36 results on '"Väliranta M"'
Search Results
2. Preservation of probable MIS 7 deglacial and nonglacial deposits near the edge of the Hudson Bay Lowland in Manitoba, Canada.
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Gauthier, M.S., Hodder, T.J., Dalton, A.S., Lian, Olav B., Schaarschmidt, M., Ross, M., Väliranta, M., and Finkelstein, S.A.
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OPTICALLY stimulated luminescence dating ,ICE sheets ,INTERGLACIALS ,SUPERPOSITION principle (Physics) ,SEDIMENT transport - Abstract
The stratigraphic principle of superposition assumes that sediments at surface are youngest. And yet, patches of older preserved landscapes continue to be identified in the regions formerly covered by the Laurentide Ice Sheet. Two gravel pits, at the edge of the western Hudson Bay Lowland near the geographic centre of the North American Ice Sheet Complex, reveal additional patches where older glacial and nonglacial sediment is preserved. These sites expose 1–4 m of a darker, highly overconsolidated, clayier till, and 0–2 m of a lighter, less consolidated, sandier till over glaciofluvial and post-glacial gravels and sands; the waning stages of deposition occurred at 214 ± 22 ka (1σ minimum age model quartz grain optical age estimates, n = 2). This was during the latter end of the cool Marine Isotope Stage (MIS) 7-d (within 1σ range) or near the end of MIS-8 (within 2σ range). Next followed a warmer period similar to, or warmer than, present day with higher precipitation; inferred from pollen and macrofossils deposited in nonglacial low-energy floodplain or pond sediments. Our study highlights the need to accurately date Quaternary sediments, given that the shallowest nonglacial sediments at both gravel pits were deposited during an old (MIS 7) interglacial; there is likely no record of the youngest interglacial (MIS 5). Preservation of older sediment also means that in Quaternary stratigraphy, disjoint regional nonglacial "organic marker beds" should not automatically be considered correlative. Identification of similar "old" patches, together with till stratigraphy and composition, is essential to accurately model glacial sediment transport over time. [ABSTRACT FROM AUTHOR]
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- 2024
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3. Newly initiated carbon stock, organic soil accumulation patterns and main driving factors in the High Arctic Svalbard, Norway
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Juselius, T., Ravolainen, V., Zhang, H., Piilo, S., Müller, M., Gallego-Sala, A., and Väliranta, M.
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- 2022
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4. Expert assessment of future vulnerability of the global peatland carbon sink
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Loisel, J., Gallego-Sala, A. V., Amesbury, M. J., Magnan, G., Anshari, G., Beilman, D. W., Benavides, J. C., Blewett, J., Camill, P., Charman, D. J., Chawchai, S., Hedgpeth, A., Kleinen, T., Korhola, A., Large, D., Mansilla, C. A., Müller, J., van Bellen, S., West, J. B., Yu, Z., Bubier, J. L., Garneau, M., Moore, T., Sannel, A. B. K., Page, S., Väliranta, M., Bechtold, M., Brovkin, V., Cole, L. E. S., Chanton, J. P., Christensen, T. R., Davies, M. A., De Vleeschouwer, F., Finkelstein, S. A., Frolking, S., Gałka, M., Gandois, L., Girkin, N., Harris, L. I., Heinemeyer, A., Hoyt, A. M., Jones, M. C., Joos, F., Juutinen, S., Kaiser, K., Lacourse, T., Lamentowicz, M., Larmola, T., Leifeld, J., Lohila, A., Milner, A. M., Minkkinen, K., Moss, P., Naafs, B. D. A., Nichols, J., O’Donnell, J., Payne, R., Philben, M., Piilo, S., Quillet, A., Ratnayake, A. S., Roland, T. P., Sjögersten, S., Sonnentag, O., Swindles, G. T., Swinnen, W., Talbot, J., Treat, C., Valach, A. C., and Wu, J.
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- 2021
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5. Author Correction: Expert assessment of future vulnerability of the global peatland carbon sink
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Loisel, J., Gallego-Sala, A. V., Amesbury, M. J., Magnan, G., Anshari, G., Beilman, D. W., Benavides, J. C., Blewett, J., Camill, P., Charman, D. J., Chawchai, S., Hedgpeth, A., Kleinen, T., Korhola, A., Large, D., Mansilla, C. A., Müller, J., van Bellen, S., West, J. B., Yu, Z., Bubier, J. L., Garneau, M., Moore, T., Sannel, A. B. K., Page, S., Väliranta, M., Bechtold, M., Brovkin, V., Cole, L. E. S., Chanton, J. P., Christensen, T. R., Davies, M. A., De Vleeschouwer, F., Finkelstein, S. A., Frolking, S., Gałka, M., Gandois, L., Girkin, N., Harris, L. I., Heinemeyer, A., Hoyt, A. M., Jones, M. C., Joos, F., Juutinen, S., Kaiser, K., Lacourse, T., Lamentowicz, M., Larmola, T., Leifeld, J., Lohila, A., Milner, A. M., Minkkinen, K., Moss, P., Naafs, B. D. A., Nichols, J., O’Donnell, J., Payne, R., Philben, M., Piilo, S., Quillet, A., Ratnayake, A. S., Roland, T. P., Sjögersten, S., Sonnentag, O., Swindles, G. T., Swinnen, W., Talbot, J., Treat, C., Valach, A. C., and Wu, J.
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- 2021
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6. Reconstructing peatland water tables using transfer functions for plant macrofossils and testate amoebae: A methodological comparison
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Väliranta, M., Blundell, A., Charman, D.J., Karofeld, E., Korhola, A., Sillasoo, Ü., and Tuittila, E.-S.
