Your search keyword '"Gallego-Sala, Angela V."' showing total 11 results

1. Bioclimatic envelope model of climate change impacts on blanket peatland distribution in Great Britain

Author

Gallego-Sala, Angela V., Clark, Joanna M., House, Joanna I., Orr, Harriet G., Prentice, I. Colin, Smith, Pete, Farewell, Timothy, and Chapman, Stephen J.

Published

2010

2. Climate change and the British Uplands : evidence for decision-making

Author

House, Jo I., Orr, Harriet G., Clark, Joanna M., Gallego-Sala, Angela V., Freeman, Chris, Prentice, I. Colin, and Smith, Pete

Published

2010

3. A new approach to simulate peat accumulation, degradation and stability in a global land surface scheme (JULES vn5.8_accumulate_soil) for northern and temperate peatlands.

Author

Chadburn, Sarah E., Burke, Eleanor J., Gallego-Sala, Angela V., Smith, Noah D., Bret-Harte, M. Syndonia, Charman, Dan J., Drewer, Julia, Edgar, Colin W., Euskirchen, Eugenie S., Fortuniak, Krzysztof, Gao, Yao, Nakhavali, Mahdi, Pawlak, Włodzimierz, Schuur, Edward A. G., and Westermann, Sebastian

Subjects

PEATLANDS, SOIL profiles, PEAT, SOIL mineralogy, SOIL compaction, HISTOSOLS

Abstract

Peatlands have often been neglected in Earth system models (ESMs). Where they are included, they are usually represented via a separate, prescribed grid cell fraction that is given the physical characteristics of a peat (highly organic) soil. However, in reality soils vary on a spectrum between purely mineral soil (no organic material) and purely organic soil, typically with an organic layer of variable thickness overlying mineral soil below. They are also dynamic, with organic layer thickness and its properties changing over time. Neither the spectrum of soil types nor their dynamic nature can be captured by current ESMs. Here we present a new version of an ESM land surface scheme (Joint UK Land Environment Simulator, JULES) where soil organic matter accumulation – and thus peatland formation, degradation and stability – is integrated in the vertically resolved soil carbon scheme. We also introduce the capacity to track soil carbon age as a function of depth in JULES and compare this to measured peat age–depth profiles. The new scheme is tested and evaluated at northern and temperate sites. This scheme simulates dynamic feedbacks between the soil organic material and its thermal and hydraulic characteristics. We show that draining the peatlands can lead to significant carbon loss, soil compaction and changes in peat properties. However, negative feedbacks can lead to the potential for peatlands to rewet themselves following drainage. These ecohydrological feedbacks can also lead to peatlands maintaining themselves in climates where peat formation would not otherwise initiate in the model, i.e. displaying some degree of resilience. The new model produces similar results to the original model for mineral soils and realistic profiles of soil organic carbon for peatlands. We evaluate the model against typical peat profiles based on 216 northern and temperate sites from a global dataset of peat cores. The root-mean-squared error (RMSE) in the soil carbon profile is reduced by 35 %–80 % in the best-performing JULES-Peat simulations compared with the standard JULES configuration. The RMSE in these JULES-Peat simulations is 7.7–16.7 kg C m -3 depending on climate zone, which is considerably smaller than the soil carbon itself (around 30–60 kg C m -3). The RMSE at mineral soil sites is also reduced in JULES-Peat compared with the original JULES configuration (reduced by ∼ 30 %–50 %). Thus, JULES-Peat can be used as a complete scheme that simulates both organic and mineral soils. It does not require any additional input data and introduces minimal additional variables to the model. This provides a new approach for improving the simulation of organic and peatland soils and associated carbon-cycle feedbacks in ESMs. [ABSTRACT FROM AUTHOR]

