Abstract
The research activities on soil–freshwaterinteractions and freshwater biotic structure andprocesses in the Høylandet area during the years 1986–89are presented in this issue ofHydrobiologia. The 9 papers cover a range of topicsfrom physiochemical gradients and processes in soilsand freshwaters to selected aspects of freshwaterbiotic community structure and temporal variability.This synopsis aims (a) to present an overview of majorfindings, (b) to interpret the results in the contextof air pollution effects and (c) to outlinesuggestions for future research activities inHøylandet. The area has a sub-oceanic climate varyingfrom 1100 to 2200 mm of precipitation normallyoriginating from unpolluted airmasses from the NorthAtlantic. It is chemically dominated by sea salts, haslow concentrations and low deposition of mineralacids. The catchment geology is variable and complexand consists mainly of various granites and gneisses.The soils are undisturbed ’ancient‘ soils,primarily iron podzols associated with forests, orintact histosols with strong organic characterassociated with mires, often quite acidic.They are sensitive because occurrence of predominantlyinsoluble unstable Al-complexes may leach out ifexposed to anthropogenically acidified soil drainagewater and turn up as toxic inorganic aqueous Al insurface runoff. Small amounts of locally generatednitrogen compounds are mostly retained in thecatchment. The water qualities of these Høylandetsites are run by inputs of sea salts, hydrologicalprocesses including dilution of the base flow, orlateral surface or overland flow and in-catchmentprocesses. Relative to affected areas, it appears thatthe inputs and catchment processes are in balance,i.e., that the inputs of strong acid anions, hydrogenions and sea salts are equilibrated by internalweathering and other processes and integrated withinapparently intact biogeochemical cycles. The overallresult is that these soils remain a net source ofalkalinity to the runoff. These results are confirmedby regional studies of water quality both at low andhigh flow which show that the humus and ionic contentof the water decreased with elevation, headwatersbeing more dominated by sea salts and dilutionprocesses. Excess sulphate concentrations are low, andfew if any sites appear anthropogenically acidified,the most acid pH‘s reflecting presence of natural weakorganic acids.
The resulting surface water quality allows a diverseaquatic fauna and flora with representatives of manyacid-sensitive groups. The fish fauna consists ofself-reproducing salmonid populations with normaldemography and ecological interactions. Despite highin-lake mortality, both brown trout and Arctic charrexhibited normal age-class compositions, with noindication of the recruitment failure or highpost-spawning mortality commonly observed inacid-stressed situations. The zooplankton and benthos in the lakesare inhabited by populations of several acid sensitivespecies, like Daphnia spp and Gammaruslacustris, and with dominance of mayfly species ofthe genus Baetis in the stream fauna. Thediatom flora includes many species which are rare orabsent in acidified waters. The observed gradients indiversity and biomass seem dominated by localenvironmental conditions which reflect natural ratherthan man-made processes. The pristine nature of thearea also emerges from the paleoecological studies inLake Røyrtjønna which show that the low acidity ofthis lake evironment has persisted from preindustrialtill present times. Suggestion for future researchactivities in Høylandet are outlined.
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References
Aagaard, K. & D. Dolmen (eds), 1996. Limnofauna norvegica. Katalog over norsk ferskvannsfauna (Catalogue of Norwegian Freshwater Fauna). Tapir Forlag (publisher), Trondheim, 310 pp.
Aagard, K., J. O. Solem, T. Nøst & O. Hanssen, 1997. The macrobenthos of the pristine stream, Skiftesiaåa, Høylandet, Norway. Hydrobiologia 348: 81–94.
Aiken, G. R., D. M. McKnight, R. L. Wershaw & P. MacCarthy (eds), 1985. Humic substances in Soil, Sediment andWater. John Wiley and Sons, New York, 692 pp.
Almer, B., W. Dickson, C. Ekstrøm & E. Hörnström, 1974. Effects of acidification on Swedish lakes. Ambio 3: 30–36.
Andersen, R., I. P. Muniz & J. Skurdal, 1984. Effects of acidification on age class composition in Arctic char (Salvelinus alpinus (L.)) and brown trout (Salmo trutta L.). Rep. Inst. Freshwat. Res. Drottningholm 61: 5–15.
Anderson, H. A. (ed.), 1991. Geosphere-Biosphere Observatories: Interactions Between Soils, Biota and Waters in Pristine Ecosystems at Hoylandet, Mid-Norway. A joint multiinstitutional project description. Macauley Land Use Research Institute, Aberdeen, Scotland, 25 pp.
