Your search keyword '"Reitalu, Triin"' showing total 10 results

1. Long-term forest composition and its drivers in taiga forest in NW Russia

Author

Kuosmanen, Niina, Seppä, Heikki, Reitalu, Triin, Alenius, Teija, Bradshaw, Richard H. W., Clear, Jennifer L., Filimonova, Ludmila, Kuznetsov, Oleg, and Zaretskaya, Natalia

Published

2016

2. Editorial : Past interactions between climate, land use, and vegetation

Author

Marquer, Laurent, Seim, Andrea, Kuosmanen, Niina, Reitalu, Triin, Solomina, Olga, Tallavaara, Miikka, Department of Geosciences and Geography, and Hominin Ecology

Subjects

1171 Geosciences, Tree-rings, Dendrochronology, Multiproxy analysis, Pollen, Data integration, Past land-cover, 1172 Environmental sciences

Published

2023

3. Closing the gap between plant ecology and Quaternary palaeoecology

Author

Reitalu, Triin, Kuneš, Petr, and Giesecke, Thomas

Published

2014

4. Landscape change in central Latvia since the Iron Age: multi-proxy analysis of the vegetation impact of conflict, colonization and economic expansion during the last 2,000 years

Author

Stivrins, Normunds, Brown, Alex, Reitalu, Triin, Veski, Siim, Heinsalu, Atko, Banerjea, Rowena Yvonne, and Elmi, Kati

Published

2015

5. Mire plant diversity change over the last 10,000 years: Importance of isostatic land uplift, climate and local conditions.

Author

Blaus, Ansis, Reitalu, Triin, Poska, Anneli, Vassiljev, Jüri, and Veski, Siim

Subjects

*PLANT diversity, *FENS, *PEATLANDS, *BOGS, *ECOSYSTEM services, *POLLEN, *BIODIVERSITY

Abstract

Mires or peatlands host unique biodiversity and provide many valuable ecosystem services. Mires often undergo different development phases during their evolution. Two mire phases that have clearly divergent hydrological regimes and characteristic biotas are minerotrophic fen and ombrotrophic bog. Open mires can be overgrown by trees and develop into peatland forests. Mire development trajectories are expected to be associated with three major factors—post‐glacial isostatic uplift, autogenic succession and climate‐induced changes. Understanding long‐term mire development is important for the conservation planning of these threatened habitats.We use data from modern pollen samples to characterize differences between the pollen signal and to identify indicator pollen taxa for three mire development phases—open fens, forested fens and bogs. The modern reference samples are then used to support the interpretation of the sediment records in terms of mire development phases and related biodiversity changes in six mires within a 20 × 30 km area in western Saaremaa, Estonia. Palynological richness and phylogenetic diversity (PD) as well as Ellenberg indicator values are compared throughout the 10,000‐year history of the Saaremaa mires.Pollen of herbaceous taxa discriminates between open fens, forested fens and bogs, and indicator pollen taxa can be associated with each mire phase. In general, the fen phases of the mires show higher richness and PD than the bog phases but there is considerable variation between the sites. The mire diversity peaks are often associated with transitional periods when high local community heterogeneity allows the coexistence of high numbers of taxa from different phylogenetic lineages.Synthesis. When the initiation of mires in isostatic land uplift areas is closely related to water‐level changes and the position of the sites in relation to the sea, the development of mires and their biodiversity in the late Holocene is associated with local conditions but mediated by climate. The ongoing rapid climate change is likely to accelerate changes in existing mires, and while the transitional periods are characterized by high diversity, these periods are temporary, and the overall diversity of mires can be expected to decrease. [ABSTRACT FROM AUTHOR]

Published

2021

6. Postglacial flooding and vegetation history on the Ob River terrace, central Western Siberia based on the palaeoecological record from Lake Svetlenkoye.

Author

Amon, Leeli, Blaus, Ansis, Alliksaar, Tiiu, Heinsalu, Atko, Lapshina, Elena, Liiv, Merlin, Reitalu, Triin, Vassiljev, Jüri, and Veski, Siim