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- 2012
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7. Author Correction:Expert assessment of future vulnerability of the global peatland carbon sink (Nature Climate Change, (2021), 11, 1, (70-77), 10.1038/s41558-020-00944-0)
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Loisel, J., Gallego-Sala, A. V., Amesbury, M. J., Magnan, G., Anshari, G., Beilman, D. W., Benavides, J. C., Blewett, J., Camill, P., Charman, D. J., Chawchai, S., Hedgpeth, A., Kleinen, T., Korhola, A., Large, D., Mansilla, C. A., Müller, J., van Bellen, S., West, J. B., Yu, Z., Bubier, J. L., Garneau, M., Moore, T., Sannel, A. B.K., Page, S., Väliranta, M., Bechtold, M., Brovkin, V., Cole, L. E.S., Chanton, J. P., Christensen, T. R., Davies, M. A., De Vleeschouwer, F., Finkelstein, S. A., Frolking, S., Gałka, M., Gandois, L., Girkin, N., Harris, L. I., Heinemeyer, A., Hoyt, A. M., Jones, M. C., Joos, F., Juutinen, S., Kaiser, K., Lacourse, T., Lamentowicz, M., Larmola, T., Leifeld, J., Lohila, A., Milner, A. M., Minkkinen, K., Moss, P., Naafs, B. D.A., Nichols, J., O’Donnell, J., Payne, R., Philben, M., Piilo, S., Quillet, A., Ratnayake, A. S., Roland, T. P., Sjögersten, S., Sonnentag, O., Swindles, G. T., Swinnen, W., Talbot, J., Treat, C., Valach, A. C., and Wu, J.
- Abstract
In the version of this Analysis originally published, the following affiliation for A. Lohila was missing: ‘Finnish Meteorological Institute, Climate System Research, Helsinki, Finland’. This affiliation has now been added, and subsequent affiliations renumbered accordingly, in the online versions of the Analysis.
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- 2021
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8. Expert assessment of future vulnerability of the global peatland carbon sink
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Loisel, J, Gallego-Sala, AV, Amesbury, MJ, Magnan, G, Anshari, G, Beilman, DW, Benavides, JC, Blewett, J, Camill, P, Charman, DJ, Chawchai, S, Hedgpeth, A, Kleinen, T, Korhola, A, Large, D, Mansilla, CA, Müller, J, van Bellen, S, West, JB, Yu, Z, Bubier, JL, Garneau, M, Moore, T, Sannel, ABK, Page, S, Väliranta, M, Bechtold, M, Brovkin, V, Cole, LES, Chanton, JP, Christensen, TR, Davies, MA, De Vleeschouwer, F, Finkelstein, SA, Frolking, S, Gałka, M, Gandois, L, Girkin, N, Harris, LI, Heinemeyer, A, Hoyt, AM, Jones, MC, Joos, F, Juutinen, S, Kaiser, K, Lacourse, T, Lamentowicz, M, Larmola, T, Leifeld, J, Lohila, A, Milner, AM, Minkkinen, K, Moss, P, Naafs, BDA, Nichols, J, O’Donnell, J, Payne, R, Philben, M, Piilo, S, Quillet, A, Ratnayake, AS, Roland, TP, Sjögersten, S, Sonnentag, O, Swindles, GT, Swinnen, W, Talbot, J, Treat, C, Valach, AC, Wu, J, Loisel, J, Gallego-Sala, AV, Amesbury, MJ, Magnan, G, Anshari, G, Beilman, DW, Benavides, JC, Blewett, J, Camill, P, Charman, DJ, Chawchai, S, Hedgpeth, A, Kleinen, T, Korhola, A, Large, D, Mansilla, CA, Müller, J, van Bellen, S, West, JB, Yu, Z, Bubier, JL, Garneau, M, Moore, T, Sannel, ABK, Page, S, Väliranta, M, Bechtold, M, Brovkin, V, Cole, LES, Chanton, JP, Christensen, TR, Davies, MA, De Vleeschouwer, F, Finkelstein, SA, Frolking, S, Gałka, M, Gandois, L, Girkin, N, Harris, LI, Heinemeyer, A, Hoyt, AM, Jones, MC, Joos, F, Juutinen, S, Kaiser, K, Lacourse, T, Lamentowicz, M, Larmola, T, Leifeld, J, Lohila, A, Milner, AM, Minkkinen, K, Moss, P, Naafs, BDA, Nichols, J, O’Donnell, J, Payne, R, Philben, M, Piilo, S, Quillet, A, Ratnayake, AS, Roland, TP, Sjögersten, S, Sonnentag, O, Swindles, GT, Swinnen, W, Talbot, J, Treat, C, Valach, AC, and Wu, J
- Abstract
The carbon balance of peatlands is predicted to shift from a sink to a source this century. However, peatland ecosystems are still omitted from the main Earth system models that are used for future climate change projections, and they are not considered in integrated assessment models that are used in impact and mitigation studies. By using evidence synthesized from the literature and an expert elicitation, we define and quantify the leading drivers of change that have impacted peatland carbon stocks during the Holocene and predict their effect during this century and in the far future. We also identify uncertainties and knowledge gaps in the scientific community and provide insight towards better integration of peatlands into modelling frameworks. Given the importance of the contribution by peatlands to the global carbon cycle, this study shows that peatland science is a critical research area and that we still have a long way to go to fully understand the peatland–carbon–climate nexus.
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- 2021
9. The influence of Holocene tree-line advance and retreat on an arctic lake ecosystem: a multi-proxy study from Kharinei Lake, North Eastern European Russia
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Jones, V. J., Solovieva, N., Self, A. E., McGowan, S., Rosén, P., Salonen, J. S., Seppä, H., Väliranta, M., Parrott, E., and Brooks, S. J.
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- 2011
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10. Spatially varying peatland initiation, Holocene development, carbon accumulation patterns and radiative forcing within a subarctic fen
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Piilo, S. R. (Sanna R.), Korhola, A. (Atte), Heiskanen, L. (Lauri), Tuovinen, J.-P. (Juha-Pekka), Aurela, M. (Mika), Juutinen, S. (Sari), Marttila, H. (Hannu), Saari, M. (Markus), Tuittila, E.-S. (Eeva-Stiina), Turunen, J. (Jukka), Väliranta, M. M. (Minna M.), Piilo, S. R. (Sanna R.), Korhola, A. (Atte), Heiskanen, L. (Lauri), Tuovinen, J.-P. (Juha-Pekka), Aurela, M. (Mika), Juutinen, S. (Sari), Marttila, H. (Hannu), Saari, M. (Markus), Tuittila, E.-S. (Eeva-Stiina), Turunen, J. (Jukka), and Väliranta, M. M. (Minna M.)
