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Your search keyword '"Bragazza, Luca"' showing total 14 results
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14 results on '"Bragazza, Luca"'

7. Variation in carbon and nitrogen concentrations among peatland categories at the global scale.

Author

Watmough, Shaun, Gilbert-Parkes, Spencer, Basiliko, Nathan, Lamit, Louis J., Lilleskov, Erik A., Andersen, Roxanne, del Aguila-Pasquel, Jhon, Artz, Rebekka E., Benscoter, Brian W., Borken, Werner, Bragazza, Luca, Brandt, Stefani M., Bräuer, Suzanna L., Carson, Michael A., Chen, Xin, Chimner, Rodney A., Clarkson, Bev R., Cobb, Alexander R., Enriquez, Andrea S., and Farmer, Jenny

Subjects
LAND cover, BOGS, PEATLANDS, DRILL core analysis, FENS, PEAT, LAND use
Abstract

Peatlands account for 15 to 30% of the world's soil carbon (C) stock and are important controls over global nitrogen (N) cycles. However, C and N concentrations are known to vary among peatlands contributing to the uncertainty of global C inventories, but there are few global studies that relate peatland classification to peat chemistry. We analyzed 436 peat cores sampled in 24 countries across six continents and measured C, N, and organic matter (OM) content at three depths down to 70 cm. Sites were distinguished between northern (387) and tropical (49) peatlands and assigned to one of six distinct broadly recognized peatland categories that vary primarily along a pH gradient. Peat C and N concentrations, OM content, and C:N ratios differed significantly among peatland categories, but few differences in chemistry with depth were found within each category. Across all peatlands C and N concentrations in the 10–20 cm layer, were 440 ± 85.1 g kg-1 and 13.9 ± 7.4 g kg-1, with an average C:N ratio of 30.1 ± 20.8. Among peatland categories, median C concentrations were highest in bogs, poor fens and tropical swamps (446–532 g kg-1) and lowest in intermediate and extremely rich fens (375–414 g kg-1). The C:OM ratio in peat was similar across most peatland categories, except in deeper samples from ombrotrophic tropical peat swamps that were higher than other peatlands categories. Peat N concentrations and C:N ratios varied approximately two-fold among peatland categories and N concentrations tended to be higher (and C:N lower) in intermediate fens compared with other peatland types. This study reports on a unique data set and demonstrates that differences in peat C and OM concentrations among broadly classified peatland categories are predictable, which can aid future studies that use land cover assessments to refine global peatland C and N stocks. [ABSTRACT FROM AUTHOR]

Published
2022
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8. Latitude, Elevation, and Mean Annual Temperature Predict Peat Organic Matter Chemistry at a Global Scale.

Author

Verbeke, Brittany A., Lamit, Louis J., Lilleskov, Erik A., Hodgkins, Suzanne B., Basiliko, Nathan, Kane, Evan S., Andersen, Roxane, Artz, Rebekka R. E., Benavides, Juan C., Benscoter, Brian W., Borken, Werner, Bragazza, Luca, Brandt, Stefani M., Bräuer, Suzanna L., Carson, Michael A., Charman, Dan, Chen, Xin, Clarkson, Beverley R., Cobb, Alexander R., and Convey, Peter

Subjects
SOIL composition, ATMOSPHERIC carbon dioxide, ORGANIC chemistry, PEAT, ORGANIC compounds, FOURIER transform infrared spectroscopy, OZONE layer
Abstract

