Abstract
AimsThe retreat of glaciers is exposing new terrains to primary plant succession around the globe. To improve the understanding of vegetation development along a glacier retreat chronosequence, we (i) evaluated a possible link between base metal (Ca, Mg, K, Na) supply and vegetation establishment, (ii) determined the rates of the establishment of soil and plant base metal stocks, and (iii) estimated the size of the main base metal fluxes.MethodsWe determined base metal stocks in the soil organic layer, the mineral topsoil (0–10 cm), and in leaves/needles, trunk, bark, branches and roots of the dominating shrub and tree species and estimated fluxes of atmospheric deposition, plant uptake and leaching losses along the 127-yr Hailuogou chronosequence.ResultsTotal ecosystem Ca and Mg stocks decreased along the chronosequence, while those of K and Na were unrelated with ecosystem age. Fortyfour and 30% of the initial stocks of Ca and Mg, respectively, were leached during the first 47 years, at rates of 130 ± 10.6 g m−2 year−1 Ca and 35 ± 3.1 g m−2 year−1 Mg. The organic layer accumulated at a mean rate of 288 g m−2 year−1 providing a bioavailable base metal stock, which was especially important for K cycling.ConclusionsWe suggest that the initial high Ca bioavailability because of a moderately alkaline soil pH and carbonate depletion in 47 years, together with the dissolution of easily-weatherable silicates providing enough Mg and K to the pioneer vegetation, contributed to the establishment of the mature forest in ca. 80 years.
Highlights
The worldwide increasing temperatures since the end of the Little Ice Age (LIA; IPCC 2021) have resulted in the retreat of high mountain glaciers in polar (Kabala and Zapart 2012; Moreau et al 2008;1 3 Vol.:(0123456789)Wietrzyk et al 2018) and tropical regions (Cullen et al 2013; Seehaus et al 2019)
The organic layer accumulated at a mean rate of 288 g m−2 year−1 providing a bioavailable base metal stock, which was especially important for K cycling
The development from bare soil to mature forest in < 80 years along the 127-year old Hailuogou glacier retreat chronosequence was linked with a strong soil acidification and an intense loss of carbonates in the first 47 years of vegetation succession
Summary
The worldwide increasing temperatures since the end of the Little Ice Age (LIA; IPCC 2021) have resulted in the retreat of high mountain glaciers in polar (Kabala and Zapart 2012; Moreau et al 2008;1 3 Vol.:(0123456789)Wietrzyk et al 2018) and tropical regions (Cullen et al 2013; Seehaus et al 2019). The worldwide increasing temperatures since the end of the Little Ice Age (LIA; IPCC 2021) have resulted in the retreat of high mountain glaciers in polar During the time between deposition of the glacial debris and establishment of a vegetation cover, there is an enhanced risk of natural hazards typical for mountain areas, such as landslides, debris flows, erosion, and flooding. Glacial retreat has accelerated during the second half of the twentieth century (Zemp et al 2008; Zhou et al 2013) and is expected to continue for global mountain systems during the twentyfirst century (Hock et al 2019; Nogués-Bravo et al 2007). The knowledge of the processes that drive vegetation succession is crucial to cope with the risks originating from the globally increasing glacier retreat areas
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