- Abstract
High latitude peatlands act as globally important carbon (C) sinks and are in constant interaction with the atmosphere. Their C storage formed during the Holocene. In the course of time, the aggregate effect of the C fluxes on radiative forcing (RF) typically changes from warming to cooling, but the timing of this shift varies among different peatlands. Here we investigated Holocene peatland development, including vegetation history, vertical peat growth and the lateral expansion of a patterned subarctic fen in northern Finland by means of multiple sampling points. We modelled the Holocene RF by combining knowledge on past vegetation communities based on plant macrofossil stratigraphies and present in situ C flux measurements. The peatland initiated at ca. 9500 calibrated years Before Present (cal yr BP), and its lateral expansion was greatest between ca. 9000 and 7000 cal yr BP. After the early expansion, vertical peat growth proceeded very differently in different parts of the peatland, regulated by internal and external factors. The pronounced surface microtopography, with high strings and wet flarks, started to form only after ca. 1000 cal yr BP. C accumulation within the peatland recorded a high degree of spatial variability throughout its history, including the recent past. We applied two flux scenarios with different interpretation of the initial peatland development phases to estimate the RF induced by C fluxes of the fen. After ca. 4000 cal yr BP, at the latest, the peatland RF has been negative (cooling), mainly driven by C uptake and biomass production, while methane emissions had a lesser role in the total RF. Interestingly, these scenarios suggest that the greatest cooling effect took place around ca. 1000 cal yr BP, after which the surface microtopography established. The study demonstrated that despite the high spatial heterogeneity and idiosyncratic behaviour of the peatland, the RF of the studied fen followed the general development pattern
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- 2020
11. Expert assessment of future vulnerability of the global peatland carbon sink
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Loisel, J., primary, Gallego-Sala, A. V., additional, Amesbury, M. J., additional, Magnan, G., additional, Anshari, G., additional, Beilman, D. W., additional, Benavides, J. C., additional, Blewett, J., additional, Camill, P., additional, Charman, D. J., additional, Chawchai, S., additional, Hedgpeth, A., additional, Kleinen, T., additional, Korhola, A., additional, Large, D., additional, Mansilla, C. A., additional, Müller, J., additional, van Bellen, S., additional, West, J. B., additional, Yu, Z., additional, Bubier, J. L., additional, Garneau, M., additional, Moore, T., additional, Sannel, A. B. K., additional, Page, S., additional, Väliranta, M., additional, Bechtold, M., additional, Brovkin, V., additional, Cole, L. E. S., additional, Chanton, J. P., additional, Christensen, T. R., additional, Davies, M. A., additional, De Vleeschouwer, F., additional, Finkelstein, S. A., additional, Frolking, S., additional, Gałka, M., additional, Gandois, L., additional, Girkin, N., additional, Harris, L. I., additional, Heinemeyer, A., additional, Hoyt, A. M., additional, Jones, M. C., additional, Joos, F., additional, Juutinen, S., additional, Kaiser, K., additional, Lacourse, T., additional, Lamentowicz, M., additional, Larmola, T., additional, Leifeld, J., additional, Lohila, A., additional, Milner, A. M., additional, Minkkinen, K., additional, Moss, P., additional, Naafs, B. D. A., additional, Nichols, J., additional, O’Donnell, J., additional, Payne, R., additional, Philben, M., additional, Piilo, S., additional, Quillet, A., additional, Ratnayake, A. S., additional, Roland, T. P., additional, Sjögersten, S., additional, Sonnentag, O., additional, Swindles, G. T., additional, Swinnen, W., additional, Talbot, J., additional, Treat, C., additional, Valach, A. C., additional, and Wu, J., additional
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- 2020
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12. Successional change of testate amoeba assemblages along a space-for-time sequence of peatland development
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Zhang, H., primary, Väliranta, M., additional, Amesbury, M.J., additional, Charman, D.J., additional, Laine, A., additional, and Tuittila, E.-S., additional
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- 2018
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13. Inconsistent Response of Arctic Permafrost Peatland Carbon Accumulation to Warm Climate Phases
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Zhang, H., primary, Gallego‐Sala, A. V., additional, Amesbury, M. J., additional, Charman, D. J., additional, Piilo, S. R., additional, and Väliranta, M. M., additional
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- 2018
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14. A combined biogeochemical and paleobotanical approach to study permafrost environments and past dynamics
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Ronkainen, T., Väliranta, M., McClymont, E.L., Biasi, C., Salonen, S., Fontana, S., and Tuittila, E.-S.
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Fen ,n-alkane ,Permafrost ,Peat plateau ,Biomarker ,Macrofossil - Abstract
When investigating past peatland processes and related carbon cycle dynamics, it is essential to identify and separate different peat environments: bogs, fens and permafrost, and their historical plant assemblages. Bog peat layers contain relatively well-preserved plant material for palaeoecological examination, whereas fen and permafrost peats are often highly humified, which in turn constrains reconstructions of past plant assemblages. Here, we analysed the chemical composition of arctic peat plateau plants to create a local reference training-set of plant biomarkers. We then combined palaeobotanical, biogeochemical and chronological analyses to one permafrost peat sequence collected from the East European Russian tundra (67°03′N, 62°57′E) to investigate past peatland dynamics and to evaluate the performance of the biomarker method in a highly decomposed permafrost environment. The results show that the chronologically constrained macrofossil analysis provided most of the essential information about the peatland succession. However, a more robust reconstruction of the past peatland dynamics was achieved by combining palaeobotanical and biogeochemical data sets. The similarity of the lipid biomarker distributions of the arctic and boreal peatland plants also implies that any established modern biomarker training-set of peatland plants could be applied universally to palaeoecological studies on peat sediments.
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- 2015
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15. Plant macrofossil and biomarker evidence of fen-bog transition and associated changes in vegetation
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Ronkainen, T., McClymont, E.L., Tuitilla, E.-S., and Väliranta, M.
