elevated CO2 and temperature on tree growth. We determined changes in shoot growth for Douglas-fir (Pseudotsuga menziesii (Mirb.) Franco) seedlings exposed to ambient or elevated CO2 ( µmol·mol-1), and ambient or elevated temperature . Seedings were grown for 4 years (three complete growing seasons) in outdoor, sunlit chambers. In each season, height growth was initiated earlier and, in two seasons, ceased earlier for elevated compared with ambient temperature trees. Elevated temperature reduced intermediate and final plant heights. Stem diameter growth began earlier each season at the elevated compared with the ambient temperature, but temperature had no affect on final stem diameter. Elevated temperature tended to reduce leaf (p = 0.07) but not woody biomass. Elevated CO2 had no significant effects on stem diameter, height, and leaf or woody biomass, and there were no significant CO2 × temperature interactions. Thus, elevated temperatures (but not elevated CO2) associated with climate change may decrease seedling canopy growth as indicated by reduced height and leaf biomass but have little or no effect on overall woody growth as indicated by stem diameter and woody biomass.

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Phenology and growth of shoots, needles, and buds of Douglas-fir seedlings with elevated CO₂ and (or) temperature

Olszyk¹,

Wise²,

VanEss³

et al. 1998

Can. J. Bot.

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Increased atmospheric CO 2 and global warming may affect overall tree growth, but impacts of these combined stresses are largely unknown in terms of multiple growing season impacts on specific flushes. Thus, the effects of ambient or elevated CO 2 (approximately 200 µmol·mol -1 above ambient) and ambient or elevated temperature (approximately 4°C above ambient) were evaluated for both main and second (lammas) flushes of Douglas-fir (Pseudotsuga menziesii (Mirb.) Franco). Established seedlings were grown for three full growing seasons in outdoor, sunlit chambers, which maintained diel and seasonal variation in climate. A reconstructed forest soil was used with a seasonal wet and dry cycle and without added fertilizer. Compared with ambient CO 2 , elevated CO 2 had no impact on overall phenology and growth of terminal shoots, needles, or buds. In contrast, compared with ambient temperature, elevated temperature resulted in higher shoot and needle growth rates early in the season; reduced final terminal shoot length; and either reduced, increased, or unchanged final needle length, depending on season. Initiation of the lammas flush was delayed and (or) decreased at elevated temperature. Leading terminal bud break and growth occurred earlier; however, resting bud length was reduced, and bud width tended to increase with elevated temperature. Thus, at least during early seedling growth, elevated temperatures may reduce both main-and lammas-flush growth, thereby altering tree productivity, whereas elevated CO 2 may have little effect on main or lammas growth at either the current or elevated temperature.Résumé : L'augmentation du CO 2 atmosphérique et le réchauffement global peuvent affecter la croissance des arbres en général, mais on connait très mal les impacts de ces stress combinés en termes d'impacts au cours de plusieurs saisons sur les pousses spécifiques. Les auteurs ont évalué les effets de CO 2 ambiant et élevé (± 200 µmol mol -1 plus d'ambiant) et de température ambiante et élevée (± 4°C plus d'ambiante) sur les rameaux principaux et sur les rameaux de seconde venue (lammas) chez le douglas taxifolié (Pseudotsuga menziesii (Mirb.) Franco). Ils ont cultivé des plantules établies, pendant trois saisons de croissance complètes, dans des chambres situées à l'extérieur, naturellement illuminées et qui maintiennent la variation quotidienne et saisonnière du climat. Ils ont utilisé un sol forestier reconstitué et un cycle saisonnier d'humidité et de sécheresse, sans addition de fertilisant. Comparativement au CO 2 ambiant, l'augmentation du CO 2 n'a pas d'effet sur la phénologie générale et la croissance de la pousse terminale, des aiguilles et des bourgeons. Au contraire, comparativement à la température ambiante, la température élevée conduit à des taux accrus de croissance de la tige et des aiguilles tôt dans la saison, à une réduction de la longueur totale de la pousse terminale et réduit, augmente ou laisse inchangée la longueur finale des aiguilles, selon la saison. Le déclenchement des pousses de seconde ve...

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Elevated temperature but not elevated CO<sub>2</sub> affects long-term patterns of stem diameter and height of Douglas-fir seedlings

Olszyk¹,

Wise²,

VanEss³

et al. 1998

Revue canadienne de recherche forestière

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Phenology and growth of shoots, needles, and buds of Douglas-fir seedlings with elevated CO<sub>2</sub> and (or) temperature

Olszyk¹,

Wise²,

VanEss³

et al. 1998

Can. J. Bot.

View full text Add to dashboard Cite

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Erica VanEss

Whole-seedling biomass allocation, leaf area, and tissue chemistry for Douglas-fir exposed to elevated CO₂ and temperature for 4 years

Elevated temperature but not elevated CO₂ affects long-term patterns of stem diameter and height of Douglas-fir seedlings

Phenology and growth of shoots, needles, and buds of Douglas-fir seedlings with elevated CO₂ and (or) temperature

Elevated temperature but not elevated CO<sub>2</sub> affects long-term patterns of stem diameter and height of Douglas-fir seedlings

Phenology and growth of shoots, needles, and buds of Douglas-fir seedlings with elevated CO<sub>2</sub> and (or) temperature

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Erica VanEss

Whole-seedling biomass allocation, leaf area, and tissue chemistry for Douglas-fir exposed to elevated CO2 and temperature for 4 years

Elevated temperature but not elevated CO2 affects long-term patterns of stem diameter and height of Douglas-fir seedlings

Phenology and growth of shoots, needles, and buds of Douglas-fir seedlings with elevated CO2 and (or) temperature

Elevated temperature but not elevated CO<sub>2</sub> affects long-term patterns of stem diameter and height of Douglas-fir seedlings

Phenology and growth of shoots, needles, and buds of Douglas-fir seedlings with elevated CO<sub>2</sub> and (or) temperature

Contact Info

Product

Resources

About

Whole-seedling biomass allocation, leaf area, and tissue chemistry for Douglas-fir exposed to elevated CO₂ and temperature for 4 years

Elevated temperature but not elevated CO₂ affects long-term patterns of stem diameter and height of Douglas-fir seedlings

Phenology and growth of shoots, needles, and buds of Douglas-fir seedlings with elevated CO₂ and (or) temperature