A common soil temperature threshold for the upper limit of alpine grasslands in European mountains

Bürli, Sarah; Theurillat, Jean‐Paul; Winkler, Manuela; Lamprecht, Andrea; Pauli, Harald; Rixen, Christian; Steinbauer, Klaus; Wipf, Sonja; Abdaladze, Otar; Andrews, Chris; Barančok, Peter; Alonso, José Luis Benito; Calzado, María Rosa Fernández; Carranza, María Laura; Dick, Jan; Erschbamer, Brigitta; Ghosn, Dany; Gigauri, Khatuna; Kazakis, George; Mallaun, Martin; Michelsen, Ottar; Moiseev, Dmitry; Moiseev, Pavel; Molau, Ulf; Mesa, Joaquı́n Molero; Cella, Umberto Morra di; Nadeem, Imran; Nagy, László; Nicklas, Lena; Palaj, Andrej; Pedersen, Bård; Petey, Martina; Pușcaș, Mihai; Rossi, Graziano; Stanisci, Angela; Tomaselli, Marcello; Unterluggauer, Peter; Ursu, Tudor‐Mihai; Villar, Luis; Vittoz, Pascal

doi:10.1007/s00035-021-00250-1

Cited by 17 publications

(13 citation statements)

References 54 publications

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“…Therefore, the hypothesis (1a) that vascular plant cover and litter should prevail on siliceous bedrock, whereas bare ground, scree, and rock should dominate on calcareous bedrock could only be partially confirmed. Independently of bedrock, mean vascular plant cover decreased strongly along the elevation gradient and thus, is strongly related to the adiabatic temperature gradient (Bürli et al, 2021). Also, the proportion of scree and rock was independent of bedrock types.…”

Section: Bedrock Specific Surface Cover Characteristics and Changes Over Timementioning

confidence: 92%

Climate Change Affects Vegetation Differently on Siliceous and Calcareous Summits of the European Alps

et al. 2021

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The alpine life zone is expected to undergo major changes with ongoing climate change. While an increase of plant species richness on mountain summits has generally been found, competitive displacement may result in the long term. Here, we explore how species richness and surface cover types (vascular plants, litter, bare ground, scree and rock) changed over time on different bedrocks on summits of the European Alps. We focus on how species richness and turnover (new and lost species) depended on the density of existing vegetation, namely vascular plant cover. We analyzed permanent plots (1 m × 1 m) in each cardinal direction on 24 summits (24 × 4 × 4), with always four summits distributed along elevation gradients in each of six regions (three siliceous, three calcareous) across the European Alps. Mean summer temperatures derived from downscaled climate data increased synchronously over the past 30 years in all six regions. During the investigated 14 years, vascular plant cover decreased on siliceous bedrock, coupled with an increase in litter, and it marginally increased on higher calcareous summits. Species richness showed a unimodal relationship with vascular plant cover. Richness increased over time on siliceous bedrock but slightly decreased on calcareous bedrock due to losses in plots with high plant cover. Our analyses suggest contrasting and complex processes on siliceous versus calcareous summits in the European Alps. The unimodal richness-cover relationship and species losses at high plant cover suggest competition as a driver for vegetation change on alpine summits.

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Section: Bedrock Specific Surface Cover Characteristics and Changes Over Timementioning

confidence: 92%

Climate Change Affects Vegetation Differently on Siliceous and Calcareous Summits of the European Alps

et al. 2021

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“…Grabherr et al (1995) present not only elevational limits of plants in tropical, subtropical, and temperate mountains in East Africa, South America, and Europe but also the upper limits of continuous vegetation. In Table 4, I summarise information of the highest elevation (HE) of the mountains considered in Table 3, along with the highest known elevational limits of vascular plants (PL) on mountains in the major mountain regions within the tropical, subtropical, and temperate zones, as well as the potential climatic treeline (TL; based on Körner 2007, 2012, Paulsen and Körner 2014, the highest elevation when closed vegetation (VL) ('grassline' of Bürli et al 2021) occurs, and the ratios of PL/TL, PL/HE, and PL/VL. The data sources used in Table 4 include Grabherr et al (1995), Körner (2003Körner ( , 2012, publications cited earlier for the basic upper-elevation limits for vascular plants in particular mountain regions, and my own field observations, particularly for the closed vegetation limit (≥40% vascular-plant cover).…”

Section: Upper-elevation Limitsmentioning

confidence: 99%

High-elevation limits and the ecology of high-elevation vascular plants: legacies from Alexander von Humboldt

Birks¹

2021

Frontiers of Biogeography

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Highlights• The known uppermost elevation limits of vascular plants in 22 regions from northernmost Greenland to Antarctica through the European Alps, North American Rockies, Andes, East and southern Africa, and South Island, New Zealand are collated to provide a global view of high-elevation limits.• The relationships between potential climatic treeline, upper limit of closed vegetation in tropical (Andes,

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“…As already mentioned, this estimation does not account for effects of soil development and altered moisture availability. It had been proposed that there is an alpine grassline in analogy to alpine treeline, meaning that connecting the position of patches of closed, very high elevation grassland communities also follows a common isotherm [42]. Since such grassland fragments are tied to stable substrate and certain topographic niches, they are unlikely to shift upslope, but are likely to retain their position, given they are currently representing the cold range limit of this type of alpine vegetation with a substantial leeway towards warmer conditions.…”

Section: Figurementioning

confidence: 99%

Why Is the Alpine Flora Comparatively Robust against Climatic Warming?

Körner

Hiltbrunner

2021

Diversity

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The alpine belt hosts the treeless vegetation above the high elevation climatic treeline. The way alpine plants manage to thrive in a climate that prevents tree growth is through small stature, apt seasonal development, and ‘managing’ the microclimate near the ground surface. Nested in a mosaic of micro-environmental conditions, these plants are in a unique position by a close-by neighborhood of strongly diverging microhabitats. The range of adjacent thermal niches that the alpine environment provides is exceeding the worst climate warming scenarios. The provided mountains are high and large enough, these are conditions that cause alpine plant species diversity to be robust against climatic change. However, the areal extent of certain habitat types will shrink as isotherms move upslope, with the potential areal loss by the advance of the treeline by far outranging the gain in new land by glacier retreat globally.

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A common soil temperature threshold for the upper limit of alpine grasslands in European mountains

Cited by 17 publications

References 54 publications

Climate Change Affects Vegetation Differently on Siliceous and Calcareous Summits of the European Alps

Climate Change Affects Vegetation Differently on Siliceous and Calcareous Summits of the European Alps

High-elevation limits and the ecology of high-elevation vascular plants: legacies from Alexander von Humboldt

Why Is the Alpine Flora Comparatively Robust against Climatic Warming?

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