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Past plant assemblages ,Degradation ,n-alkane ,Fen peat ,Biomarker ,Fen–bog transition - Abstract
Past vegetation assemblages, preserved in peat layers, are one of the key proxies when reconstructing historical peatland dynamics. Northern peatlands can be divided into two main types: fens and bogs. Compared with bog peat, the fen peat is usually more decomposed because of different eco-hydrological conditions and effective humification processes. A high level of decomposition hampers reliable identification of plant remains and constrains palaeoecological approaches. Biogeochemical studies on bog plants and bog peat have shown that plant group–specific biomarkers can be applied to identify fossil plants or plant groups from peat, given the identification of plant group–specific markers in living fen plants. In this study, we applied plant macrofossil, biomarkers and multivariate statistical analyses to two mid-boreal peat sequences to investigate whether biomarkers can be applied to distinguish fen and bog environments and whether plant-specific biomarkers can be identified from fen peat. Macrofossil analyses clearly separate dry bog hummocks, moist lawns and wet fen habitats apart. Corresponding division emerged when the biomarker data were combined with the macrofossil data. Moreover, we succeeded to separate bog and fen habitats apart by the changes in n-alkane and the n-alkane ratio distributions along the cores. The fen–bog transition zone was indicated by high sterol and triterpenoid concentrations and changes in degradation measures. However, it remains a challenging task to attain species-level information of past plant assemblages from highly humified fen peat layers based on biomarkers only.
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- 2014
16. Effects of permafrost aggradation on peat properties as determined from a pan‐Arctic synthesis of plant macrofossils
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Treat, C. C., primary, Jones, M. C., additional, Camill, P., additional, Gallego‐Sala, A., additional, Garneau, M., additional, Harden, J. W., additional, Hugelius, G., additional, Klein, E. S., additional, Kokfelt, U., additional, Kuhry, P., additional, Loisel, J., additional, Mathijssen, P. J. H., additional, O'Donnell, J. A., additional, Oksanen, P. O., additional, Ronkainen, T. M., additional, Sannel, A. B. K., additional, Talbot, J., additional, Tarnocai, C., additional, and Väliranta, M., additional
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- 2016
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17. Fire pattern in a drainage-affected boreal bog
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Ronkainen, T., Väliranta, M., Eeva-Stiina Tuittila, Environmental Sciences, Department of Forest Sciences, and Environmental Change Research Unit (ECRU)
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1172 Environmental sciences - Abstract
Fire is an important natural disturbance element in the boreal zone, not only in the forested areas but also wetter peatland ecosystems. Predicted climate warming is expected to cause a moderate water-level drawdown in northern peatlands, which might result in increased frequency and severity of fires in boreal peatlands because of increase in fire-loading. We surveyed the fire pattern and the impact of drainage to the fire pattern on partly drained and pristine parts of a boreal raised bog using three sampling transects reaching from drainage-affected area to a pristine, fire-impacted bog area. We detected that dry bog hummock surfaces provided spreading routes for fire while hollow surfaces stayed almost intact. Drainage had promoted succession that lead to dominance of hummock vegetation. The lowered water level and abundance of hummock surfaces typical to the drainage-affected area was favourable for fire. The results suggest an increase in fire impact following drainage and that under changing climate bogs may become more vulnerable for fire.
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- 2013
18. Plant macrofossil evidence for an early onset of the Holocene summer thermal maximum in northernmost Europe
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Väliranta, M., primary, Salonen, J. S., additional, Heikkilä, M., additional, Amon, L., additional, Helmens, K., additional, Klimaschewski, A., additional, Kuhry, P., additional, Kultti, S., additional, Poska, A., additional, Shala, S., additional, Veski, S., additional, and Birks, H. H., additional
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- 2015
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19. Palaeoecological evidence of changes in vegetation and climate during the Holocene in the pre-Polar Urals, northeast European Russia
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Kultti, S., Väliranta, M., Sarmaja-Korjonen, K., Solovieva, N., Virtanen, T., Kauppila, T., Eronen, M., Department of Biological and Environmental Sciences, Bio- ja ympäristötieteiden laitos, and Bio- och miljövetenskaper, Institutionen för
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Holocene ,northern Russia ,lake-level changes ,tree-line ,palaeoclimate - Abstract
This study investigated Holocene tree-line history and climatic change in the pre-Polar Urals, northeast European Russia. A sediment core from Mezhgornoe Lake situated at the present-day alpine tree-line was studied for pollen, plant macrofossils, Cladocera and diatoms. A peat section from Vangyr Mire in the nearby mixed mountain taiga zone was analysed for pollen. The results suggest that the study area experienced a climatic optimum in the early Holocene and that summer temperatures were at least 2°C warmer than today. Tree birch immigrated to the Mezhgornoe Lake area at the onset of the Holocene. Mixed spruce forests followed at ca. 9500-9000 14C yr BP. Climate was moist and the water level of Mezhgornoe Lake rose rapidly. The hypsithermal phase lasted until ca. 5500-4500 14C yr BP, after which the mixed forest withdrew from the Mezhgornoe catchment as a result of the climate cooling. The gradual altitudinal downward shift of vegetation zones resulted in the present situation, with larch forming the tree-line. European Commission - Tundra Degredation in the Russian Arctic project; Grant Number: ENV4-CT97-0522
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- 2003
