Your search keyword '"Lang, S.I."' showing total 8 results

1. Limited sensitivity of permafrost soils to heavy rainfall across Svalbard ecosystems

Author

Magnússon, R.Í., Schuuring, S., Hamm, A., Verhoeven, M.A., Limpens, J., Loonen, M.J.E.E., and Lang, S.I.

Published

2024

2. Five decades of terrestrial and freshwater research at Ny-Ålesund, Svalbard

Author

Pedersen, Å.Ø., Convey, P., Newsham, K.K., Mosbacher, J.B., Fuglei, E., Ravolainen, V., Hansen, B.B., Jensen, T.C., Augusti, A., Biersma, E.M., Cooper, E.J., Coulson, S.J., Gabrielsen, G.W., Gallet, J.C., Karsten, U., Kristiansen, S.M., Svenning, M.M., Tveit, A.T., Uchida, M., Baneschi, I., Calizza, E., Cannone, N., de Goede, E.M., Doveri, M., Elster, J., Giamberini, M.S., Hayashi, K., Lang, S.I., Lee, Y.K., Nakatsubo, T., Pasquali, V., Paulsen, I.M.G., Pedersen, C., Peng, F., Provenzale, A., Pushkareva, E., Sandström, C.A.M., Sklet, V., Stach, A., Tojo, M., Tytgat, B., Tømmervik, H., Velazquez, D., Verleyen, E., Welker, J.M., Yao, Y.-F., Loonen, M.J.J.E., Pedersen, Å.Ø., Convey, P., Newsham, K.K., Mosbacher, J.B., Fuglei, E., Ravolainen, V., Hansen, B.B., Jensen, T.C., Augusti, A., Biersma, E.M., Cooper, E.J., Coulson, S.J., Gabrielsen, G.W., Gallet, J.C., Karsten, U., Kristiansen, S.M., Svenning, M.M., Tveit, A.T., Uchida, M., Baneschi, I., Calizza, E., Cannone, N., de Goede, E.M., Doveri, M., Elster, J., Giamberini, M.S., Hayashi, K., Lang, S.I., Lee, Y.K., Nakatsubo, T., Pasquali, V., Paulsen, I.M.G., Pedersen, C., Peng, F., Provenzale, A., Pushkareva, E., Sandström, C.A.M., Sklet, V., Stach, A., Tojo, M., Tytgat, B., Tømmervik, H., Velazquez, D., Verleyen, E., Welker, J.M., Yao, Y.-F., and Loonen, M.J.J.E.

Abstract

For more than five decades, research has been conducted at Ny-Ålesund, in Svalbard, Norway, to understand the structure and functioning of High-Arctic ecosystems and the profound impacts on them of environmental change. Terrestrial, freshwater, glacial and marine ecosystems are accessible year-round from Ny-Ålesund, providing unique opportunities for interdisciplinary observational and experimental studies along physical, chemical, hydrological and climatic gradients. Here, we synthesize terrestrial and freshwater research at Ny-Ålesund and review current knowledge of biodiversity patterns, species population dynamics and interactions, ecosystem processes, biogeochemical cycles and anthropogenic impacts. There is now strong evidence of past and ongoing biotic changes caused by climate change, including negative effects on populations of many taxa and impacts of rain-on-snow events across multiple trophic levels. While species-level characteristics and responses are well understood for macro-organisms, major knowledge gaps exist for microbes, invertebrates and ecosystem-level processes. In order to fill current knowledge gaps, we recommend (1) maintaining monitoring efforts, while establishing a long-term ecosystem-based monitoring programme; (2) gaining a mechanistic understanding of environmental change impacts on processes and linkages in food webs; (3) identifying trophic interactions and cascades across ecosystems; and (4) integrating long-term data on microbial, invertebrate and freshwater communities, along with measurements of carbon and nutrient fluxes among soils, atmosphere, freshwaters and the marine environment. The synthesis here shows that the Ny-Ålesund study system has the characteristics needed to fill these gaps in knowledge, thereby enhancing our understanding of High-Arctic ecosystems and their responses to environmental variability and change.