Peatlands contain a significant fraction of global soil carbon, but how these reservoirs will respond to the changing climate is still relatively unknown. A global picture of the variations in peat organic matter chemistry will aid our ability to gauge peatland soil response to climate. The goal of this research is to test the hypotheses that (a) peat carbohydrate content, an indicator of soil organic matter reactivity, will increase with latitude and decrease with mean annual temperatures, (b) while peat aromatic content, an indicator of recalcitrance, will vary inversely, and (c) elevation will have a similar effect to latitude. We used Fourier Transform Infrared Spectroscopy to examine variations in the organic matter functional groups of 1034 peat samples collected from 10 to 20, 30–40, and 60–70 cm depths at 165 individual sites across a latitudinal gradient of 79°N–65°S and from elevations of 0–4,773 m. Carbohydrate contents of high latitude peat were significantly greater than peat originating near the equator, while aromatic content showed the opposite trend. For peat from similar latitudes but different elevations, the carbohydrate content was greater and aromatic content was lower at higher elevations. Higher carbohydrate content at higher latitudes indicates a greater potential for mineralization, whereas the chemical composition of low latitude peat is consistent with their apparent relative stability in the face of warmer temperatures. The combination of low carbohydrates and high aromatics at warmer locations near the equator suggests the mineralization of high latitude peat until reaching recalcitrance under a new temperature regime. Plain Language Summary: Peatlands are a large global soil carbon reservoir, containing a quantity of carbon that is equivalent to about half or more of the carbon dioxide in the atmosphere. What will be their fate on a warming planet? Across a latitudinal gradient from 79°N to 65°S, we measured the fraction of the peat made up of carbohydrates, which are easily decomposed, and of aromatics, which are less easily decomposed. We found that peat from high latitudes and high elevations had greater carbohydrate content, while aromatic content showed the opposite trend. Larger carbohydrate content in organic matter indicates greater decomposability, while greater aromatic content indicates lower decomposability. We suggest that this latitude/elevation difference that we observed predicts how high‐latitude and high‐elevation peats may change under warmer conditions. Our work indicates that while a large portion of the carbohydrate fraction in these peats could be lost upon warming, releasing greenhouse gases, a residual fraction will survive and become more aromatic‐rich, making the remainder more resistant to rapid decomposition. Key Points: Peatland soil organic matter stability can be evaluated through the relative abundances of carbohydrate and aromatic content in peatPeat at higher latitudes and elevations has larger carbohydrate and smaller aromatic content relative lower latitudes and elevationsOur results foreshadow a transition of organic matter from higher latitude peatlands to a more recalcitrant form in response to warming [ABSTRACT FROM AUTHOR]

Published
2022
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9. Vascular plants affect properties and decomposition of moss-dominated peat, particularly at elevated temperatures.

Author

Zeh, Lilli, Igel, Marie Theresa, Schellekens, Judith, Limpens, Juul, Bragazza, Luca, and Kalbitz, Karsten

Subjects
HIGH temperatures, PEAT, HEATHER, CYPERACEAE, CHEMICAL decomposition
Abstract

Peatlands, storing significant amounts of carbon, are extremely vulnerable to climate change. The effects of climate change are projected to lead to a vegetation shift from Sphagnum mosses to sedges and shrubs. Impacts on the present moss-dominated peat remain largely unknown. In this study, we used a multiproxy approach to investigate the influence of contrasting vascular plant types (sedges, shrubs) on peat chemistry and decomposition. Peat cores of 20 cm depth and plant material (Sphagnum spp., Calluna vulgaris and Eriophorum vaginatum) from two ombrotrophic peatlands in the Italian Alps with a mean annual temperature difference of 1.4 ∘ C were analyzed. Peat cores were taken under adjacent shrub and sedge plants growing at the same height above the water table. We used carbon, nitrogen and their stable isotopes to assess general patterns in the degree of decomposition across sampling locations and depths. In addition, analytical pyrolysis was applied to disentangle effects of vascular plants (sedge, shrub) on chemical properties and decomposition of the moss-dominated peat. Pyrolysis data confirmed that Sphagnum moss dominated the present peat irrespective of depth. Nevertheless, vascular plants contributed to peat properties as revealed by, e.g., pyrolysis products of lignin. The degree of peat decomposition increased with depth as shown by, e.g., decreasing amounts of the pyrolysis product of sphagnum acid and increasing δ13C with depth. Multiple parameters also revealed a higher degree of decomposition of Sphagnum -dominated peat collected under sedges than under shrubs, particularly at the high temperature site. Surprisingly, temperature effects on peat decomposition were less pronounced than those of sedges. Our results imply that vascular plants affect the decomposition of the existing peat formed by Sphagnum , particularly at elevated temperature. These results suggest that changes in plant functional types may have a stronger impact on the soil carbon feedback in a warmer world than hitherto assumed. [ABSTRACT FROM AUTHOR]

Published
2020
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10. Vascular plants affect properties and decomposition of mossdominated peat, particularly at elevated temperatures.

