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1

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Altered root growth and plant chemistry ofPinus sylvestris seedlings subjected to aluminum in nutrient solution (1996)

Oleksyn, J. ; Karolewski, P. ; Giertych, M. J. ; [et al.]

Springer

Trees 10 (1996), S. 135-144

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ISSN: 1432-2285

Keywords: Scots pine ; Aluminum ; Pollution ; Photosynthesis ; Roots

Source: Springer Online Journal Archives 1860-2000

Topics: Biology , Agriculture, Forestry, Horticulture, Fishery, Domestic Science, Nutrition

Notes: Abstract One-year-old Scots pine (Pinus sylvestris L.) seedlings were grown for 9 weeks in nutrient solutions containing 0, 0.5, 1, 2 and 4 mM aluminum nitrate (Al(NO3)3) at pH 4.2. Nine weeks exposure to Al significantly reduced total plant, shoot and root mass and caused a linear decline in proportional allocation of biomass to roots. Relative growth rate of roots declined to as low as zero. Aluminum treatment decreased calcium and magnesium uptake and increased Al content in roots and needles. After 3 weeks of exposure a 10–60% increase in total phenols in roots and a 20–40% increase in o-diphenols in roots and needles were noted. Roots affected by Al showed degeneration of meristematic cells, fewer cell divisions, deformation in cell walls and higher lignification and suberization. The majority of root apices were structurally similar to dormant roots, and a premature senescence of the entire root system was observed. Net photosynthetic rate after 6 weeks of treatment was negatively correlated with needle Al content and Al/Ca ratio (r 〈 -0.9, P 〈 0.1). The results suggest that Scots pine may be more susceptible to Al than was expected based on previous experiments.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF02340765

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2

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Altered root growth and plant chemistry of Pinus sylvestris seedlings subjected to aluminum in nutrient solution (1996)

Oleksyn, J. ; Karolewski, P. ; Giertych, M. J. ; [et al.]

Springer

Trees 10 (1996), S. 135-144

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ISSN: 0931-1890

Keywords: Key words Scots pine ; Aluminum ; Pollution ; Photosynthesis ; Roots

Source: Springer Online Journal Archives 1860-2000

Topics: Biology , Agriculture, Forestry, Horticulture, Fishery, Domestic Science, Nutrition

Notes: Abstract One-year-old Scots pine (Pinus sylvestris L.) seedlings were grown for 9 weeks in nutrient solutions containing 0, 0.5, 1, 2 and 4 mM aluminum nitrate (Al(NO3)3) at pH 4.2. Nine weeks exposure to Al significantly reduced total plant, shoot and root mass and caused a linear decline in proportional allocation of biomass to roots. Relative growth rate of roots declined to as low as zero. Aluminum treatment decreased calcium and magnesium uptake and increased Al content in roots and needles. After 3 weeks of exposure a 10 – 60% increase in total phenols in roots and a 20 – 40% increase in o-diphenols in roots and needles were noted. Roots affected by Al showed degeneration of meristematic cells, fewer cell divisions, deformation in cell walls and higher lignification and suberization. The majority of root apices were structurally similar to dormant roots, and a premature senescence of the entire root system was observed. Net photosynthetic rate after 6 weeks of treatment was negatively correlated with needle Al content and Al/Ca ratio (r 〈 – 0.9, P 〈 0.1). The results suggest that Scots pine may be more susceptible to Al than was expected based on previous experiments.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/PL00009642

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Ontogenetic patterns of leaf CO2 exchange, morphology and chemistry in Betula pendula trees (2000)

Oleksyn, J. ; Żytkowiak, R. ; Reich, P. B. ; [et al.]

Springer

Trees 14 (2000), S. 271-281

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ISSN: 0931-1890

Keywords: Key words Betula pendula ; Photosynthesis ; Respiration ; Nutrients ; Leaf ontogeny

Source: Springer Online Journal Archives 1860-2000

Topics: Biology , Agriculture, Forestry, Horticulture, Fishery, Domestic Science, Nutrition

