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1.3.3 Nutrient input

In nutrient enriched areas, organic soils of over 10 cm depth may accumulate, illustrating the impact of nutrient flow from the marine environment to the often nutrient limited terrestrial habitat (Odasz, 1994).  

Bird cliff meadows are luxuriant communities developing in drier areas under bird cliffs, as seabirds may introduce large amounts of marine‐derived nutrients to land in their breeding locations. The guano is rich in nitrogen, phosphorus, and other elements, which strongly fertilize these areas and influence the spatial distribution of plants along nutrient gradients. The nutrient concentration very close to the cliff can be so high that it is toxic, and no vascular plants are growing there. 

Furthermore, this nutrient transport leads to increased vegetation productivity and biomass, which attract herbivores and subsequently transfer of marine‐derived nutrients to higher trophic levels, and at last to decomposition, releasing nutrients back to soil and partially brought back into the sea through run-offs. Some nutrients are also transferred to other terrestrial locations by herbivores. 

There are three main types of bird cliffs: 

1. Pure cliffs 

  • Steep cliffs directly from the sea 
  • Vegetation on narrow ledges not used as bird nesting sites, lichens (Rusavskia elegans, syn. Xantoria elegans) on cliff walls. 
  • Mainly Brünnich’s guillemots and kittiwakes 

2. Combined cliff and talus 

  • Little auk and puffins in addition 
  • Steep nutrient gradients from nesting area to the sea 

3. Pure talus 

  • Little auks, puffins 
  • Influence of nutrients more evenly distributed. 
In nutrient enriched areas, organic soils of over 10 cm depth may accumulate, illustrating the impact of nutrient flow from the marine environment to the often nutrient limited terrestrial habitat (Odasz, 1994). Reworked after illustration in "The Sage Handbook of Biogeography" ed. Millington et al. (2011)

Shape and steepness of the bird cliff influence both bird communities and nutrient gradients (pure cliffs will not show a continuous gradient, put have patches of enriched soils and local gradients). 

The nutrient enrichment of soil also differs depending on preferred diet: e.g. Little auks have zooplankton as their main food source (planktivorous), and studies by Zwolicki et al. (2013; 2016) suggests that their diet influence soil chemistry, and thus vegetation, differently than fish-eating seabirds like kittiwakes (piscivores). Phosphate content and pH were significantly higher in soil influenced by piscivores, and with higher dominance of Cochlearia groenlandica close to the bird cliff. The well-developed meadows in drier parts of the bird cliff are dominated by various grasses, like Alopecurus ovatus, and species of Poa and Festuca. Other herbs commonly found in bird manured areas are Micranthes hieracifolia, Saxifraga cespitosa, S. cernua, Chrysosplenium tetrandrum, Oxyria digyna, and Polemonium boreale (Eurola & Hakkala, 1977; Elvebakk, 1994).

In bird cliffs with taluses, in particular those flatting out, moss tundra will be dominant. Moss tundra is dominated by graminoids or herbs growing in a thick moss carpet, and formed under influence of fertilization in moist slopes and concave terrain forms. A talus slope can be well drained topographically, but in a bird cliff it receives intensive input of organic matter falling from the cliffs. Over time it will fill up with organic material. As mosses are the first to establish, and thus act as the parent material of the surface soil on bird-affected taluses, this soil develops high water retention capacity. The wet moss carpet holds the soil cool, and reduce the active layer depth. This again slow down decomposition, further building up organic material and affect nutrient cycling (Gornall et al., 2007, Hayashi et al., 2018).

Lush Oxyrya growing where it is too steep for reindeers
Arctic skua build watch towers through nutrient input

Elvebakk, A. (1994). A survey of plant associations and alliances from Svalbard. J. Veg. Sci. 5, 791–802. doi: 10.2307/3236194

Eurola, S., and A.V.K. Hakala. 1977. The bird cliff vegetation of Svalbard. Aquilo/Seria botanica 15: 1–18.

Gornall JL, Jónsdóttir IS, Woodin SJ & Van der Wal R (2007) Arctic mosses govern below-ground environment and ecosystem processes. Oecologia 153: 931-941.

Hayashi K, Tanabe Y, Ono K, Loonen MJJE, Asano M, Fujitani H, Tokida T, Uchida M & Hayatsu M (2018) Seabird-affected taluses are denitrification hotspots and potential N2O emitters in the High Arctic. Scientific Reports 8: 17261.

Odasz, A.M. (1994). Nitrate reductase activity in vegetation below an Arctic bird cliff, Svalbard, Norway. Journal of Vegetation Science5(6), 913-920. https://doi.org/10.2307/3236203The SAGE Handbook of Biogeography – Edited by A. Millington, M. Blumler and U. Schickoff. 2011

Zwolicki, A., Zmudczyńska-Skarbek, K. M., Iliszko, L., and Stempniewicz, L. (2013). Guano deposition and nutrient enrichment in the vicinity of planktivorous and piscivorous seabird colonies in Spitsbergen. Polar Biol. 36, 363–372. doi: 10.1007/s00300-012-1265-5

Zwolicki A, Zmudczyńska-Skarbek K, Matuła J, Wojtuń B and Stempniewicz L (2016) Differential Responses of Arctic Vegetation to Nutrient Enrichment Plankton and Fish-Eating Colonial Seabirds in Spitsbergen. Front. Plant Sci. 7:1959. doi: 10.3389/fpls.2016.01959