Subjects

WATER depth, BODIES of water, DIATOMS, LAKES, RIVERS, FLOODPLAINS, PINACEAE

Abstract

The hemispheric-scale climatic fluctuations during the Holocene have probably influenced the large Siberian rivers. However, detailed studies of the West Siberian Plain postglacial environmental change are scarce and the records of millennial-scale palaeohydrology are nearly absent. This paper presents the Holocene palaeoecological reconstruction based on the sedimentary record of Lake Svetlenkoye, located near the confluence of major Siberian rivers Ob and Irtysh. Postglacial history of flooding, dynamics of regional and local vegetation, sedimentation regime, geochemical changes and lake water pH were reconstructed based on multi-proxy studies. We used palaeobotanical (plant macrofossils, pollen, diatoms), geochemical (organic matter, total organic carbon and nitrogen content, carbon/nitrogen ratio) and chronological (14C dates, spheroidal fly-ash particle counts) methods. The studied sediment section started to accumulate ~11,400 cal. yr BP. The initial shallow water body was flooded by Ob River waters ~8100–8000 cal. yr BP as confirmed by a remarkable increase in the sedimentation rate and the accumulation rate of the aquatic vegetation proxies. The period of flooding coincides with the high humidity periods reconstructed from regional palaeobotanical records. About 6800–6700 cal. yr BP, the study site became isolated from the Ob River floodplain and remained a small lake until present. The diatom-based lake water pH estimates suggest fluctuations in the pH values during the Holocene, the recent decrease since 1960s being the most notable. The vegetation record revealed constant postglacial presence of tree taxa – Betula, Pinus and Picea – although in different pollen ratios and accumulation rates through time. The paludification of the surroundings occurred since ca. 8500 cal. yr BP. [ABSTRACT FROM AUTHOR]

Published

2020

7. Patterns of modern pollen and plant richness across northern Europe.

Author

Reitalu, Triin, Bjune, Anne E., Blaus, Ansis, Giesecke, Thomas, Helm, Aveliina, Matthias, Isabelle, Peglar, Sylvia M., Salonen, J. Sakari, Seppä, Heikki, Väli, Vivika, Birks, H. John B., and de Lafontaine, Guillaume

Subjects

*POLLEN, *PLANT capacity, *PLANT diversity, *VEGETATION dynamics, *CLIMATE change, *PRODUCTION increases

Abstract

Sedimentary pollen offers excellent opportunities to reconstruct vegetation changes over past millennia. Number of different pollen taxa or pollen richness is used to characterise past plant richness. To improve the interpretation of sedimentary pollen richness, it is essential to understand the relationship between pollen and plant richness in contemporary landscapes. This study presents a regional‐scale comparison of pollen and plant richness from northern Europe and evaluates the importance of environmental variables on pollen and plant richness.We use a pollen dataset of 511 lake‐surface pollen samples ranging through temperate, boreal and tundra biomes. To characterise plant diversity, we use a dataset formulated from the two largest plant atlases available in Europe. We compare pollen and plant richness estimates in different groups of taxa (wind‐pollinated vs. non‐wind‐pollinated, trees and shrubs vs. herbs and grasses) and test their relationships with climate and landscape variables.Pollen richness is significantly positively correlated with plant richness (r = 0.53). The pollen plant richness correlation improves (r = 0.63) when high pollen producers are downweighted prior to estimating richness minimising the influence of pollen production on the pollen richness estimate. This suggests that methods accommodating pollen‐production differences in richness estimates deserve further attention and should become more widely used in Quaternary pollen diversity studies.The highest correlations are found between pollen and plant richness of trees and shrubs (r = 0.83) and of wind‐pollinated taxa (r = 0.75) suggesting that these are the best measures of broad‐scale plant richness over several thousands of square kilometres.Mean annual temperature is the strongest predictor of both pollen and plant richness. Landscape openness is positively associated with pollen richness but not with plant richness. Pollen richness values from extremely open and/or cold areas where pollen production is low should be interpreted with caution because low local pollen production increases the proportion of extra‐regional pollen.Synthesis. Our results confirm that pollen data can provide insights into past plant richness changes in northern Europe, and with careful consideration of pollen‐production differences and spatial scale represented, pollen data make it possible to investigate vegetation diversity trends over long time‐scales and under changing climatic and habitat conditions. [ABSTRACT FROM AUTHOR]

Published

2019

8. The role of climate, forest fires and human population size in Holocene vegetation dynamics in Fennoscandia.

Author

Kuosmanen, Niina, Marquer, Laurent, Tallavaara, Miikka, Molinari, Chiara, Zhang, Yurui, Alenius, Teija, Edinborough, Kevan, Pesonen, Petro, Reitalu, Triin, Renssen, Hans, Trondman, Anna‐kari, and Seppä, Heikki