Published

2022

4. Latitudinal limits to the predicted increase of the peatland carbon sink with warming

Author

Gallego-Sala, Angela V., Charman, Dan J., Brewer, Simon, Page, Susan E., Prentice, I. Colin, Friedlingstein, Pierre, Moreton, Steve, Amesbury, Matthew J., Beilman, David W., Blyakharchuk, Tatiana, Bochicchio, Christopher, Booth, Robert K., Bunbury, Joan, Camill, Philip, Carless, Donna, Chimner, Rodney A., Cressey, Elizabeth, Courtney-Mustaphi, Colin, de Jong, Rixt, Fialkiewicz-Koziel, Barbara, Finkelstein, Sarah A., Garneau, Michelle, Githumbi, Esther, Hribjlan, John, Holmquist, James, Hughes, Paul D. M., Jones, Miriam C., Karofeld, Edgar, Klein, Eric S., Kokfelt, Ulla, Korhola, Atte, Lacourse, Terri, Le Roux, Gael, Lamentowicz, Mariusz, Large, David, Lavoie, Martin, Loisel, Julie, Mackay, Helen, MacDonald, Glen M., Makila, Markku, Magnan, Gabriel, Marchant, Robert, Marcisz, Katarzyna, Massa, Charly, Mathijssen, Paul, Mauquoy, Dmitri, Mighall, Timothy, Mitchell, Fraser J. G., Moss, Patrick, Nichols, Jonathan, Oksanen, Pirita O., Orme, Lisa, Packalen, Maara S., Robinson, Stephen, Roland, Thomas P., Sanderson, Nicole K., Sannel, A. Britta K., Steinberg, Natascha, Swindles, Graeme T., Turner, T. Edward, Uglow, Joanna, van Bellen, Simon, van der Linden, Marjolein, van Geel, Bas, Wang, Guoping, Yu, Zicheng, Zaragoza-Castells, Joana, Zhao, Yan, and Clifford, Michael

Subjects

Tropical peat, Climate change, Carbon cycle, Peatlands, Last milennium

Abstract

The carbon sink potential of peatlands depends on the balance of carbon uptake by plants and microbial decomposition. The rates of both these processes will increase with warming but it remains unclear which will dominate the global peatland response. Here we examine the global relationship between peatland carbon accumulation rates during the last millennium and planetary-scale climate space. A positive relationship is found between carbon accumulation and cumulative photosynthetically active radiation during the growing season for mid- to high-latitude peatlands in both hemispheres. However, this relationship reverses at lower latitudes, suggesting that carbon accumulation is lower under the warmest climate regimes. Projections under Representative Concentration Pathway (RCP)2.6 and RCP8.5 scenarios indicate that the present-day global sink will increase slightly until around ad 2100 but decline thereafter. Peatlands will remain a carbon sink in the future, but their response to warming switches from a negative to a positive climate feedback (decreased carbon sink with warming) at the end of the twenty-first century.

Published

2018

5. A cautionary tale about using the apparent carbon accumulation rate (aCAR) obtained from peat cores.

Author

Young, Dylan M., Baird, Andy J., Gallego-Sala, Angela V., and Loisel, Julie

Subjects

PEATLANDS, CLIMATE change mitigation, CARBON, ECOSYSTEMS, ENVIRONMENTAL protection

Abstract

The carbon (C) accumulation histories of peatlands are of great interest to scientists, land users and policy makers. Because peatlands contain more than 500 billion tonnes of C, an understanding of the fate of this dynamic store, when subjected to the pressures of land use or climate change, is an important part of climate-change mitigation strategies. Information from peat cores is often used to recreate a peatland's C accumulation history from recent decades to past millennia, so that comparisons between past and current rates can be made. However, these present day observations of peatlands' past C accumulation rates (known as the apparent rate of C accumulation - aCAR) are usually different from the actual uptake or loss of C that occurred at the time (the true C balance). Here we use a simple peatland model and a more detailed ecosystem model to illustrate why aCAR should not be used to compare past and current C accumulation rates. Instead, we propose that data from peat cores are used with existing or new C balance models to produce reliable estimates of how peatland C function has changed over time. [ABSTRACT FROM AUTHOR]

Published

2021

6. Testate amoeba as palaeohydrological indicators in the permafrost peatlands of north-east European Russia and Finnish Lapland.