Anderson, H. A., J. D. Miller, R. C. Ferrier, T. A. Bruce Walker, D. C. Bain, R. G. McMahon, A. Hepburn, M. Stewart, B. F. L. Smith & J. S. Anderson, 1997. The effects of boreal vegetation and podzolic soils on hydrochemistry at Høylandet (mid-Norway). Hydrobiologia 348: 5–17.
Aune, E. I., E. Dahl & A-K. Løes, 1997. Soils and vegetation of bilberry-rich spruce forests in Høylandet with a comparison with similar sites but with heavier pollution loads in South Norway and in Schwarzwald, Germany. NINA Fagrapport (in press).
R. W. Battarbee, R. J. Flower, S. Juggins, S. T. Patrick & A. C. Stevenson, 1997. The relationship between diatoms and surface water quality in the Høylandet area of Nord-Trøndelag, Norway. Hydrobiologia 348: 69–80.
Berge, F., Y-W. Brodin, G. Cronberg, F. El-Daoushy, H. I. Høeg, J. P. Nilssen, I Renberg, B. Rippey, S. Sandøy, A. Timberlid & M. Wik, 1990. Paleolimnological changes related to acid deposition and landuse in the catchments of two Norwegian soft-water lakes. Phil. Trans. r. Soc. Lond. B 327: 385–389.
Blakar, I. A. & D. Hongve, 1997. On the chemical water quality in Høylandet, a reference area for acidification research?. Hydrobiologia 348: 39–47.
Borg, H., 1986. Metal speciation in acidified mountain streams in central Sweden. Wat. Air Soil Pollut. 30: 100–112.
Christophersen, N., C. Neal, R. D. Vogt, J. M. Esser & S. Andersen, 1990. Aluminum mobilization in soil and stream waters at three Norwegian catchments with different acid deposition and site characteristics. Sci. Total Envir. 96: 175–188.
Cronberg, G., 1990. Recent acidification and changes in the subfossile chrysophyte flora of lakes in Sweden, Norway and Scotland. Phil. Trans. r. Soc. Lond. B 327: 289–293.
Dahl, E., 1997. TheHøylandet Project–Introduction. Hydrobiologia 348: 1–3.
FitzPatrick, E. A., 1983. Soils: their formation, classification and distribution. Longman, London, 353 pp.
Framstad, E. & J. I. Holten (eds), 1997. Status of the Høylandet Reference Area–terrestrial studies. NINA Fagrapport (in press).
Greve, L. & J. O. Solem, 1990. Notes on the genus Diastatain Norway (Diptera, Diastatidae. Fauna norv. Ser. B, 37: 33–35.
Henriksen, A., 1980. Acidification of freshwaters–a large scale titration. In: D. Drabløs and A. Tollan (eds), Ecol. Impacts Acid Precip., SNSF project: 68–74.
Hesthagen, T., B. Jonsson, O. Ugedal & T. Forseth, 1997. Habitat use and life history of brown trout (Salmo truttaL.) and Arctic charr (Salvelinus alpinus(L.)) in some low acidity lakes in central Norway. Hydrobiologia 348: 113–126.
Holten, J. I., I. Brattbakk, A. A. Frisvold & B. Wilman, 1997. Gradient structure and soil chemistry of coniferous forests in Høylandet, Central Norway. NINA Fagrapport (in press).
Jensen, J. W., 1988. Crustacean plankton and fish during the first decade of a subalpine, man-made reservoir. Nordic J. Freshwat. Res. 64: 5–53.
Jensen, J. W., T. Nøst & I. P. Muniz, 1997. The ecology of brown trout and Arctic charr in two lakes in Høylandet. Hydrobiologia 348: 127–143.
Krug, E. C. & C. R. Frink, 1983. Acid rain and acid soil: A new perspective. Science 221: 520–525.
Larsson, P., 1978. The life cycle dynamics and production of zooplankton in Øvre Heimdalsvatn. Holarct. Ecol. 1: 162–218.
Likens, G. E. & F. H. Bormann, 1995. Biogeochemistry of a forested ecosystem.(2nd edn). Springer Verlag, New York.
Mulder, J., M. Pijpers & N. Christophersen, 1995. Water flow paths and the spatial distribution of soils as a key to understanding differences in stream water chemistry between three catchments (Norway). Wat. Air Soil Pollut. 81: 76–91.