Author

Zeh, Lilli, Igel, Theresa Marie, Schellekens, Judith, Limpens, Juul, Bragazza, Luca, and Kalbitz, Karsten

Subjects
VASCULAR plants, HIGH temperatures, PEAT, HEATHER, CYPERACEAE, SHRUBS
Abstract

Peatlands, storing significant amounts of carbon are extremely vulnerable to climate change. The effects of climate change are projected to lead to a vegetation shift from Sphagnum mosses to sedges and shrubs. Impacts on the present moss-dominated peat remain largely unknown. In this study, we used a multi proxy approach to investigate the influence of contrasting vascular plant types (sedges, shrubs) on peat chemistry and decomposition. Peat cores of 20 cm depth and plant material ( Sphagnum spp., Calluna vulgaris, Eriophorum vaginatum ) from two ombrotrophic peatlands in the Italian Alps with a mean annual temperature difference of 1.4 °C were analysed. Peat cores were taken under adjacent shrub and sedge plants growing at the same height above the water table. We used carbon, nitrogen and their stable isotopes to assess general patterns in the degree of decomposition across sampling locations and depths. In addition, analytical pyrolysis was applied to disentangle effects of vascular plants (sedge, shrub) on chemical properties and decomposition of the moss-dominated peat. Pyrolysis data confirmed that Sphagnum moss dominated the present peat irrespectively of depth. Nevertheless, vascular plants contributed to peat properties as revealed by e.g. pyrolysis products of lignin. The degree of peat decomposition increased with depth as shown by e.g. decreasing amounts of the pyrolysis product of sphagnum acid and increasing δ13C with depth. Multiple parameters also revealed a higher degree of decomposition of Sphagnum -dominated peat collected under sedges than under shrubs, particularly at the high temperature site. Surprisingly, temperature effects on peat decomposition were less pronounced than those of sedges. Our results imply that vascular plants affect the decomposition of the existing peat formed by Sphagnum, particularly at elevated temperature. These results suggest that changes in plant functional types may have a stronger impact on the soil carbon feedback in a warmer world than hitherto assumed. [ABSTRACT FROM AUTHOR]

Published
2020
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12. Heatwave 2003: high summer temperature, rather than experimental fertilization, affects vegetation and CO2 exchange in an alpine bog.

Author

Gerdol, Renato, Bragazza, Luca, and Brancaleoni, Lisa

Subjects
*NITROGEN, *PHOSPHORUS, *BOTANY, *VEGETATION dynamics, *PEAT mosses, *BIOTIC communities
Abstract

• Nitrogen and phosphorus were added experimentally in a bog in the southern Alps. It was hypothesized that alleviating nutrient limitation will increase vascular plant cover. As a consequence, more carbon will be fixed through higher rates of net ecosystem CO2 exchange (NEE). • The vascular cover did increase at the expense of Sphagnum mosses. However, such vegetation changes were largely independent of the treatment and were probably triggered by an exceptional heatwave in summer 2003. • Contrary to the tested hypothesis, NEE was unaffected by the nutrient treatments but was strongly influenced by temperature and water-table depth. In particular, ecosystem respiration in the hot summer of 2003 increased dramatically, presumably owing to enhanced heterotrophic respiration in an increased oxic peat layer. • At the end of the experiment, the Sphagnum cover decreased significantly in the nitrogen-fertilized treatment at hummock microhabitats. In the long term, this will imply a proportionally greater accumulation of vascular litter, more easily decomposable than the recalcitrant Sphagnum litter. As a result, rates of carbon fixation may decrease because of stimulated respiration. [ABSTRACT FROM AUTHOR]