Subjects

VEGETATION dynamics, FOREST fires, RADIOCARBON dating, AGRICULTURE

Abstract

Abstract: Questions: We investigated the changing role of climate, forest fires and human population size in the broad‐scale compositional changes in Holocene vegetation dynamics before and after the onset of farming in Sweden (at 6,000 cal yr BP) and in Finland (at 4,000 cal yr BP). Location: Southern and central Sweden, SW and SE Finland. Methods: Holocene regional plant abundances were reconstructed using the REVEALS model on selected fossil pollen records from lakes. The relative importance of climate, fires and human population size on changes in vegetation composition was assessed using variation partitioning. Past climate variable was derived from the LOVECLIM climate model. Fire variable was reconstructed from sedimentary charcoal records. Estimated trend in human population size was based on the temporal distribution of archaeological radiocarbon dates. Results: Climate explains the highest proportion of variation in vegetation composition during the whole study period in Sweden (10,000–4,000 cal yr BP) and in Finland (10,000–1,000 cal yr BP), and during the pre‐agricultural period. In general, fires explain a relatively low proportion of variation. Human population size has significant effect on vegetation dynamics after the onset of farming and explains the highest variation in vegetation in S Sweden and SW Finland. Conclusions: Mesolithic hunter‐gatherer populations did not significantly affect vegetation composition in Fennoscandia, and climate was the main driver of changes at that time. Agricultural communities, however, had greater effect on vegetation dynamics, and the role of human population size became a more important factor during the late Holocene. Our results demonstrate that climate can be considered the main driver of long‐term vegetation dynamics in Fennoscandia. However, in some regions the influence of human population size on Holocene vegetation changes exceeded that of climate and has a longevity dating to the early Neolithic. [ABSTRACT FROM AUTHOR]

Published

2018

9. Biotic turnover rates during the Pleistocene-Holocene transition.

Author

Stivrins, Normunds, Soininen, Janne, Amon, Leeli, Fontana, Sonia L., Gryguc, Gražyna, Heikkilä, Maija, Heiri, Oliver, Kisielienė, Dalia, Reitalu, Triin, Stančikaitė, Miglė, Veski, Siim, and Seppä, Heikki

Subjects

*PLEISTOCENE-Holocene boundary, *BIOTIC communities, *ICE sheets, *FOSSIL microorganisms, *CHIRONOMIDAE

Abstract

The Northern Hemisphere is currently warming at the rate which is unprecedented during the Holocene. Quantitative palaeoclimatic records show that the most recent time in the geological history with comparable warming rates was during the Pleistocene-Holocene transition (PHT) about 14,000 to 11,000 years ago. To better understand the biotic response to rapid temperature change, we explore the community turnover rates during the PHT by focusing on the Baltic region in the southeastern sector of the Scandinavian Ice Sheet, where an exceptionally dense network on microfossil and macrofossil data that reflect the biotic community history are available. We further use a composite chironomid-based summer temperature reconstruction compiled specifically for our study region to calculate the rate of temperature change during the PHT. The fastest biotic turnover in the terrestrial and aquatic communities occurred during the Younger Dryas-Holocene shift at 11,700 years ago. This general shift in species composition was accompanied by regional extinctions, including disappearance of mammoth ( Mammuthus primigenius ) and reindeer ( Rangifer tarandus ) and many arctic-alpine plant taxa, such as Dryas octopetala , Salix polaris and Saxifraga aizoides , from the region. This rapid biotic turnover rate occurred when the rate of warming was 0.17 °C/decade, thus slightly lower than the current Northern Hemisphere warming of 0.2 °C/decade. We therefore conclude that the Younger Dryas-Holocene shift with its rapid turnover rates and associated regional extinctions represents an important palaeoanalogue to the current high latitude warming and gives insights about the probable future turnover rates and patterns of the terrestrial and aquatic ecosystem change. [ABSTRACT FROM AUTHOR]

Published

2016

10. Quantitative summer and winter temperature reconstructions from pollen and chironomid data between 15 and 8 ka BP in the Baltic–Belarus area.

Author

Veski, Siim, Seppä, Heikki, Stančikaitė, Migle, Zernitskaya, Valentina, Reitalu, Triin, Gryguc, Gražyna, Heinsalu, Atko, Stivrins, Normunds, Amon, Leeli, Vassiljev, Jüri, and Heiri, Oliver

Subjects

*ATMOSPHERIC temperature, *POLLEN, *CHIRONOMIDAE, *PALEOCLIMATOLOGY

Abstract

New pollen based reconstructions of summer (May-to-August) and winter (December-to-February) temperatures between 15 and 8 ka BP along a S–N transect in the Baltic–Belarus (BB) area display trends in temporal and spatial changes in climate variability. These results are completed by two chironomid-based July mean temperature reconstructions. The magnitude of change compared with modern temperatures was more prominent in the northern part of BB area. The 4 C° winter and 2 C° summer warming at the start of GI-1 was delayed in the BB area and Lateglacial maximum temperatures were reached at ca 13.6 ka BP, being 4 C° colder than the modern mean. The Younger Dryas cooling in the area was 5 C° colder than present, as inferred by all proxies. In addition, our analyses show an early Holocene divergence in winter temperature trends with modern values reaching 1 ka earlier (10 ka BP) in southern BB compared to the northern part of the region (9 ka BP). [ABSTRACT FROM AUTHOR]

Published

2015