Notes: Abstract In order to explore ontogenetic variation in leaf-level physiological traits of Betula pendula trees, we measured changes in mass- (A mass) and area-based (A area) net photosynthesis under light-saturated conditions, mass- (RSmass) and area-based (RSarea) leaf respiration, relative growth rate, leaf mass per area (LMA), total nonstructural carbohydrates (TNC), and macro- and micronutrient concentrations. Expanding leaves maintained high rates of A area, but due to high growth respiration rates, net CO2 fixation occurred only at irradiances 〉200 µmol photons m–2 s–1. We found that full structural leaf development is not a necessary prerequisite for maintaining positive CO2 balance in young birch leaves. Maximum rates of A area were realized in late June and early July, whereas the highest values of A mass occurred in May and steadily declined thereafter. The maintenance respiration rate averaged ≈8 nmol CO2 g–1 s–1, whereas growth respiration varied between 0 and 65 nmol CO2 g–1 s–1. After reaching its lowest point in mid-June, leaf respiration increased gradually until the end of the growing season. Mass and area-based dark respiration were significantly positively correlated with LMA at stages of leaf maturity, and senescence. Concentrations of P and K decreased during leaf development and stabilized or increased during maturity, and concentrations of immobile elements such as Ca, Mn and B increased throughout the growing season. Identification of interrelations between leaf development, CO2 exchange, TNC and leaf nutrients allowed us to define factors related to ontogenetic variation in leaf-level physiological traits and can be helpful in establishing periods appropriate for sampling birch leaves for diagnostic purposes such as assessment of plant and site productivity or effects of biotic or abiotic factors.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/PL00009768

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Different photosynthesis-nitrogen relations in deciduous hardwood and evergreen coniferous tree species (1995)

Reich, P. B. ; Walters, M. B. ; Kloeppel, B. D. ; [et al.]

Springer

Oecologia 104 (1995), S. 24-30

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ISSN: 1432-1939

Keywords: Leaf life-span ; Evergreen ; Deciduous ; Photosynthesis ; Nitrogen

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Abstract The relationship between photosynthetic capacity (A max) and leaf nitrogen concentration (N) among all C3 species can be described roughly with one general equation, yet within that overall pattern species groups or individual species may have markedly different A max-N relationships. To determine whether one or several predictive, fundamental A max-N relationships exist for temperate trees we measured A max, specific leaf area (SLA) and N in 22 broad-leaved deciduous and 9 needle-leaved evergreen tree species in Wisconsin, United States. For broad-leaved deciduous trees, mass-based A max was highly correlated with leaf N (r 2=0.75, P〈0.001). For evergreen conifers, mass-based A max was also correlated with leaf N (r 2=0.59, P〈0.001) and the slope of the regression (rate of increase of A max per unit increase in N) was lower (P〈0.001) by two-thirds than in the broad-leaved species (1.9 vs. 6.4 μmol CO2 g−1 N s−1), consistent with predictions based on tropical rain forest trees of short vs. long leaf life-span. On an area basis, there was a strong A max-N correlation among deciduous species (r 2=0.78, P〈0.001) and no correlation (r 2=0.03, P〉0.25) in the evergreen conifers. Compared to deciduous trees at a common leaf N (mass or area basis), evergreen trees had lower A max and SLA. For all data pooled, both leaf N and A max on a mass basis were correlated (r 2=0.6) with SLA; in contrast, area-based leaf N scaled tightly with SLA (r 2=0.81), but area-based A max did not (r 2=0.06) because of low A max per unit N in the evergreen conifers. Multiple regression analysis of all data pooled showed that both N (mass or area basis) and SLA were significantly (P〈0.001) related to A max on mass (r 2=0.80) and area (r 2=0.55) bases, respectively. These results provide further evidence that A max-N relationships are fundamentally different for ecologically distinct species groups with differing suites of foliage characteristics: species with long leaf life-spans and low SLA, whether broad-leaved or needle-leaved, tend to have lower A max per unit leaf N and a lower slope and higher intercept of the A max-N relation than do species with shorter leaf life-span and higher SLA. A single global A max-N equation overestimates and underestimates A max for temperate trees at the upper and lower end of their leaf N range, respectively. Users of A max-N relationships in modeling photosynthesis in different ecosystems should appreciate the strengths and limitations of regression equations based on different species groupings.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00365558

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5

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Canopy structure and vertical patterns of photosynthesis and related leaf traits in a deciduous forest (1993)

Ellsworth, D. S. ; Reich, P. B.

