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Sources of sulphur in forest canopy throughfall (1988)

Lindberg, S. E. ; Garten, C. T.

[s.l.] : Nature Publishing Group

Nature 336 (1988), S. 148-151

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ISSN: 1476-4687

Source: Nature Archives 1869 - 2009

Topics: Biology , Chemistry and Pharmacology , Medicine , Natural Sciences in General , Physics

Notes: [Auszug] The enrichment of sulphate in TF is defined as net throughfall, or NTF (NTF equals flux in TF minus flux in rain). The foliar leaching portion of NTF, representing an internal cycling source of sulphur, should not be included in estimates of atmospheric inputs. Quantifying the sulphur flux in rain ...

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1038/336148a0

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Fate and distribution of sulfur-35 in yellow poplar and red maple trees (1988)

Garten, C. T.

Springer

Oecologia 76 (1988), S. 43-50

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ISSN: 1432-1939

Keywords: Tree physiology ; Nutrient cycling ; Biogenic emission ; Sulfur ; Radioecology

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Summary Two deciduous tree species (yellow poplar and red maple) on Walker Branch Watershed (WBW), near Oak Ridge, Tennessee, were radiolabeled with 35S (87 day halflife) to study internal cycling, storage, and biogenic emission of sulfur (S). One tree of each species was girdled before radiolabeling to prevent phloem translocation to the roots, and the aboveground biomass was harvested prior to autumn leaf fall. Aboveground biomass, leaf fall, throughfall, and stemflow were sampled over a 13 to 24 week period. Sulfur-35 concentrations in tree leaves reached nearly asymptotic levels within 1 to 2 weeks after radiolabeling. Foliar leaching of 35S and leaf fall represented relatively unimportant return pathways to the forest soil. The final distribution of 35S in the nongirdled trees indicated little aboveground storage of S in biomass and appreciable (〉60%) capacity to cycle S either to the belowground system by means of translocation or to the atmosphere by means of biogenic S emissions. Losses of volatile 35S were estimated from the amount of isotope missing (∼33%) in final inventories of the girdled trees. Estimated 35S emission rates from the girdled trees were ∼10-6 to ∼10-7 μCi cm-2 leaf d-1, and corresponded to an estimated gaseous S emission of approximately 0.1 to 1 μg S cm-2 leaf d-1. Translocation to roots was a significant sink for 35S in the red maple tree (40% of the injected amount). Research on forest biogeochemical S cycles should further explore biogenic S emissions from trees as a potential process of S flux from forest ecosystems.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00379598

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Foliar δ13C within a temperate deciduous forest: spatial, temporal, and species sources of variation (1992)

Garten, C. T. ; Taylor, G. E.

Springer

Oecologia 90 (1992), S. 1-7

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ISSN: 1432-1939

Keywords: Stable isotopes ; Deciduous forests ; 13C/12C ratios ; Topographic variation ; Water use efficiency

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Summary Foliar 13C-abundance (δ13C) was analyzed in the dominant trees of a temperate deciduous forest in east Tennessee (Walker Branch Watershed) to investigate the variation in foliar δ13C as a function of time (within-year and between years), space (canopy height, watershed topography and habitat) and species (deciduous and coniferous taxa). Various hypotheses were tested by analyzing (i) samples collected from the field during the growing season and (ii) foliar tissues maintained in an archived collection. The δ13C-value for leaves from the tops of trees was 2 to 3%. more positive than for leaves sampled at lower heights in the canopy. Quercus prinus leaves sampled just prior to autumn leaf fall had significantly more negative δ13C-values than those sampled during midsummer. On the more xeric ridges, needles of Pinus spp. had more positive δ13C-values than leaves from deciduous species. Foliar δ13C-values differed significantly as a function of topography. Deciduous leaves from xeric sites (ridges and slopes) had more positive δ13C-values than those from mesic (riparian and cove) environments. On the more xeric sites, foliar δ13C was significantly more positive in 1988 (a dry year) relative to that in 1989 (a year with above-normal precipitation). In contrast, leaf δ13C in trees from mesic valley bottoms did not differ significantly among years with disparate precipitation. Patterns in foliar δ13C indicated a higher ratio of net CO2 assimilation to transpiration (A/E) for trees in more xeric versus mesic habitats, and for trees in xeric habitats during years of drought versus years of normal precipitation. However, A/E (units of mmol CO2 fixed/mol H2O transpired) calculated on the basis of δ13C-values for leaves from the more xeric sites was higher in a wet year (6.6±1.2) versus a dry year (3.4±0.4). This difference was attributed to higher transpiration (and therefore lower A/E) in the year with lower relative humidity and higher average daily temperature. The calculated A/E values for the forest in 1988–89, based on δ13C, were within ±55% of estimates made over a 17 day period at this site in 1984 using micrometeorological methods.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00317801

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Elevational trends in the fluxes of sulphur and nitrogen in throughfall in the Southern Appalachian Mountains: Some surprising results (1995)

Shubzda, J. ; Lindberg, S. E. ; Garten, C. T. ; [et al.]

