Ann. Zool. Fennici 42: 277–282 ISSN 0003-455X Helsinki 28 June 2005 © Finnish Zoological and Botanical Publishing Board 2005 Red wood ant mound densities in managed boreal forests Timo Domisch1, Leena Finér1 & Martin F. Jurgensen2 1) Finnish Forest Research Institute, Joensuu Research Centre, P.O. Box 68, FI-80101 Joensuu, Finland (e-mails: timo.domisch@metla.fi, leena.finer@metla.fi) 2) School of Forest Resources and Environmental Science, Michigan Technological University, 1400 Townsend Drive, Houghton MI, 49931, USA (e-mail: mfjurgen@mtu.edu) Received 28 Oct. 2004, revised version received 20 Mar. 2005, accepted 22 Mar. 2005 Domisch, T., Finér, L. & Jurgensen, M. F. 2005: Red wood ant mound densities in managed boreal forests. — Ann. Zool. Fennici 42: 277–282. Clear-cutting can greatly impact red wood ant (Formica rufa group) colonies by changing microclimate, altering forage routes and eliminating aphid colonies as a food source. However, changed forestry practices in Finland, such as smaller clear-cut areas, leaving residual trees, and less intensive site preparation methods used during the last decade may result in less detrimental effects on red wood ants. Therefore, we studied how the number and size of red wood ant mounds varied between mature, 140-year-old, Norway spruce, Picea abies (L.) Karst., dominated mixed stands, and in 20-year-old and 5-year-old stands planted with Scots pine (Pinus sylvestris L.) in eastern Finland, all originating from similar mature forest stands. No red wood ant mounds were found in the 20-year-old Scots pine stands, which seems to be due to the cutting practices and heavy site preparation used at that time. The mound density in the 5-year-old stands (2.7 mounds per ha) was not different from that in the mature stands (2.9 mounds per ha), which could be a result of lighter harvesting and site prepara- tion practices. However, the mounds in the 5-year-old clear cut areas were smaller in volume and flatter in shape than those in the mature stands. This could be due to accelerated organic matter decomposition in the mounds after timber harvest, or large mounds may have split into smaller ones as a result of changed environmental or food supply conditions. However, five years after clear-cutting and site preparation could be too short a time period to observe the degeneration and eventual disappearance of the still existing red wood ant mounds. Introduction Red wood ants (RWA, Formica rufa group) are one of the dominant ecosystem elements in the boreal forests of Eurasia. In Finnish forests, ants are the dominant predators, scavengers and turn- ers of soil, and their biomass may comprise up to 10% or more of the animal biomass of that region (Hölldobler & Wilson 1990). RWAs influ- ence the forest food web due to their high abun- dance and diverse roles in the ecosystem (Laakso & Setälä 2000). The long-lived, robust colonies of RWAs accumulate tree litter (such as conifer- ous needles, twigs and bark), resin and insects 278 Domisch et al. • ANN. ZOOL. FENNICI Vol. 42 into their mounds (Wisniewski 1967, Maavara et al. 1994, Laakso & Setälä 1998). RWAs intensively use as a food source the honeydew excreted from aphids living on trees (Hölldobler & Wilson 1990), and the majority of their diet consists of honeydew (Wellenstein 1952, Rosen- gren & Sundström 1991). Decomposer microbes are more abundant inside their mounds as com- pared with the forest soil (Laakso & Setälä 1997, 1998). Extensive studies on RWAs have concentrated on their social structure (Gößwald 1989), geographical distribution and density (Sudd et al. 1977, Laine & Niemelä 1989), population dynamics and behaviour (Klimetzek 1981), effects on forest health (Finnegan 1976, Gößwald 1989), and biodiversity (Laakso & Setälä 2000). In the 1950s, an average RWA mound density of 3 ha–1 was found in the most common forest site types in southern Finland (Rosengren et al. 1979). These forest site types are dominated by conifers and are of medium fertility. Much lower mound densities (0.005–0.32 mounds per ha) were reported for Irish, French, German or Polish forests (Breen 1979, Klimetzek 1981, Szczepanski & Podkowka 1983, Travan 1990, Nageleisen 1999). Thus the role of RWAs can be more important in boreal forests than in the temperate forests of central Europe (e.g. France, Germany or Poland), where urbanisation, forest fragmentation, forest management, air pollution or pupae collection as food for cage birds or medical purposes may have led to lower mound densities. Since the 1950s urbanisation and forest man- agement have also intensified in Finland, and could have negative impacts on RWA popula- tions and community structure (Rosengren & Pamilo 1978, Vepsäläinen & Wuorenrinne 1978, Punttila et al. 1994). Clear-cutting is a common practice in Finland (approx. 