Springer

Oecologia 96 (1993), S. 169-178

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ISSN: 1432-1939

Keywords: Acer saccharum ; Photosynthesis ; Forest canopy ; Sugar maple ; Nitrogen

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Abstract Canopy structure and light interception were measured in an 18-m tall, closed canopy deciduous forest of sugar maple (Acer saccharum) in southwestern Wisconsin, USA, and related to leaf structural characteristics, N content, and leaf photosynthetic capacity. Light attenuation in the forest occurred primarily in the upper and middle portions of the canopy. Forest stand leaf area index (LAI) and its distribution with respect to canopy height were estimated from canopy transmittance values independently verified with a combined leaf litterfall and point-intersect method. Leaf mass, N and A max per unit area (LMA, N/area and A max/area, respectively) all decreased continuously by over two-fold from the upper to lower canopy, and these traits were strongly correlated with cumulative leaf area above the leaf position in the canopy. In contrast, neither N concentration nor A max per unit mass varied significantly in relation to the vertical canopy gradient. Since leaf N concentration showed no consistent pattern with respect to canopy position, the observed vertical pattern in N/area is a direct consequence of vertical variation of LMA. N/area and LMA were strongly correlated with A max/area among different canopy positions (r2=0.81 and r2=0.66, respectively), indicating that vertical variation in area-based photosynthetic capacity can also be attributed to variation in LMA. A model of whole-canopy photosynthesis was used to show that observed or hypothetical canopy mass distributions toward higher LMA (and hence higher N/area) in the upper portions of the canopy tended to increase integrated daily canopy photosynthesis over other LMA distribution patterns. Empirical relationships between leaf and canopy-level characteristics may help resolve problems associated with scaling gas exchange measurements made at the leaf level to the individual tree crown and forest canopy-level.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00317729

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Relative growth rate in relation to physiological and morphological traits for northern hardwood tree seedlings: species, light environment and ontogenetic considerations (1993)

Walters, M. B. ; Kruger, E. L. ; Reich, P. B.

Springer

Oecologia 96 (1993), S. 219-231

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ISSN: 1432-1939

Keywords: Relative growth rate ; Leaf allocation ; Photosynthesis ; Respiration ; Ontogeny

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Abstract The influence of ontogeny, light environment and species on relationships of relative growth rate (RGR) to physiological and morphological traits were examined for first-year northern hardwood tree seedlings. Three Betulaceae species (Betula papyrifera, Betula alleghaniensis and Ostrya virginiana) were grown in high and low light and Quercus rubra and Acer saccharum were grown only in high light. Plant traits were determined at four ages: 41, 62, 83 and 104 days after germination. In high light (610 μmol m−2 s−1 PPFD), across species and ages, RGR was positively related to the proportion of the plant in leaves (leaf weight ratio, LWR; leaf area ratio, LAR), in situ rates of average canopy net photosynthesis (A) per unit mass (Amass) and per unit area (Aarea), and rates of leaf, stem and root respiration. In low light (127 μmol m−2 s−1 PPFD), RGR was not correlated with Amass and Aarea whereas RGR was positively correlated with LAR, LWR, and rates of root and stem respiration. RGR was negatively correlated with leaf mass per area in both high and low light. Across light levels, relationships of CO2 exchange and morphological characteristics with RGR were generally weaker than within light environments. Moreover, relationships were weaker for plant parameters containing a leaf area component (leaf mass per area, LAR and Aarea), than those that were solely mass-based (respiration rates, LWR and Amass). Across light environments, parameters incorporating the proportion of the plant in leaves and rates of photosynthesis explained a greater amount of variation in RGR (e.g. LWR*Amass, R2=0.64) than did any single parameter related to whole-plant carbon gain. RGR generally declined with age and mass, which were used as scalars of ontogeny. LWR (and LAR) also declined for seven of the eight species-light treatments and A declined in four of the five species in high light. Decreasing LWR and A with ontogeny may have been partially responsible for decreasing RGR. Declines in RGR were not due to increased respiration resulting from an increase in the proportion of solely respiring tissue (roots and stems). In general, although LWR declined with ontogeny, specific rates of leaf, stem, and root respiration also decreased. The net result was that whole-plant respiration rates per unit leaf mass decreased for all eight treatments. Identifying the major determinants of variation in growth (e.g. LWR*Amass) across light environments, species and ontogeny contributes to the establishment of a framework for exploring limits to productivity and the nature of ecological success as measured by growth. The generality of these relationships both across the sources of variation we explored here and across other sources of variation in RGR needs further study.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00317735

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Growth, biomass distribution and CO2 exchange of northern hardwood seedlings in high and low light: relationships with successional status and shade tolerance (1993)

Walters, M. B. ; Kruger, E. L. ; Reich, P. B.