Author

Zhang, Hui, Amesbury, Matthew J., Ronkainen, Tiina, Charman, Dan J., Gallego‐Sala, Angela V., and VÄliranta, Minna

Subjects

PALEOHYDROLOGY, PERMAFROST, AMOEBA, CLIMATE change, PEATLANDS

Abstract

ABSTRACT To explore the use of testate amoeba for investigating the impacts of climate change on permafrost peatland hydrology, we established a new modern training set from Arctic permafrost peatlands in north-east European Russia and Finnish Lapland. Ordination analyses showed that water-table depth (WTD) was the most important control on testate amoeba distribution. We developed a new testate amoeba-based WTD transfer function and thoroughly tested it. We found that our transfer function had strong predictive power. The best-performing model was based on tolerance-downweighted weighted averaging with inverse deshrinking ( R2 = 0.77, RMSEP = 5.62 cm with leave-one-out cross validation). The new transfer function was applied to a short peat core from Arctic Russia and revealed two major hydrological shifts, which could be validated against plant macrofossil data. We also compared our model to another two models from more temperate peatlands. Comparison of the different testate amoeba datasets suggests that testate amoeba ecohydrological relationships are similar for permafrost peatlands to those in more temperate regions, but there are some differences that suggest a need for training datasets that are fully representative of permafrost peatlands. [ABSTRACT FROM AUTHOR]

Published

2017

7. Climate controls on carbon accumulation in peatlands of Northeast China.

Author

Xing, Wei, Bao, Kunshan, Gallego-Sala, Angela V., Charman, Dan J., Zhang, Zhenqing, Gao, Chuanyu, Lu, Xianguo, and Wang, Guoping

Subjects

*PEATLANDS, *ENVIRONMENTAL engineering, *CARBON in soils, *CARBON cycle, *HOLOCENE Epoch

Abstract

Peatlands contain around one third of the global soil carbon (C) and play an important role in the C cycle. In particular, the response of the productivity-decay balance to climate variability is critical for understanding both the past and future global C cycle. Most studies of peatland C dynamics have been carried out on boreal and subarctic peatlands, where climate models predict a greater increase in temperature compared to the global average. Less is known about peatlands at lower latitudes, yet there are significant peatland C stocks in these regions that may be more vulnerable to future climate change because they are closer to the climatic limit of peatland distribution. Northeast China is China's largest wetland region, with extensive peatlands in mountain regions and across the plains. Here, we used core data from 134 peatland sites to quantify the C accumulation rate over different timescales and estimate C storage across northeast China. The results show that the Holocene long-term apparent rate of C accumulation (LORCA) ranged from 5.74 to 129.31 g C m −2 yr −1 , with a mean rate of 33.66 g C m −2 yr −1 . The total wetland area and C storage within this region is 82,870 km 2 and 4.34 Gt C, and about 80% of the C is contained in mountain peatlands. We find that total C accumulated over the last 2000 years is linearly related to photosynthetically active radiation over the growing season, supporting the hypothesis that rates of net primary productivity (NPP) are more important than decomposition rates in determining long-term C accumulation. Although peatlands in northeast China are close to the southern limit of major peatland extent, our data suggest that future warming will lead to greater future C accumulation, as long as moisture balance or cloudiness do not become limiting factors. [ABSTRACT FROM AUTHOR]

Published

2015

8. The role of climate change in regulating Arctic permafrost peatland hydrological and vegetation change over the last millennium.

Author

Zhang, Hui, Piilo, Sanna R., Amesbury, Matthew J., Charman, Dan J., Gallego-Sala, Angela V., and Väliranta, Minna M.

Subjects

*PERMAFROST, *CLIMATE change, *HYDROLOGY, *VEGETATION dynamics, *PEATLANDS

Abstract

Climate warming has inevitable impacts on the vegetation and hydrological dynamics of high-latitude permafrost peatlands. These impacts in turn determine the role of these peatlands in the global biogeochemical cycle. Here, we used six active layer peat cores from four permafrost peatlands in Northeast European Russia and Finnish Lapland to investigate permafrost peatland dynamics over the last millennium. Testate amoeba and plant macrofossils were used as proxies for hydrological and vegetation changes. Our results show that during the Medieval Climate Anomaly (MCA), Russian sites experienced short-term permafrost thawing and this induced alternating dry-wet habitat changes eventually followed by desiccation. During the Little Ice Age (LIA) both sites generally supported dry-hummock habitats, at least partly driven by permafrost aggradation. However, proxy data suggest that occasionally, MCA habitat conditions were drier than during the LIA, implying that evapotranspiration may create important additional eco-hydrological feedback mechanisms under warm conditions. All sites showed a tendency towards dry conditions as inferred from both proxies starting either from ca . 100 years ago or in the past few decades after slight permafrost thawing, suggesting that recent warming has stimulated surface desiccation rather than deeper permafrost thawing. This study shows links between two important controls over hydrology and vegetation changes in high-latitude peatlands: direct temperature-induced surface layer response and deeper permafrost layer-related dynamics. These data provide important backgrounds for predictions of Arctic permafrost peatlands and related feedback mechanisms. Our results highlight the importance of increased evapotranspiration and thus provide an additional perspective to understanding of peatland-climate feedback mechanisms. [ABSTRACT FROM AUTHOR]