Published
2008
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14. Carbon dynamics in peatlands under changing hydrology: Effects of water level drawdown on litter quality, microbial enzyme activities and litter decomposition rates

Author

Petra Straková, University of Helsinki, Faculty of Agriculture and Forestry, Department of Forest Sciences, Finnish Forest Research Institute (METLA), Helsingin yliopisto, maatalous-metsätieteellinen tiedekunta, metsatieteiden laitos, Helsingfors universitet, agrikultur-forstvetenskapliga fakulteten, institutionen för skogsvetenskaper, Bragazza, Luca, and Laiho, Raija

Subjects
Hydrology, geography, Peat, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, biology, Wetland, Plant community, metsätieteet, 04 agricultural and veterinary sciences, 15. Life on land, Plant litter, biology.organism_classification, 01 natural sciences, Sphagnum, 13. Climate action, Forest ecology, 040103 agronomy & agriculture, 0401 agriculture, forestry, and fisheries, Environmental science, Ecosystem, Cycling, 0105 earth and related environmental sciences
Abstract

Pristine peatlands are carbon (C) accumulating wetland ecosystems sustained by a high water level (WL) and consequent anoxia that slows down decomposition. Persistent WL drawdown as a response to climate and/or land-use change directly affects decomposition: increased oxygenation stimulates decomposition of the old C (peat) sequestered under prior anoxic conditions. Responses of the new C (plant litter) in terms of quality, production and decomposability, and the consequences for the whole C cycle of peatlands are not fully understood. WL drawdown induces changes in plant community resulting in shift in dominance from Sphagnum and graminoids to shrubs and trees. There is increasing evidence that the indirect effects of WL drawdown via the changes in plant communities will have more impact on the ecosystem C cycling than any direct effects. The aim of this study is to disentangle the direct and indirect effects of WL drawdown on the new C by measuring the relative importance of 1) environmental parameters (WL depth, temperature, soil chemistry) and 2) plant community composition on litter production, microbial activity, litter decomposition rates and, consequently, on the C accumulation. This information is crucial for modelling C cycle under changing climate and/or land-use. The effects of WL drawdown were tested in a large-scale experiment with manipulated WL at two time scales and three nutrient regimes. Furthermore, the effect of climate on litter decomposability was tested along a north-south gradient. Additionally, a novel method for estimating litter chemical quality and decomposability was explored by combining Near infrared spectroscopy with multivariate modelling. WL drawdown had direct effects on litter quality, microbial community composition and activity and litter decomposition rates. However, the direct effects of WL drawdown were overruled by the indirect effects via changes in litter type composition and production. Short-term (years) responses to WL drawdown were small. In long-term (decades), dramatically increased litter inputs resulted in large accumulation of organic matter in spite of increased decomposition rates. Further, the quality of the accumulated matter greatly changed from that accumulated in pristine conditions. The response of a peatland ecosystem to persistent WL drawdown was more pronounced at sites with more nutrients. The study demonstrates that the shift in vegetation composition as a response to climate and/or land-use change is the main factor affecting peatland ecosystem C cycle and thus dynamic vegetation is a necessity in any models applied for estimating responses of C fluxes to changes in the