Springer

Oecologia 94 (1993), S. 7-16

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ISSN: 1432-1939

Keywords: Relative growth rate ; Photosynthesis ; Respiration ; Biomass distribution ; Shade tolerance

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Abstract The physiology, morphology and growth of first-year Betula papyrifera Marsh., Betula alleghaniensis Britton, Ostrya virginiana (Mill.) K. Koch, Acer saccharum Marsh., and Quercus rubra L. seedlings, which differ widely in reported successional affinity and shade tolerance, were compared in a controlled high-resource environment. Relative to late-successional, shade-tolerant Acer and Ostrya species, early-successional, shade-intolerant Betula species had high relative growth rates (RGR) and high rates of photosynthesis, nitrogen uptake and respiration when grown in high light. Fire-adapted Quercus rubra had intermediate photosynthetic rates, but had the lowest RGR and leaf area ratio and the highest root weight ratio of any species. Interspecific variation in RGR in high light was positively correlated with allocation to leaves and rates of photosynthesis and respiration, and negatively related to seed mass and leaf mass per unit area. Despite higher respiration rates, early-successional Betula papyrifera lost a lower percentage of daily photosynthetic CO2 gain to respiration than other species in high light. A subset comprised of the three Betulaceae family members was also grown in low light. As in high light, low-light grown Betula species had higher growth rates than tolerant Ostrya virainiana. The rapid growth habit of sarly-successional species in low light was associated with a higher proportion of biomass distributed to leaves, lower leaf mass per unit area, a lower proportion of biomass in roots, and a greater height per unit stem mass. Variation in these traits is discussed in terms of reported species ecologies in a resource availability context.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00317294

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Photosynthesis-nitrogen relations in Amazonian tree species (1994)

Reich, P. B. ; Walters, M. B.

Springer

Oecologia 97 (1994), S. 73-81

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ISSN: 1432-1939

Keywords: Specific leaf area ; Rain forests ; Photosynthesis ; Nitrogen

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Abstract The relationships between leaf nitrogen (N), specific leaf area (SLA) (an inverse index of leaf “thickness” or “density”), and photosynthetic capacity (Amax) were studied in 23 Amazonian tree species to characterize scaling in these properties among natural populations of leaves of different ages and light microenvironments, and to examine how variation within species in N and SLA can influence the expression of the Amax-to-N relationship on mass versus area bases. The slope of the Amax-N relationship, change in A per change in N (μmol CO2 gN-1 s-1), was consistently greater, by as much as 300%, when both measures were expressed on mass rather than area bases. The x-intercept of this relationship (N-compensation point) was generally positive on a mass but not an area basis. In this paper we address the causes and implications of such differences. Significant linear relationships (p〈0.05) between mass-based leaf N (Nmass) and SLA were observed in 12 species and all 23 regressions had positive slopes. In 13 species, mass-based Amax (Amass) was positively related (p〈0.05) with SLA. These patterns reflect the concurrent decline in Nmass and SLA with increasing leaf age. Significant (p〈0.05) relationships between area-based leaf N (Narea) and SLA were observed in 18 species. In this case, all relationships had negative slopes. Taken collectively, and consistent in all species, as SLA decreased (leaves become “thicker”) across increasing leaf age and light gradients, Nmass also decreased, but proportionally more slowly, such that Narea increased. Due to the linear dependence of Amass on Nmass and a negative 4-intercept, “thicker” leaves (low SLA) therefore tend, on average, to have lower Nmass and Amass but higher Narea than “thinner” leaves. This tendency towards decreasing Amass with increasing Narea, resulting in a lower slope of the Amax-N relationship on an area than mass basis in 16 of 17 species where both were significant. For the sole species exception (higher area than mass-based slope) variation in Narea was related to variation in Nmass and not in SLA, and thus, these data are also consistent with this explanation. The relations between N, SLA and Amax explain how the rate of change in Amax per change in N can vary three-fold depending on whether a mass or area mode of expression is used.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00317910

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Relationship of aluminium and calcium to net CO2 exchange among diverse Scots pine provenances under pollution stress in Poland (1994)

Reich, P. B. ; Oleksyn, J. ; Tjoelker, M. G.