Published

2018

9. Regional variability in peatland burning at mid-to high-latitudes during the Holocene.

Author

Sim, Thomas G., Swindles, Graeme T., Morris, Paul J., Baird, Andy J., Gallego-Sala, Angela V., Wang, Yuwan, Blaauw, Maarten, Camill, Philip, Garneau, Michelle, Hardiman, Mark, Loisel, Julie, Vӓliranta, Minna, Anderson, Lysanna, Apolinarska, Karina, Augustijns, Femke, Aunina, Liene, Beaulne, Joannie, Bobek, Přemysl, Borken, Werner, and Broothaerts, Nils

Subjects

*HOLOCENE Epoch, *LITTLE Ice Age, *PEATLAND restoration, *DROUGHTS, *FRAGMENTED landscapes, *PEATLANDS, *CLIMATE change, *COASTS

Abstract

Northern peatlands store globally-important amounts of carbon in the form of partly decomposed plant detritus. Drying associated with climate and land-use change may lead to increased fire frequency and severity in peatlands and the rapid loss of carbon to the atmosphere. However, our understanding of the patterns and drivers of peatland burning on an appropriate decadal to millennial timescale relies heavily on individual site-based reconstructions. For the first time, we synthesise peatland macrocharcoal records from across North America, Europe, and Patagonia to reveal regional variation in peatland burning during the Holocene. We used an existing database of proximal sedimentary charcoal to represent regional burning trends in the wider landscape for each region. Long-term trends in peatland burning appear to be largely climate driven, with human activities likely having an increasing influence in the late Holocene. Warmer conditions during the Holocene Thermal Maximum (∼9–6 cal. ka BP) were associated with greater peatland burning in North America's Atlantic coast, southern Scandinavia and the Baltics, and Patagonia. Since the Little Ice Age, peatland burning has declined across North America and in some areas of Europe. This decline is mirrored by a decrease in wider landscape burning in some, but not all sub-regions, linked to fire-suppression policies, and landscape fragmentation caused by agricultural expansion. Peatlands demonstrate lower susceptibility to burning than the wider landscape in several instances, probably because of autogenic processes that maintain high levels of near-surface wetness even during drought. Nonetheless, widespread drying and degradation of peatlands, particularly in Europe, has likely increased their vulnerability to burning in recent centuries. Consequently, peatland restoration efforts are important to mitigate the risk of peatland fire under a changing climate. Finally, we make recommendations for future research to improve our understanding of the controls on peatland fires. • We reconstruct peatland burning trends at mid-to high-latitudes for the Holocene. • Variation in climate, human activity and peatland processes influences burning. • Peatlands demonstrate lower susceptibility to burning than the wider landscape. • We outline the steps needed to better understand the drivers of peatland fire. [ABSTRACT FROM AUTHOR]

Published

2023

10. Can oxygen stable isotopes be used to track precipitation moisture source in vascular plant-dominated peatlands?

Author

Amesbury, Matthew J., Charman, Dan J., Newnham, Rewi M., Loader, Neil J., Goodrich, Jordan, Royles, Jessica, Campbell, David I., Keller, Elizabeth D., Baisden, W. Troy, Roland, Thomas P., and Gallego-Sala, Angela V.

