importance of different factors in determining herbivore range use. Forage preferences Once a predictive understanding of when the animals are likely to actually visit a particular area is gained, it is at this second level that an understanding of diet choice is fundamental. This con- cerns not only the relative prefer- ences for different tree species by different herbivores, but also the range of other factors which affect these preferences, such as surrounding vegetation and time of year. Preferences for different tree species have been relatively widely studied in a range of countries (e.g. Mitchell, Staines & Welch 1977; Van Hees., Kuiters & Slim 1996), resulting in a rea- sonable consensus as to which tree species are most preferred by large herbivores - examples of more preferred species are Salix spp, Sorbus aucuparia, Populus trem- ula, and examples of less pre- ferred species are Pinus sylvestris, luniperus communis, Picea spp. This is an important issue for a land manager who wishes to encour- age regeneration of particular tree species. Forexample, Pinus sylvestris is likely to regenerate at higher deer densities than Salix spp, and there are good examples of this pattern in some of the Scottish estates which have been reducing deer numbers to allow forest regeneration (Beaumont et al. 1994). It is also well estab- lished that, within a species, some individual saplings are more preferred than others, for a range of reasons such as mor- phology, visibility and chemical content (Mitchell etal. 1977; Danell etal. 1991; Edenius et al. 1995). However, both the above factors are strongly influenced by surrounding vegetation; itaffects food choice, sapling visibility and accessibility. Finally, time of year also interacts with all the above; many factors change through the year to alter herbivore forage choice, such as biomass and digestibility of other forage, and visibility of the saplings them- selves. To summarise, a range of fac- tors interact even at the level of forage preferences to determine choice of diet. The crucial issue for designing robust manage- ment options is to understand and be able to predict how, when and why these factors might interact. Sapling responses to damage At the smallest scale, factors affecting sapling responses to damage are very similar: different species respond differently to damage, and the response also depends on the age and size of the sapling; younger, smaller saplings are generally more badly affected by browsing dam- age (Chapin et al. 1995). To give an example, Pinus sylvestris is gen- erally one of the less preferred species of browse, but it is also one of the least tolerant of dam- age (Miiler et al. 1982; Millard & Hester in press). Even if it is less heavily browsed than a species such as Sorbus aucuparia, which is very tolerant of damage (Miller et ai. 1982; Millard & Hester in press), it may still be more badly affected. Therefore browsing preferences for different tree species need to be considered along with sapling tolerance. Timing and severity of damage are also fundamentally important and their effects also vary between different tree species (Danelletal. 1994, Hester et al. 1996). Furthermore, as with for- age preferences, surrounding vegetation, as well as soils, affect competition and resource avail- ability, which may all influence a sapling’s ability to regrow after damage (Hester et al. 1996). Therefore, as with foraging preferences, a complex of factors all interact at the sapling level, and all need to be understood to some degree to be able to make reliable predictions about brows- ing impacts on saplings under different conditions. Integration Most research to date has focused on particular questions or small groups of questions, usually within only one of the three main approaches described above. Such types of studies are continuing in many different countries, often in isolation rather than as part of a larger integrated programme. Thus, 1 suggest that the most pressing need at present is to move towards much greater integration of such work at a whole range of scales; from the landscape, where a large number of interact- ing factors require to be studied, down to the individual plant where highly controlled experi- ments can be carried out. Research at the landscape level (e.g. Fig 1) has the advan- tage of describing 'reality'; but the disadvantage is the huge variability and the difficulty of isolating which factors or combi- nations of factors have caused the results measured (e.g. Beaumont et al. 1994). Using only this approach can lead to misleading conclusions. It can be combined with research at medi- um geographical scales (ha - km), using semi-controlled experiments, for example, where large replicate experimental plots are set up within a natural- ly variable landscape, with a range of factors varied explicitly (such as herbivore density, tim- ing of grazing, different sapling species) to examine their influ- SKÓGRÆKTARRITIÐ 2001 l.tbl. 101

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