SKÓGRÆKT HANDAN SKÓGARMARKA / NSSE FRANS E. WIELGOLASKI Field- and bottom iayer vegeta- tion mat transplantation: A method to simulate possible effects of climate change? SAMANTEKT Þökum úr bláberjalyngsmóum var umplantað yfir í þurra fléttuheiði, en þökur úr henni voru færðar yfir í bláberjalyngsdæld 100-200 m í burtu. Breytingar á gróðrinum voru skoðaðar eftir mislangan tíma. Eftir 4 ár var minna en 20% af bláberjalynginu á lífi í fléttuheiðinni, en eftir 9 ár einungis 10%, og fimmtán árum eftir umplöntunina voru engir lifandi sprotar af bláberjalyngi eftir í hinni þurru fléttuheiði. Á runn- fléttunni Cetraria nivalis (maríugrös), sem venjulega vex á vindsorfnum hæðarbrúnum, gulnaði þalið hins vegar strax einu ári eftir umplöntun í votari bláberjalyngsdæld. Þekja maríugrasanna minnkaði niður í 3-4% eftir fjögur ár, og var einungis I % eftir níu ár, borið saman við þökur sem var umplantað innan sama svæðis. Breyting á þekju annarra tegunda við mismunandi umplöntun var einnig greinileg, en þó minni. Votara loftslag með meiri snjó- og íshulu og styttra vaxtartímabili getur haft svipuð áhrif og umplöntun á gróðurþökum úr þurri fléttu- heiði í bláberjalyngsdæld með lengri snjóþekju, líkt og kom fram með dauða maríugrasanna. Afturá móti geta loftslagsbreytingar sem valda minni snjóþekju, kaldari vetrum og meiri þurrki haft svipuð áhrif og sést á umplöntun bláberjalynggróðurs í þurra og opna fléttuheiði. The climatic growth conditions vary strongly over small distances in mountains. Particularly, this is true for the snow cover and the soil moisture. Therefore, it may be possible to simulate the effect of climatic changes by reciprocal transplantations of the vegetation between nearby sites of different soil moisture and snow cover. In most cases transplantation studies have been carried out on single plant specimens, although in some cases populations are studied (Clausen et al., 1948; Mooney and Billings, 1961; McGraw, 1987). The reason is that in most natural plant com- munities it is not possible to transplant the whole community because of the size of the plants both above and below ground. ln many types of arctic, alpine and sometimes subalpine plant com- munities, however, this might physically be done because of the small plants found in the field and bottom layer. As a working hypothesis in the present study it was expected that the species growing in a sheltered snow bed would be more strongly influenced by transplantation to a winter cold and summer dry wind exposed heath, than the species naturally growing at that community, when placed in a more sheltered and moister snow bed. It was also expected that the recovery would be slower in the more strongly stressed windswept heath than in the snow bed. Material and methods Vegetation mats of two types of low alpine plant communities at the mountain plateau Hardanger- vidda in southwestern Norway (latitude 60°N, elevation I200m a.s.l.) were chosen in the present study, but similar transplanta- tions could also been done in the subalpine mountain birch forest. One community was an olig- otrophic heath dominated by blueberries (a Phyllodoco-Vac- cinion myrtilli community), one of the most common communi- ties in the region. It is found where there is some snow protec- tion from the lowest winter tem- peratures and not too dry soil in the summer. On the other hand the vegetation period cannot be too short, which means that this type is missing also in extreme snow beds. The other community chosen was a typical oligotrophic lichen heath (an Arctostaphyleto- Cetrarion nivalis community), common at dry, wind swept, win- ter cold ridges. The two communities thus represent various climatic condi- tions, although the horizontal distance between them in the field was only l-200m. It was SKÓGRÆKTARRITIÐ 2001 1. tbl 167

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