environment. The time scale for vegetation changes caused by hydrological changes needs to extend to decades. This study provides grouping of litter types (plant species and part) into functional types based on their chemical quality and/or decomposability that the models could utilize. Further, the results clearly show a drop in soil temperature as a response to WL drawdown when an initially open peatland converts into a forest ecosystem, which has not yet been considered in the existing models. Luonnontilaiset suot ovat hiiltä sitovia ekosysteemejä. Niissä maaperän märkyydestä johtuva hapen niukkuus hidastaa orgaanisen aineen hajotusta. Ilmaston tai maankäytön muutos voi aiheuttaa suon pitkäkestoisen kuivumisen. Se vaikuttaa sekä suorasti että epäsuorasti hajotukseen ja sitä kautta hiilen kiertoon ja hiilitaseeseen. Merkittävin suora vaikutus on maaperän hapekkuuden lisääntyminen, mikä nopeuttaa hajotusta. Epäsuorasti kuivuminen vaikuttaa muuttamalla suon kasviyhteisöä: tyypillisten suokasvien, kuten rahkasammalten ja sarojen, biomassa, tuotos ja karikesyöte vähenevät, kun taas varpujen ja puiden lisääntyvät. Kasviyhteisössä ja sen karikesyötteessä tapahtuvilla muutoksilla voi olla suurempi vaikutus hiilen kiertoon kuin vedenpinnan alenemisella sinänsä. Näiden muutosten suuntaa ja merkitystä koko ekosysteemin hiilitaseelle ei kuitenkaan vielä tunneta riittävästi. Tässä työssä tarkasteltiin vedenpinnan tason vaikutusta suohon tulevan karikkeen määrään, kemiallisiin ominaisuuksiin, mikrobiaktiivisuuteen ja hajoamisnopeuteen, ja näiden lopputulemana tapahtuvaan uuden orgaanisen aineen kertymään. Kuivumisen suorien ja epäsuorien vaikutusten merkitystä arvioitiin vertailemalla ympäristötekijöiden (vedenpinnan taso sekä maan lämpötila ja kemialliset ominaisuudet) ja kasvillisuuden koostumuksen selitysvoimaa. Tätä tietoa tarvitaan, kun mallinnetaan soiden hiilen kiertoa muuttuvissa olosuhteissa. Lyhyt- (muutamia vuosia) ja pitkäkestoisen (muutamia vuosikymmeniä) kuivumisen vaikutuksia tutkittiin kolmella eri ravinteisuustasolla. Ilmaston vaikutusta arvioitiin lisäksi vertailemalla Pohjois- ja Etelä-Suomessa sekä Virossa sijaitsevia koealoja. Karikkeen kemiallisen koostumuksen ja hajotettavuuden arviointiin kokeiltiin perinteisten uuttomenetelmien ja regressiomallien lisäksi nopeaa ja edullista infrapunaspektroskopiaa ja monimuuttuja-analyysiä. Vedenpinnan aleneminen vaikutti kasvilajitasolla karikkeen laatuun, kariketta hajottavaan mikrobiyhteisöön ja karikkeen hajoamisnopeuteen. Nämä kuivumisen suorat vaikutukset olivat kuitenkin vähäisiä verrattuina karikkeen määrän ja koostumuksen muutosten epäsuoriin vaikutuksiin. Lyhytkestoisen kuivumisen vaikutukset tutkittuihin tunnuksiin olivat kaikkinensa melko vähäisiä. Pitkäkestoisen kuivumisen aikana karikesyöte kasvoi merkittävästi. Se johti orgaanisen aineen kertymän lisääntymiseen, vaikka hajotus samalla nopeutui. Kertyvän aineen laatu myös poikkesi selvästi luonnontilaisten soiden kertymän laadusta. Vaste vedenpinnan alenemiseen sekä nopeutui että voimistui suon ravinteisuustason noustessa. Tulokset osoittavat, että metsäojituksesta ja ilmaston kuivumisesta aiheutuvat muutokset soiden kasviyhteisöissä vaikuttavat oleellisesti hiilen kiertoon. Siksi kasvillisuusmuutokset on sisällytettävä malleihin, joilla arvioidaan hiilivirtojen vasteita muuttuviin olosuhteisiin. Muutokset on myös huomioitava riittävän pitkällä aikajänteellä. Työssä esitetään karikkeen kemiallisiin ominaisuuksiin ja hajoamisnopeuteen perustuvat soille tyypillisten kasvien toiminnalliset ryhmät, joita malleissa voidaan hyödyntää. Lisäksi työ osoittaa kuivumisen alentavan maan lämpötilaa huomattavasti, mitä malleissa ei ole otettu huomioon.

Published
2010
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