20. Short‐term and long‐term carbon dynamics in a northern peatland‐stream‐lake continuum: A catchment approach
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Juutinen, Sari, primary, Väliranta, M., additional, Kuutti, V., additional, Laine, A. M., additional, Virtanen, T., additional, Seppä, H., additional, Weckström, J., additional, and Tuittila, E‐S., additional
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- 2013
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21. Climate-related changes in peatland carbon accumulation during the last millennium
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Charman, D. J., primary, Beilman, D. W., additional, Blaauw, M., additional, Booth, R. K., additional, Brewer, S., additional, Chambers, F. M., additional, Christen, J. A., additional, Gallego-Sala, A., additional, Harrison, S. P., additional, Hughes, P. D. M., additional, Jackson, S. T., additional, Korhola, A., additional, Mauquoy, D., additional, Mitchell, F. J. G., additional, Prentice, I. C., additional, van der Linden, M., additional, De Vleeschouwer, F., additional, Yu, Z. C., additional, Alm, J., additional, Bauer, I. E., additional, Corish, Y. M. C., additional, Garneau, M., additional, Hohl, V., additional, Huang, Y., additional, Karofeld, E., additional, Le Roux, G., additional, Loisel, J., additional, Moschen, R., additional, Nichols, J. E., additional, Nieminen, T. M., additional, MacDonald, G. M., additional, Phadtare, N. R., additional, Rausch, N., additional, Sillasoo, Ü., additional, Swindles, G. T., additional, Tuittila, E.-S., additional, Ukonmaanaho, L., additional, Väliranta, M., additional, van Bellen, S., additional, van Geel, B., additional, Vitt, D. H., additional, and Zhao, Y., additional
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- 2013
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22. Climate-related changes in peatland carbon accumulation during the last millennium
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Charman, D. J., primary, Beilman, D. W., additional, Blaauw, M., additional, Booth, R. K., additional, Brewer, S., additional, Chambers, F. M., additional, Christen, J. A., additional, Gallego-Sala, A., additional, Harrison, S. P., additional, Hughes, P. D. M., additional, Jackson, S. T., additional, Korhola, A., additional, Mauquoy, D., additional, Mitchell, F. J. G., additional, Prentice, I. C., additional, van der Linden, M., additional, De Vleeschouwer, F., additional, Yu, Z. C., additional, Alm, J., additional, Bauer, I. E., additional, Corish, Y. M. C., additional, Garneau, M., additional, Hohl, V., additional, Huang, Y., additional, Karofeld, E., additional, Le Roux, G., additional, Loisel, J., additional, Moschen, R., additional, Nichols, J. E., additional, Nieminen, T. M., additional, MacDonald, G. M., additional, Phadtare, N. R., additional, Rausch, N., additional, Sillasoo, Ü., additional, Swindles, G. T., additional, Tuittila, E.-S., additional, Ukonmaanaho, L., additional, Väliranta, M., additional, van Bellen, S., additional, van Geel, B., additional, Vitt, D. H., additional, and Zhao, Y., additional
- Published
- 2012
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23. Quantifying patterns and controls of mire vegetation succession in a southern boreal bog in Finland using partial ordinations
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Tuittila, E.-S., primary, Väliranta, M., additional, Laine, J., additional, and Korhola, A., additional
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- 2007
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24. Expert assessment of future vulnerability of the global peatland carbon sink
- Author
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Loisel, J., Gallego-Sala, A. V., Amesbury, M. J., Magnan, G., Anshari, G., Beilman, D. W., Benavides, J. C., Blewett, J., Camill, P., Charman, D. J., Chawchai, S., Hedgpeth, A., Kleinen, T., Korhola, A., Large, D., Mansilla, C. A., Müller, J., van Bellen, S., West, J. B., Yu, Z., Bubier, J. L., Garneau, M., Moore, T., Sannel, A. B. K., Page, S., Väliranta, M., Bechtold, M., Brovkin, V., Cole, L. E. S., Chanton, J. P., Christensen, T. R., Davies, M. A., De Vleeschouwer, F., Finkelstein, S. A., Frolking, S., Gałka, M., Gandois, L., Girkin, N., Harris, L. I., Heinemeyer, A., Hoyt, A. M., Jones, M. C., Joos, F., Juutinen, S., Kaiser, K., Lacourse, T., Lamentowicz, M., Larmola, T., Leifeld, J., Lohila, A., Milner, A. M., Minkkinen, K., Moss, P., Naafs, B. D. A., Nichols, J., O’Donnell, J., Payne, R., Philben, M., Piilo, S., Quillet, A., Ratnayake, A. S., Roland, T. P., Sjögersten, S., Sonnentag, O., Swindles, G. T., Swinnen, W., Talbot, J., Treat, C., Valach, A. C., and Wu, J.
- Subjects
13. Climate action ,530 Physics ,550 Earth sciences & geology ,15. Life on land
25. Tropical peat composition may provide a negative feedback on fire occurrence and severity.
- Author
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Crawford AJ, Belcher CM, New S, Gallego-Sala A, Swindles GT, Page S, Blyakharchuk TA, Cadillo-Quiroz H, Charman DJ, Gałka M, Hughes PDM, Lähteenoja O, Mauquoy D, Roland TP, and Väliranta M
- Abstract
Loss of peat through increased burning will have major impacts on the global carbon cycle. In a normal hydrological state, the risk of fire propagation is largely controlled by peat bulk density and moisture content. However, where humans have interfered with the moisture status of peat either via drainage, or indirectly via climate change, we hypothesise that its botanical composition will become important to flammability, such that peats from different latitudes might have different compositionally-driven susceptibility to ignition. We use pyrolysis combustion flow calorimetry to determine the temperature of maximum thermal decomposition (T
max ) of peats from different latitudes, and couple this to a botanical composition analysis. We find that tropical peat has higher Tmax than other regions, likely on account of its higher wood content which appears to convey a greater resistance to ignition. This resistance also increases with depth, which means that loss of surface peat in tropical regions may lead to a reduction in the subsequent ignitability of deeper peat layers as they are exposed, potentially resulting in a negative feedback on increased fire occurrence and severity., (© 2024. The Author(s).)- Published
- 2024
- Full Text
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26. The ongoing lateral expansion of peatlands in Finland.