Subjects

*OXYGEN isotopes, *STABLE isotopes, *PRECIPITATION (Chemistry), *VASCULAR plants, *PEATLANDS

Abstract

Variations in the isotopic composition of precipitation are determined by fractionation processes which occur during temperature- and humidity-dependent phase changes associated with evaporation and condensation. Oxygen stable isotope ratios have therefore been frequently used as a source of palaeoclimate data from a variety of proxy archives, which integrate this signal over time. Applications from ombrotrophic peatlands, where the source water used in cellulose synthesis is derived solely from precipitation, have been mostly limited to Northern Hemisphere Sphagnum -dominated bogs, with few in the Southern Hemisphere or in peatlands dominated by vascular plants. New Zealand (NZ) provides an ideal location to undertake empirical research into oxygen isotope fractionation in vascular peatlands because single taxon analysis can be easily carried out, in particular using the preserved root matrix of the restionaceous wire rush ( Empodisma spp.) that forms deep Holocene peat deposits throughout the country. Furthermore, large gradients are observed in the mean isotopic composition of precipitation across NZ, caused primarily by the relative influence of different climate modes. Here, we test whether δ 18 O of Empodisma α -cellulose from ombrotrophic restiad peatlands in NZ can provide a methodology for developing palaeoclimate records of past precipitation δ 18 O. Surface plant, water and precipitation samples were taken over spatial (six sites spanning >10° latitude) and temporal (monthly measurements over one year) gradients. A link between the isotopic composition of root-associated water, the most likely source water for plant growth, and precipitation in both datasets was found. Back-trajectory modelling of precipitation moisture source for rain days prior to sampling showed clear seasonality in the temporal data that was reflected in root-associated water. The link between source water and plant cellulose was less clear, although mechanistic modelling predicted mean cellulose values within published error margins for both datasets. Improved physiological understanding and modelling of δ 18 O in restiad peatlands should enable use of this approach as a new source of palaeoclimate data to reconstruct changes in past atmospheric circulation. [ABSTRACT FROM AUTHOR]

Published

2015

11. Ecology of peatland testate amoebae in Svalbard and the development of transfer functions for reconstructing past water-table depth and pH.

Author

Sim, Thomas G., Swindles, Graeme T., Morris, Paul J., Baird, Andy J., Charman, Dan J., Amesbury, Matthew J., Beilman, Dave, Channon, Alex, and Gallego-Sala, Angela V.

Subjects

*TRANSFER functions, *PEATLAND restoration, *MULTIVARIATE analysis, *AMOEBA, *ECOSYSTEM dynamics, *CURRENT distribution

Abstract

• Testate amoeba distributions are driven by water-table depth and pH in Svalbard. • We develop transfer functions for reconstructing peatland water-table depth and pH. • These represent the most northerly peatland testate amoeba transfer functions. • Weak idiosomic tests preserve poorly but removal has no impact on model performance. • Transfer functions are used to reconstruct peatland dynamics from 800 CE to present. Peatlands are valuable archives of information about past environmental conditions and represent a globally-important carbon store. Robust proxy methods are required to reconstruct past ecohydrological dynamics in high-latitude peatlands to improve our understanding of change in these carbon-rich ecosystems. The High Arctic peatlands in Svalbard are at the northern limit of current peatland distribution and have experienced rapidly rising temperatures of 0.81 °C per decade since 1958. We examine the ecology of peatland testate amoebae in surface vegetation samples from permafrost peatlands on Spitsbergen, the largest island of the Svalbard archipelago, and develop new transfer functions to reconstruct water-table depth (WTD) and pH that can be applied to understand past peatland ecosystem dynamics in response to climate change. These transfer functions are the first of their kind for peatlands in Svalbard and the northernmost developed to date. Multivariate statistical analysis shows that WTD and pore water pH are the dominant controls on testate amoeba species distribution. This finding is consistent with results from peatlands in lower latitudes with regard to WTD and supports work showing that when samples are taken across a long enough trophic gradient, peatland trophic status is an important control on the distribution of testate amoebae. No differences were found between transfer functions including and excluding the taxa with weak idiosomic tests (WISTs) that are most susceptible to decay. The final models for application to fossil samples therefore excluded these taxa. The WTD transfer function demonstrates the best performance (R2 LOO = 0.719, RMSEP LOO = 3.2 cm), but the pH transfer function also performs well (R2 LOO = 0.690, RMSEP LOO = 0.320). The transfer functions were applied to a core from western Spitsbergen and suggest drying conditions ~1750 CE, followed by a trend of recent wetting and increasing pH from ~1920 CE. These new transfer functions allow the reconstruction of past peatland WTD and pH in Svalbard, thereby enabling a greater understanding of long-term ecohydrological dynamics in these rapidly changing ecosystems. [ABSTRACT FROM AUTHOR]

Published

2021