Published

2022

3. Five decades of terrestrial and freshwater research at Ny-Ålesund, Svalbard

Author

Pedersen, Å.Ø., primary, Convey, P., additional, Newsham, K.K., additional, Mosbacher, J.B., additional, Fuglei, E., additional, Ravolainen, V., additional, Hansen, B.B., additional, Jensen, T.C., additional, Augusti, A., additional, Biersma, E.M., additional, Cooper, E.J., additional, Coulson, S.J., additional, Gabrielsen, G.W., additional, Gallet, J.C., additional, Karsten, U., additional, Kristiansen, S.M., additional, Svenning, M.M., additional, Tveit, A.T., additional, Uchida, M., additional, Baneschi, I., additional, Calizza, E., additional, Cannone, N., additional, de Goede, E.M., additional, Doveri, M., additional, Elster, J., additional, Giamberini, M.S., additional, Hayashi, K., additional, Lang, S.I., additional, Lee, Y.K., additional, Nakatsubo, T., additional, Pasquali, V., additional, Paulsen, I.M.G., additional, Pedersen, C., additional, Peng, F., additional, Provenzale, A., additional, Pushkareva, E., additional, Sandström, C.A.M., additional, Sklet, V., additional, Stach, A., additional, Tojo, M., additional, Tytgat, B., additional, Tømmervik, H., additional, Velazquez, D., additional, Verleyen, E., additional, Welker, J.M., additional, Yao, Y.-F., additional, and Loonen, M.J.J.E., additional

Published

2022

4. Similar cation exchange capacities among bryophyte species refute a presumed mechanism of peatland acidification

Author

Soudzilovskaia, N.A., Cornelissen, J.H.C., During, H.J., van Logtestijn, R.S.P., Lang, S.I., and Aerts, R.

Subjects

Soil acidification -- Research, Ion exchange -- Research, Peat mosses -- Research, Biological sciences, Environmental issues

Abstract

Fen--bog succession is accompanied by strong increases of carbon accumulation rates. We tested the prevailing hypothesis that living Sphagna have extraordinarily high cation exchange capacity (CEC) and therefore acidify their environment by exchanging tissue-bound protons for basic cations in soil water. As Sphagnum invasion in a peatland usually coincides with succession from a brown moss-dominated alkaline fen to an acidic bog, the CEC of Sphagna is widely believed to play an important role in this acidification process. However, Sphagnum CEC has never been compared explicitly to that of a wide range of other bryophyte taxa. Whether high CEC directly leads to the ability to acidify the environment in situ also remains to be tested. We screened 20 predominant subarctic bryophyte species, including fen brown mosses and bog Sphagna for CEC, in situ soil water acidification capacity (AC), and peat acid neutralizing capacity (ANC). All these bryophyte species possessed substantial CEC, which was remarkably similar for brown mosses and Sphagna. This refutes the commonly accepted idea of living Sphagnum CEC being responsible for peatland acidification, as Sphagnum's ecological predecessors, brown mosses, can do the same job. Sphagnum AC was several times higher than that of other bryophytes, suggesting that CE (cation exchange) sites of Sphagna in situ are not saturated with basic cations, probably due to the virtual absence of these cations in the bog water. Together, these results suggest that Sphagna can not realize their CEC in bogs, while fen mosses can do so in fens. The fen peat ANC was 65% higher than bog ANC, indicating that acidity released by brown mosses in the CE process was neutralized, maintaining an alkaline environment. We propose two successional pathways indicating boundaries for a fen bog shift with respect to bryophyte CEC. In neither of them is Sphagnum CE an important factor. We conclude that living Sphagnum CEC does not play any considerable role in the fen--bog shift. Alternatively, we propose that exclusively indirect effects of Sphagnum expansion such as peat accumulation and subsequent blocking of upward alkaline soil water transport are keys to the fen bog succession and therefore for bog-associated carbon accumulation. Key words: acidification; acidity; acid neutralizing capacity; bog; brown moss; bryophyte; carbon cycling; CEC (cation exchange capacity); fen, moss; Sphagnum spp.; succession.