Springer

Oecologia 97 (1994), S. 82-92

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ISSN: 1432-1939

Keywords: Photosynthesis ; Respiration ; Pinus sylvestris ; Pinus nigra ; Betula pubescens

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Abstract Light-saturated net photosynthesis (Asat), dark respiration (RD), and foliar nutrient content of eight European Scots pine (Pinus sylvestris L.) provenances were measured at experimental sites in western Poland. Two-year-old seedlings were planted in 1984 at two sites with similar soils in areas of contrasting air pollution. One site was near a point source of SO2 and other pollutants, and another 12 km to the southeast in an area free of acute air pollution was treated as a control. The eight provenances were from a large north-tosouth latitudinal range (60 to 43° N). At the heavily polluted site Scots pine trees exhibited lower growth rates and crown dieback and deformation. Soil pH, Ca and Mg were at least 10 times lower, and Al 10 times higher at the polluted than the control site. In 1991, concentrations of Al, P, Ca, S, Mn, Fe, and Zn in oneyear old Scots pine foliage were higher and Mg lower at the polluted than control site. At both sites foliar Mg levels were within the range considered deficient (≤0.6 mg g-1), and at the polluted site, Al concentrations were very high (670 to 880 μg g-1). In all provenances, RD of one-year-old needles was higher (by 22% on average) and Asat was lower (by 37% on average) at the polluted than the control site. The ratio of Asat: RD was half as great in all provenances at the polluted (4 to 6) than control site (8 to 11). Provenances of southern origin had greater increases in RD and water-use efficiency at the polluted site than other provenances. Within the polluted site alone, or across both sites, Asat in Scots pine was negatively correlated to the Al: Ca ratio (p〈0.001, r=−0.93). Across sites RD increased with needle N and Al (multiple regression, p〈0.001). The data suggest that at the polluted site there is excessive soil Al and deficient Mg availability, low needle Mg and high Al concentrations and high Al: Ca ratios, and that these have resulted in reduced photosynthetic capacity and increased respiration.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00317911

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Photosynthesis-nitrogen relations in Amazonian tree species (1994)

Reich, P. B. ; Walters, M. B. ; Ellsworth, D. S. ; [et al.]

Springer

Oecologia 97 (1994), S. 62-72

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ISSN: 1432-1939

Keywords: Amazon ; Rain forests ; Leaf life-span ; Photosynthesis ; Nitrogen

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Abstract Among species, photosynthetic capacity (Amax) is usually related to leaf nitrogen content (N), but variation in the species-specific relationship is not well understood. To address this issue, we studied Amax-N relationships in 23 species in adjacent Amazonian communities differentially limited by nitrogen (N), phosphorus (P), and/or other mineral nutrients. Five species were studied in each of three late successional forest types (Tierra Firme, Caatinga and Bana) and eight species were studied on disturbed sites (cultivated and early secondary successional Tierra Firme plots). Amax expressed on a mass basis (Amass) was correlated (p〈0.05) with Nmass in 17 of 23 species, and Amax on an area basis (Aarea) was correlated (p〈0.05) with Narea in 21 of 23 species. The slopes of Amax-N relationships were greater and intercepts lower for disturbance adapted early successional species than for late successional species. On a mass basis, the Amax-N slope averaged ≈15 μmol CO2 [g N]-1 s-1 for 7 early secondary successional species and ≈4 μmol CO2 [g N]-1 s-1 for 15 late successional species, respectively. Species from disturbed sites had shorter leaf life-span and greater specific leaf area (SLA) than late successional species. Across all 23 species, the slope of the Amass-Nmass relationship was related (p〈0.001) positively to SLA (r2=0.70) and negatively to leaf life-span (r2=0.78) and temporal niche during secondary succession (years since cutting-and-burning, r2=0.90). Thus, disturbance adapted early successional species display a set of traits (short leaf life-span, high SLA and Amax and a steep slope of Amax-N) conducive to resource acquisition and rapid growth in their high resource regeneration niches. The significance and form of the Amax-N relationship were associated with the relative nutrient limitations in the three late successional communities. At species and community levels, Amax was more highly dependent on N in the N-limited Caatinga than in the P-and N-limited Bana and least in the P-and Ca-limited Tierra Firme on oxisol-and differences among these three communities in their massbased Amax-N slope reflects this pattern (6.0, 2.4, and 0.7 μmol CO2 [g N]-1 s-1, respectively). Among all 23 species, the estimated leaf Nmass needed to reach compensation (net photosynthesis ≈ zero) was positively related to the Amass-Nmass slope and to dark respiration rates and negatively related to leaf life-span. Variation among species in the Amax-N slope was well correlated with potential photosynthetic N use efficiency, Amax per unit leaf N. The dependence of Amax on N and the form of the relationship vary among Amazonian species and communities, consistent with both relative availabilities of N, P, and other mineral nutrients, and with intrinsic ecophysiological characteristics of species adapted to habitats of varying resource availability.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00317909

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