- Author
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Juselius-Rajamäki T, Väliranta M, and Korhola A
- Subjects
- Finland, Carbon Cycle, Carbon analysis, Ecosystem, Soil
- Abstract
Peatlands are the most dense terrestrial carbon stock and since the last glacial epoch northern peatlands have accumulated between 400 and 1000 Gt of carbon. Although the horizontal development history of the peatlands during the Holocene has been previously researched, these studies have overlooked the current peatland margins. This has led to a long-standing view that the lateral expansion of the peatlands has halted or significantly slowed down. However, no concentrated effort focusing on the recent development of the peatland margins has been conducted. To fulfil this knowledge gap, we studied the development of peatland margins in five Finnish peatlands. In addition, we studied the effect of peatland subsoil characteristics and past forest fires on the peatland expansion. We sampled 15 transects with a total of 47 peat cores utilizing
14 C radiocarbon dating on the basal layers of these peat cores. Our results show that the Northern peatlands are still expanding with four of our study sites having recent, post-1950's basal ages in the peatland margins. In addition, the rate of peatland lateral expansion has increased during the last 1500 years in our study sites, challenging the current knowledge of the recent peatland expansion dynamics. We recorded lateral expansion rates of 0.1-6.4 cm/year from the sites studied. The rate of lateral expansion was restricted by local characteristics, especially the steepness of subsoil (p = .0108). Forest fires likely played an important role as the trigger for lateral expansion in southern study sites with large number of charcoal found at the basal layer of the peat cores. Depending on the scope of this recent lateral expansion across the vast northern peatlands, the effect on the carbon balance could be significant and should be taken into account when estimating the development of carbon pools in these crucial ecosystems., (© 2023 The Authors. Global Change Biology published by John Wiley & Sons Ltd.)- Published
- 2023
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27. Recent climate change has driven divergent hydrological shifts in high-latitude peatlands.
- Author
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Zhang H, Väliranta M, Swindles GT, Aquino-López MA, Mullan D, Tan N, Amesbury M, Babeshko KV, Bao K, Bobrov A, Chernyshov V, Davies MA, Diaconu AC, Feurdean A, Finkelstein SA, Garneau M, Guo Z, Jones MC, Kay M, Klein ES, Lamentowicz M, Magnan G, Marcisz K, Mazei N, Mazei Y, Payne R, Pelletier N, Piilo SR, Pratte S, Roland T, Saldaev D, Shotyk W, Sim TG, Sloan TJ, Słowiński M, Talbot J, Taylor L, Tsyganov AN, Wetterich S, Xing W, and Zhao Y
- Subjects
- Climate Change, Hydrology, Soil, Amoeba, Permafrost
- Abstract
High-latitude peatlands are changing rapidly in response to climate change, including permafrost thaw. Here, we reconstruct hydrological conditions since the seventeenth century using testate amoeba data from 103 high-latitude peat archives. We show that 54% of the peatlands have been drying and 32% have been wetting over this period, illustrating the complex ecohydrological dynamics of high latitude peatlands and their highly uncertain responses to a warming climate., (© 2022. The Author(s).)
- Published
- 2022
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28. Identifying main uncertainties in estimating past and present radiative forcing of peatlands.
- Author
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Mathijssen PJH, Tuovinen JP, Lohila A, Väliranta M, and Tuittila ES
- Subjects
- Carbon, Soil, Uncertainty, Carbon Dioxide analysis, Methane
- Abstract
Reconstructions of past climate impact, that is, radiative forcing (RF), of peatland carbon (C) dynamics show that immediately after peatland initiation the climate warming effect of CH
4 emissions exceeds the cooling effect of CO2 uptake, but thereafter the net effect of most peatlands will move toward cooling, when RF switches from positive to negative. Reconstructing peatland C dynamics necessarily involves uncertainties related to basic assumptions on past CO2 flux, CH4 emission and peatland expansion. We investigated the effect of these uncertainties on the RF of three peatlands, using either apparent C accumulation rates, net C balance (NCB) or NCB plus C loss during fires as basis for CO2 uptake estimate; applying a plausible range for CH4 emission; and assuming linearly interpolated expansion between basal dates or comparatively early or late expansion. When we factored that some C would only be stored temporarily (NCB and NCB+fire), the estimated past cooling effect of CO2 uptake increased, but the present-day RF was affected little. Altering the assumptions behind the reconstructed CO2 flux or expansion patterns caused the RF to peak earlier and advanced the switch from positive to negative RF by several thousand years. Compared with NCB, including fires had only small additional effect on RF lasting less than 1000 year. The largest uncertainty in reconstructing peatland RF was associated with CH4 emissions. As shown by the consistently positive RF modelled for one site, and in some cases for the other two, peatlands with high CH4 emissions and low C accumulation rates may have remained climate warming agents since their initiation. Although uncertainties in present-day RF were mainly due to the assumed CH4 emission rates, the uncertainty in lateral expansion still had a significant effect on the present-day RF, highlighting the importance to consider uncertainties in the past peatland C balance in RF reconstructions., (© 2022 The Authors. Global Change Biology published by John Wiley & Sons Ltd.)- Published
- 2022
- Full Text
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29. Widespread recent ecosystem state shifts in high-latitude peatlands of northeastern Canada and implications for carbon sequestration.
- Author
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Magnan G, Sanderson NK, Piilo S, Pratte S, Väliranta M, van Bellen S, Zhang H, and Garneau M
- Subjects
- Carbon, Ecosystem, Soil, Wetlands, Carbon Sequestration, Sphagnopsida
- Abstract
Northern peatlands are a major component of the global carbon (C) cycle. Widespread climate-driven ecohydrological changes in these ecosystems can have major consequences on their C sequestration function. Here, we synthesize plant macrofossil data from 33 surficial peat cores from different ecoclimatic regions, with high-resolution chronologies. The main objectives were to document recent ecosystem state shifts and explore their impact on C sequestration in high-latitude undisturbed peatlands of northeastern Canada. Our synthesis shows widespread recent ecosystem shifts in peatlands, such as transitions from oligotrophic fens to bogs and Sphagnum expansion, coinciding with climate warming which has also influenced C accumulation during the last ~100 years. The rapid shifts towards drier bog communities and an expansion of Sphagnum sect. Acutifolia after 1980 CE were most pronounced in the northern subarctic sites and are concurrent with summer warming in northeastern Canada. These results provide further evidence of a northward migration of Sphagnum-dominated peatlands in North America in response to climate change. The results also highlight differences in the timing of ecosystem shifts among peatlands and regions, reflecting internal peatland dynamics and varying responses of vegetation communities. Our study suggests that the recent rapid climate-driven shifts from oligotrophic fen to drier bog communities have promoted plant productivity and thus peat C accumulation. We highlight the importance of considering recent ecohydrological trajectories when modelling the potential contribution of peatlands to climate change. Our study suggests that, contrary to expectations, peat C sequestration could be promoted in high-latitude non-permafrost peatlands where wet sedge fens may transition to drier Sphagnum bog communities due to warmer and longer growing seasons., (© 2021 John Wiley & Sons Ltd.)