Published

2010

5. Global assessment of experimental climater warming on tundra vegetation: Heterogeneity over space and time

Author

Elmendorf, S.C., Henry, G.H.R., Hollister, R.D., Bjork, R.G., Bjorkman, A.J., Callaghan, T.V., Cooper, E.J., Cornelissen, J.H.C., Day, T.A., Maria Fosaa, A., Gould, W.A., Gretarsdottir, J., Harte, J., Hermanutz, L., Hik, D.A., Hofgaard, A., Jarrad, F., Keuper, F., Jonsdottir, I.S., Klanderud, K., Klein, J.A., Koh, S., Kudo, G., Lang, S.I., Lowen, V., May, J.L., Mercado, J., Michelsen, A., Molau, U., Pieper, S., Robinson, C.H., Siegart, L., Myers-Smith, I., Oberbauer, S.F., Post, E., Rixen, C., Martin Schmidt, N., Shaver, G.R., Tolvanen, A., Totland, O., Troxler, T., Wahren, C.H., Webber, P.J., Welker, J.M., Wookey, P.A., Systems Ecology, and Amsterdam Global Change Institute

Subjects

SDG 13 - Climate Action

Abstract

Understanding the sensitivity of tundra vegetation to climate warming is critical to forecasting future biodiversity and vegetation feedbacks to climate. In situ warming experiments accelerate climate change on a small scale to forecast responses of local plant communities. Limitations of this approach include the apparent site-specificity of results and uncertainty about the power of short-term studies to anticipate longer term change. We address these issues with a synthesis of 61 experimental warming studies, of up to 20years duration, in tundra sites worldwide. The response of plant groups to warming often differed with ambient summer temperature, soil moisture and experimental duration. Shrubs increased with warming only where ambient temperature was high, whereas graminoids increased primarily in the coldest study sites. Linear increases in effect size over time were frequently observed. There was little indication of saturating or accelerating effects, as would be predicted if negative or positive vegetation feedbacks were common. These results indicate that tundra vegetation exhibits strong regional variation in response to warming, and that in vulnerable regions, cumulative effects of long-term warming on tundra vegetation - and associated ecosystem consequences - have the potential to be much greater than we have observed to date. © 2011 Blackwell Publishing Ltd/CNRS.

Published

2012

6. Global change and the functional diversity of cryptogams in northern biomes

Author

Lang, S.I., Cornelissen, JHC, Aerts, Rien, and Systems Ecology

Published

2011

7. Strong microsite control of seedling recruitment in tundra.

Author

Graae, B.J., Ejrnaes, R., Lang, S.I., Meineri, E., Ibarra, P.T., Bruun, H.H., Graae, B.J., Ejrnaes, R., Lang, S.I., Meineri, E., Ibarra, P.T., and Bruun, H.H.

Abstract

The inclusion of environmental variation in studies of recruitment is a prerequisite for realistic predictions of the responses of vegetation to a changing environment. We investigated how seedling recruitment is affected by seed availability and microsite quality along a steep environmental gradient in dry tundra. A survey of natural seed rain and seedling density in vegetation was combined with observations of the establishment of 14 species after sowing into intact or disturbed vegetation. Although seed rain density was closely correlated with natural seedling establishment, the experimental seed addition showed that the microsite environment was even more important. For all species, seedling emergence peaked at the productive end of the gradient, irrespective of the adult niches realized. Disturbance promoted recruitment at all positions along the environmental gradient, not just at high productivity. Early seedling emergence constituted the main temporal bottleneck in recruitment for all species. Surprisingly, winter mortality was highest at what appeared to be the most benign end of the gradient. The results highlight that seedling recruitment patterns are largely determined by the earliest stages in seedling emergence, which again are closely linked to microsite quality. A fuller understanding of microsite effects on recruitment with implications for plant community assembly and vegetation change is provided. © 2010 The Author(s).

Published

2011

8. Amino acid uptake among wide-ranging moss species may contribute to their strong position in higher-latitude ecosystems.

Author

Krab, E.J., Cornelissen, J.H.C., Lang, S.I., van Logtestijn, R.S.P, Krab, E.J., Cornelissen, J.H.C., Lang, S.I., and van Logtestijn, R.S.P

Abstract

Plants that can take up amino acids directly from the soil solution may have a competitive advantage in ecosystems where inorganic nitrogen sources are scarce. We hypothesized that diverse mosses in cold, N-stressed ecosystems share this ability. We experimentally tested 11 sub-arctic Swedish moss species of wide-ranging taxa and growth form for their ability to take up double labelled (

Published

2008