Springer

Water, air & soil pollution 85 (1995), S. 2265-2270

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ISSN: 1573-2932

Keywords: atmospheric deposition ; high elevation forests ; foliar uptake ; cloudwater ; nitrogen ; sulphur

Source: Springer Online Journal Archives 1860-2000

Topics: Energy, Environment Protection, Nuclear Power Engineering

Notes: Abstract From 1986–1989, a team of scientists measured atmospheric concentrations and fluxes in precipitation and throughfall, and modeled dry and cloudwater deposition in a spruce-fir forest of the Great Smoky Mountains National Park which is located in the Southern Appalachian Region of the United States. The work was part of the Integrated Forest Study (IFS) conducted at 12 forests in N. America and Europe. The spruce-fir forest at 1740 m consistently received the highest total deposition rates (∼2200, 1200, and 700 eq ha−1 yr−1 for SO4 2−, NO3 −, and NH4 +). During the summers of 1989 and 1990 we used multiple samplers to measure hydrologie, SO4 2−, and NO3 − fluxes in rain and throughfall events beneath spruce forests above (1940 m) and below (1720 m) cloud base. Throughfall was used to estimate total deposition using relationships determined during the IFS. Although the SO4 2− fluxes increased with elevation by a factor of ∼2 due to higher cloudwater interception at 1940 m, the NO3 − fluxes decreased with elevation by ∼30%. To investigate further, we began year round measurements of fluxes of all major ions in throughfall below spruce-fir forests at 1740 m and at 1920 m in 1993–1994. The fluxes of most ions showed a 10–50% increase with elevation due to the ∼70 cm yr−1 cloudwater input at 1920 m. However, total inorganic nitrogen exhibited a 40% lower flux in throughfall at 1920 m than at 1740 m suggesting either higher dry deposition to trees at 1740 m or much higher canopy uptake of nitrogen by trees at 1920 m. Differential canopy absorption of N by trees at different elevations would have significant consequences for the use of throughfall N fluxes to estimate deposition. We used artificial trees to understand the foliar interactions of N.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF01186171

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Forest soil carbon inventories and dynamics along an elevation gradient in the southern Appalachian Mountains (1999)

Garten, C. T. ; Post, W. M. ; Hanson, P. J. ; [et al.]

Springer

Biogeochemistry 45 (1999), S. 115-145

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ISSN: 1573-515X

Keywords: climate ; C/N ratios ; light-fraction organic matter ; particulate organic matter ; soil C turnover

Source: Springer Online Journal Archives 1860-2000

Topics: Chemistry and Pharmacology , Geosciences

Notes: Abstract Soil organic carbon (SOC) was partitioned between unprotected and protected pools in six forests along an elevation gradient in the southern Appalachian Mountains using two physical methods: flotation in aqueous CaCl2 (1.4 g/mL) and wet sieving through a 0.053 mm sieve. Both methods produced results that were qualitatively and quantitatively similar. Along the elevation gradient, 28 to 53% of the SOC was associated with an unprotected pool that included forest floor O-layers and other labile soil organic matter (SOM) in various stages of decomposition. Most (71 to 83%) of the C in the mineral soil at the six forest sites was identified as protected because of its association with a heavy soil fraction (〉1.4 g/mL) or a silt-clay soil fraction. Total inventories of SOC in the forests (to a depth of 30 cm) ranged from 384 to 1244 mg C/cm2. The turnover time of the unprotected SOC was negatively correlated (r=−0.95, p〈0.05) with mean annual air temperature (MAT) across the elevation gradient. Measured SOC inventories, annual C returns to the forest floor, and estimates of C turnover associated with the protected soil pool were used to parameterize a simple model of SOC dynamics. Steady-state predictions with the model indicated that, with no change in C inputs, the low-(235–335 m), mid-(940–1000 m), and high-(1650–1670 m) elevation forests under study might surrender ≈ 40 to 45% of their current SOC inventory following a 4°C increase in MAT. Substantial losses of unprotected SOM as a result of a warmer climate could have longterm impacts on hydrology, soil quality, and plant nutrition in forest ecosystems throughout the southern Appalachian Mountains.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF01106778

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Nitrogen Saturation and Soil N Availability in a High-Elevation Spruce and Fir Forest (2000)

Garten, C. T.

Springer

Water, air & soil pollution 120 (2000), S. 295-313

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ISSN: 1573-2932

Keywords: elevation gradient ; Great Smoky Mountains National Park ; nitrification ; particulate organic matter ; soilN mineralization ; topography

Source: Springer Online Journal Archives 1860-2000

Topics: Energy, Environment Protection, Nuclear Power Engineering

Notes: Abstract A field study was conducted during the summer of 1995 to gain abetter understanding of the causes of nitrate (NO3-N)leaching and ongoing changes in soil nitrogen (N) availabilityin high-elevation (1524–2000 m) spruce (Picea rubens) andfir (Abies fraseri) forests of the Great Smoky MountainsNational Park, Tennessee and North Carolina, U.S.A. Indicatorsof soil N availability (total soil N concentrations,extractable NH4-N, extractable NO3-N, and C/N ratios)were measured in Oa and A horizons at 33 study plots. Dynamicmeasures included potential net soil N mineralization determinedin 12-week aerobic laboratory incubations at 22 °C.Potential net nitrification in the A horizon was correlated (r =+0.83, P 〈 0.001) with total soil N concentrations. Mostmeasures of soil N availability did not exhibit significanttrends with elevation, but there were topographic differences.Potential net soil N mineralization and net nitrification in theA horizon were higher in coves than on ridges. Relative amountsof particulate and organomineral soil organic matter influencedpotential net N mineralization and nitrification in the Ahorizon. Calculations indicate that soil N availability andNO3-N leaching in high-elevation spruce and fir forests ofthe Great Smoky Mountains National Park will increase inresponse to regional warming.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1023/A:1005270012802

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