- Published
- 2022
- Full Text
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30. Decreased carbon accumulation feedback driven by climate-induced drying of two southern boreal bogs over recent centuries.
- Author
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Zhang H, Väliranta M, Piilo S, Amesbury MJ, Aquino-López MA, Roland TP, Salminen-Paatero S, Paatero J, Lohila A, and Tuittila ES
- Abstract
Northern boreal peatlands are important ecosystems in modulating global biogeochemical cycles, yet their biological communities and related carbon dynamics are highly sensitive to changes in climate. Despite this, the strength and recent direction of these feedbacks are still unclear. The response of boreal peatlands to climate warming has received relatively little attention compared with other northern peatland types, despite forming a large northern hemisphere-wide ecosystem. Here, we studied the response of two ombrotrophic boreal peatlands to climate variability over the last c. 200 years for which local meteorological data are available. We used remains from plants and testate amoebae to study historical changes in peatland biological communities. These data were supplemented by peat property (bulk density, carbon and nitrogen content),
14 C,210 Pb and137 Cs analyses and were used to infer changes in peatland hydrology and carbon dynamics. In total, six peat cores, three per study site, were studied that represent different microhabitats: low hummock (LH), high lawn and low lawn. The data show a consistent drying trend over recent centuries, represented mainly as a change from wet habitat Sphagnum spp. to dry habitat S. fuscum. Summer temperature and precipitation appeared to be important drivers shaping peatland community and surface moisture conditions. Data from the driest microhabitat studied, LH, revealed a clear and strong negative linear correlation (R2 = .5031; p < .001) between carbon accumulation rate and peat surface moisture conditions: under dry conditions, less carbon was accumulated. This suggests that at the dry end of the moisture gradient, availability of water regulates carbon accumulation. It can be further linked to the decreased abundance of mixotrophic testate amoebae under drier conditions (R2 = .4207; p < .001). Our study implies that if effective precipitation decreases in the future, the carbon uptake capacity of boreal bogs may be threatened., (© 2020 John Wiley & Sons Ltd.)- Published
- 2020
- Full Text
- View/download PDF
31. Widespread global peatland establishment and persistence over the last 130,000 y.
- Author
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Treat CC, Kleinen T, Broothaerts N, Dalton AS, Dommain R, Douglas TA, Drexler JZ, Finkelstein SA, Grosse G, Hope G, Hutchings J, Jones MC, Kuhry P, Lacourse T, Lähteenoja O, Loisel J, Notebaert B, Payne RJ, Peteet DM, Sannel ABK, Stelling JM, Strauss J, Swindles GT, Talbot J, Tarnocai C, Verstraeten G, Williams CJ, Xia Z, Yu Z, Väliranta M, Hättestrand M, Alexanderson H, and Brovkin V
- Abstract
Glacial-interglacial variations in CO
2 and methane in polar ice cores have been attributed, in part, to changes in global wetland extent, but the wetland distribution before the Last Glacial Maximum (LGM, 21 ka to 18 ka) remains virtually unknown. We present a study of global peatland extent and carbon (C) stocks through the last glacial cycle (130 ka to present) using a newly compiled database of 1,063 detailed stratigraphic records of peat deposits buried by mineral sediments, as well as a global peatland model. Quantitative agreement between modeling and observations shows extensive peat accumulation before the LGM in northern latitudes (>40°N), particularly during warmer periods including the last interglacial (130 ka to 116 ka, MIS 5e) and the interstadial (57 ka to 29 ka, MIS 3). During cooling periods of glacial advance and permafrost formation, the burial of northern peatlands by glaciers and mineral sediments decreased active peatland extent, thickness, and modeled C stocks by 70 to 90% from warmer times. Tropical peatland extent and C stocks show little temporal variation throughout the study period. While the increased burial of northern peats was correlated with cooling periods, the burial of tropical peat was predominately driven by changes in sea level and regional hydrology. Peat burial by mineral sediments represents a mechanism for long-term terrestrial C storage in the Earth system. These results show that northern peatlands accumulate significant C stocks during warmer times, indicating their potential for C sequestration during the warming Anthropocene., Competing Interests: The authors declare no conflict of interest., (Copyright © 2019 the Author(s). Published by PNAS.)- Published
- 2019
- Full Text
- View/download PDF
32. Abrupt high-latitude climate events and decoupled seasonal trends during the Eemian.
- Author
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Salonen JS, Helmens KF, Brendryen J, Kuosmanen N, Väliranta M, Goring S, Korpela M, Kylander M, Philip A, Plikk A, Renssen H, and Luoto M
- Abstract
The Eemian (the Last Interglacial; ca. 129-116 thousand years ago) presents a testbed for assessing environmental responses and climate feedbacks under warmer-than-present boundary conditions. However, climate syntheses for the Eemian remain hampered by lack of data from the high-latitude land areas, masking the climate response and feedbacks in the Arctic. Here we present a high-resolution (sub-centennial) record of Eemian palaeoclimate from northern Finland, with multi-model reconstructions for July and January air temperature. In contrast with the mid-latitudes of Europe, our data show decoupled seasonal trends with falling July and rising January temperatures over the Eemian, due to orbital and oceanic forcings. This leads to an oceanic Late-Eemian climate, consistent with an earlier hypothesis of glacial inception in Europe. The interglacial is further intersected by two strong cooling and drying events. These abrupt events parallel shifts in marine proxy data, linked to disturbances in the North Atlantic oceanic circulation regime.