Muniz, I. P., 1991. Freshwater acidification: its effects on species and communities of freshwater microbes, plants and animals. Proc. r. Soc. Edinburgh 97B: 227–254.
Nilssen, J. P. & S. Sandøy, 1990. Recent lake acidification and cladoceran dynamics: surface sediment and core analyses in lakes from Norway Scotland and Sweden. Phil. Trans. r. Soc. Lond. B 327: 299–309.
Nilsson, J. & P.-I. Grennfelt (eds), 1988. Critical Loads for Sulphur and Nitrogen. Nordic Council of Ministers. Miljørapport 1988: 15, 418 pp.
Nøst, T. & J. W. Jensen, 1997. Crustacean plankton in Høylandet. Hydrobiologia, 348: 95–111.
Økland, K. A. & J. Økland, 1985. Factor interaction influencing the distribution of the freshwater ‘shrimp’ Gammarus. Oecologia 66: 364–367.
Raddum, G. G. & A. Fjellheim, 1984. Acidification and early warning organisms in freshwater in western Norway. Verh. int. Ver. Theor. Angew. Limnol. 22: 1973–1980.
Rapp, C. & G. Jentschke, 1994. Effects of Acid Rain on Forest Processes. In D. G. Goldbold & A. Hüttemann (eds), Wiley-Liss Inc.: 183–230.
Rippey, B., 1990. Sediment chemistry and atmospheric contamination. Phil. Trans. r. Soc. Lond. B 327: 311–317.
Schindler, D. W., 1988. Experimental studies of chemical stressors on whole lake ecosystems. Ver. int. Ver. Limnol. 23: 11–41.
Schindler, D.W., K. G. Beaty, E. J. Free, E. R. DeBruyn, D. L. Findlay, J. A. Shearer, M. P. Stainton & M. A. Turner, 1990. Effects of climatic warming on lakes of the Central Boreal Forest. Science 250: 967–969.
Schindler, D.W., T. M. Frost, K.H. Mills, P. S. S. Chang, I. J. Davies, D. L. Findlay, D. F. Malley, J. A. Shearer, M. A. Turner, P. J. Garrison, C. J. Watras, K. Webster, J. M. Gunn, P. L. Brezonik & W. A. Swenson, 1991. Comparisons between experimentallyand atmospherically-acidified lakes during stress and reccovery. Proc. r. Soc. Edinburgh 97B: 193–226.
Schnell, Ø. A., 1991. New records of Chironomidae (Diptera) from Norway (II) with two new species synonyms. Fauna norv. Ser. B 38: 5–10.
Solem, J. O., H. Kauri & P. Straumfors, 1990. Tabanidae (Diptera) community in a very little exploited northern boreal forest at Høylandet, N. Trøndelag, Norway. Fauna norv. Ser. B 37: 63–66.
Solem, J. O. & H. Mendl, 1989. Limoniidae communities in alpine and boreal zones along the Atna River, South Norway (Diptera, Nematocera). Fauna norv. Ser. B 36: 107–114.
Sullivan, T. J., N. Christophersen, I. P. Muniz, H. M. Seip & P.D. Sullivan, 1986. Aqueous aluminium chemistry response to episodic increases in discharge. Nature 323: 324–327.
Sæther, O. A., 1990. A review of the genus Limnophyes Eaton from the Holarctic and Afrotrophical regions (Diptera: Chironomidae, Orthocladiinae). Ent. Scand. Suppl. No. 35, 135 pp.
Vogt, R. D. & I. P. Muniz, 1997. Soil and stream water chemistry in a pristine and boggy site in mid-Norway. Hydrobiologia 348: 19–38.
Wik, M. & J. Natkanski, 1990. British and Scandinavian lake sediment records of carbonaceous particles from Fossile-fuel combustion. Phil. Trans. r. Soc. Lond. B 327: 319–323.
Wolters, V. & R. G. Jorgensen, 1991. Microbial carbon turnover in beech forest soils at different stages of acidification. Soil. Biol. Biochem. 23: 897–902.
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Muniz, I.P. The Høylandet area – patterns and processes of a pristine boreal-subalpine ecosystem – a synopsis. Hydrobiologia 348, 145–154 (1997). https://doi.org/10.1023/A:1003097419358
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DOI: https://doi.org/10.1023/A:1003097419358