- Published
- 2018
- Full Text
- View/download PDF
33. Warm summers during the Younger Dryas cold reversal.
- Author
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Schenk F, Väliranta M, Muschitiello F, Tarasov L, Heikkilä M, Björck S, Brandefelt J, Johansson AV, Näslund JO, and Wohlfarth B
- Abstract
The Younger Dryas (YD) cold reversal interrupts the warming climate of the deglaciation with global climatic impacts. The sudden cooling is typically linked to an abrupt slowdown of the Atlantic Meridional Overturning Circulation (AMOC) in response to meltwater discharges from ice sheets. However, inconsistencies regarding the YD-response of European summer temperatures have cast doubt whether the concept provides a sufficient explanation. Here we present results from a high-resolution global climate simulation together with a new July temperature compilation based on plant indicator species and show that European summers remain warm during the YD. Our climate simulation provides robust physical evidence that atmospheric blocking of cold westerly winds over Fennoscandia is a key mechanism counteracting the cooling impact of an AMOC-slowdown during summer. Despite the persistence of short warm summers, the YD is dominated by a shift to a continental climate with extreme winter to spring cooling and short growing seasons.
- Published
- 2018
- Full Text
- View/download PDF
34. First physical evidence for forested environment in the Arctic during MIS 3.
- Author
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Sarala P, Väliranta M, Eskola T, and Vaikutiené G
- Abstract
Old sedimentological and geochronological records can be preserved underneath the central parts of the continental ice sheets under non-erosive, cold-based subglacial conditions. Organic deposits that predate the last deglaciation are of particular value for the information held on glacial-time climate and environmental conditions. In this study, we present multiproxy data derived from a well-preserved MIS 3 interstadial (55-25 ka ago) organic layer from inside the Arctic Circle in the Finnish Lapland. Biological proxy evidence, namely coming from aquatic plant species, indicates July temperatures as high as 14.4 °C, i.e. higher than those of today for the study site. Macrofossil evidence demonstrates for the first time the presence of pines accompanied by tree birch during the MIS 3 interstadial in northern Fennoscandia. These results concur with contemporary insolation model outcomes but contradict with the previous proxy-based view of open tundra conditions during the MIS 3. The data suggest that there are highly dynamic interstadial continental ice-sheet dynamics following changes in orbital forcing. Warm climate enabled the establishment of forests on exposed landscape. Moreover, we suggest that in the light of these new data, previous MIS 3 pollen data could be re-interpreted.
- Published
- 2016
- Full Text
- View/download PDF
35. The extent and meaning of hybridization and introgression between Siberian spruce (Picea obovata) and Norway spruce (Picea abies): cryptic refugia as stepping stones to the west?
- Author
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Tsuda Y, Chen J, Stocks M, Källman T, Sønstebø JH, Parducci L, Semerikov V, Sperisen C, Politov D, Ronkainen T, Väliranta M, Vendramin GG, Tollefsrud MM, and Lascoux M
- Subjects
- Bayes Theorem, DNA, Mitochondrial genetics, DNA, Plant genetics, Genotyping Techniques, Microsatellite Repeats, Models, Genetic, Picea classification, Population Dynamics, Russia, Scandinavian and Nordic Countries, Genetics, Population, Hybridization, Genetic, Picea genetics, Refugium
- Abstract
Boreal species were repeatedly exposed to ice ages and went through cycles of contraction and expansion while sister species alternated periods of contact and isolation. The resulting genetic structure is consequently complex, and demographic inferences are intrinsically challenging. The range of Norway spruce (Picea abies) and Siberian spruce (Picea obovata) covers most of northern Eurasia; yet their geographical limits and histories remain poorly understood. To delineate the hybrid zone between the two species and reconstruct their joint demographic history, we analysed variation at nuclear SSR and mitochondrial DNA in 102 and 88 populations, respectively. The dynamics of the hybrid zone was analysed with approximate Bayesian computation (ABC) followed by posterior predictive structure plot reconstruction and the presence of barriers across the range tested with estimated effective migration surfaces. To estimate the divergence time between the two species, nuclear sequences from two well-separated populations of each species were analysed with ABC. Two main barriers divide the range of the two species: one corresponds to the hybrid zone between them, and the other separates the southern and northern domains of Norway spruce. The hybrid zone is centred on the Urals, but the genetic impact of Siberian spruce extends further west. The joint distribution of mitochondrial and nuclear variation indicates an introgression of mitochondrial DNA from Norway spruce into Siberian spruce. Overall, our data reveal a demographic history where the two species interacted frequently and where migrants originating from the Urals and the West Siberian Plain recolonized northern Russia and Scandinavia using scattered refugial populations of Norway spruce as stepping stones towards the west., (© 2016 John Wiley & Sons Ltd.)
- Published
- 2016
- Full Text
- View/download PDF
36. Proxy comparison in ancient peat sediments: pollen, macrofossil and plant DNA.
- Author
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Parducci L, Väliranta M, Salonen JS, Ronkainen T, Matetovici I, Fontana SL, Eskola T, Sarala P, and Suyama Y
- Subjects
- Base Sequence, DNA, Plant classification, DNA, Plant history, Finland, History, Ancient, Molecular Sequence Data, Multiplex Polymerase Chain Reaction, Russia, Sequence Analysis, DNA methods, DNA, Plant genetics, Fossils, Geologic Sediments chemistry, Pollen genetics, Soil chemistry
- Abstract
We compared DNA, pollen and macrofossil data obtained from Weichselian interstadial (age more than 40 kyr) and Holocene (maximum age 8400 cal yr BP) peat sediments from northern Europe and used them to reconstruct contemporary floristic compositions at two sites. The majority of the samples provided plant DNA sequences of good quality with success amplification rates depending on age. DNA and sequencing analysis provided five plant taxa from the older site and nine taxa from the younger site, corresponding to 7% and 15% of the total number of taxa identified by the three proxies together. At both sites, pollen analysis detected the largest (54) and DNA the lowest (10) number of taxa, but five of the DNA taxa were not detected by pollen and macrofossils. The finding of a larger overlap between DNA and pollen than between DNA and macrofossils proxies seems to go against our previous suggestion based on lacustrine sediments that DNA originates principally from plant tissues and less from pollen. At both sites, we also detected Quercus spp. DNA, but few pollen grains were found in the record, and these are normally interpreted as long-distance dispersal. We confirm that in palaeoecological investigations, sedimentary DNA analysis is less comprehensive than classical morphological analysis, but is a complementary and important tool to obtain a more complete picture of past flora., (© 2014 The Author(s) Published by the Royal Society. All rights reserved.)
- Published
- 2015
- Full Text
- View/download PDF
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