150 000 ha a–1, Pel- tola 2003), and is harmful for RWAs by changing microclimate, altering forage routes and elimi- nating aphid colonies as a food source (Rosen- gren & Pamilo 1978, Rosengren et al. 1979, Punttila et al. 1991). Mechanical disturbance by forestry practices, such as harvesting and intensive site preparation, may also destroy RWA colonies. However, changed forestry practices in Finland, e.g. use of smaller clear-cut areas, leaving residual living trees and lighter site prep- aration methods used during the last decade can result in less detrimental effects on RWAs. Therefore, the objectives of our study were (1) to determine the density of RWA mounds in boreal coniferous forest stands of different age, and (2) to discuss the effect of clear-cutting and site preparation on RWA mound densities. Material and methods Study area We inventoried RWA mounds in a forest area of 82 ha in eastern Finland, which comprised of 15 forest stands, representing 3 different age classes: forest stands 5 and 20 years after clear-cutting, and mature, 140-year-old stands (Sotkamo com- mune, 63°51´N, 28°58´E, 220 m a.s.l.) (Table 1). All the clear-cut stands originated from similar Norway spruce dominated mature stands. The site type was classified as a medium rich Vac- cinium–Myrtillus type according to the Finnish Table 1. Description of the stands studied. Statistically significant different averages (p < 0.05) between the mature and 5-year-old stands are marked by different letters (a and b). 5-year-old stands 20-year-old stands Mature stands (~140 years) Dominant tree species Planted Scots pine Planted Scots pine Norway spruce Number of stands 4 3 8 Mean stand area (mean ± S.E.; ha) 5.0 ± 1.3 6.4 ± 3.1 5.4 ± 3.7a Site preparation Disk ploughing Deep ploughing – Active mound density (mean ± S.E.; ha–1) 02.6 ± 0.6a 0 2.9 ± 0.6a Abandoned mound density (mean ± S.E.; ha–1) 00.3 ± 0.1a 0 0.3 ± 0.2a Abandoned mounds (mean ± S.E.; %) 11.2 ± 4.0a 0 9.5 ± 6.2a ANN. ZOOL. FENNICI Vol. 42 • Ant mound densities in managed boreal forests 279 classification system (Cajander 1949). The soils were podzolic, developed on till material (Finér et al. 1997). The mature stands were dominated by Norway spruce (Picea abies L. Karst.), mixed with Scots pine (Pinus sylvestris L.) and white and silver birch (Betula pubescens Ehrh. and B. pendula Roth.). The 20-year-old stands were clear-cut in the early 1980s with the conven- tional “stem-only” method which removed all trees from the stand. Site preparation was done by deep ploughing and Scots pine seedlings were subsequently planted. The now 5-year-old stands were also clear-cut with the “stem-only” method in 1996, but some living and all dead trees were left uncut on the area. The site was prepared by disk ploughing in the autumn of 1998, and Scots pine seedlings were planted in the spring of 1999. The annual mean air temperature in the area was 1.8 °C, and the mean average annual precipitation was 700 mm. For more detailed descriptions of the study site see Finér et al. (1997, 2003). Field measurements All RWA mounds in the studied stands were inventoried in September 2001 by measuring their top height and base diameter (north–south and east–west), and categorising them as either active or abandoned. The ant species were not determined, but they were likely to be Formica aquilonia Först. or F. polyctena Yarr. (Baroni Urbani & Collingwood 1977, Rosengren et al. 1979). Calculations and statistical tests The above-ground volume of the ant mounds was calculated using the formula for an ellipsoid, and the base area of each mound was calculated using the formula for an ellipse. North–south and east–west diameters were averaged for statistical testing of the diameter. The physical proper- ties of the ant mounds, diameter, height and volume were tested with ANOVA (SPSS 12.0.1) with age class (5-year-old and mature stands) as a grouping variable. Levene’s test indicated similar variances between groups. All data were subjected to a logarithmic transformation before statistical analysis. Results No RWA mounds were found in the 20-year- old Scots pine stands, while the mound density between the mature forest and the 5-year-old stands was not significantly different (Table 1, df = 1, F = 0.016, p = 0.901). The mounds in the 5- year-old stands were smaller (df = 1, F = 7.68, p = 0.020) and flatter (df = 1, F = 10.38, p = 0.009) than those in the mature ones (Table 2), although their diameter did not differ (df = 1, F = 3.75, p = 0.082). The smallest volume class (< 0.25 m3) had the highest frequency in the 5-year-old stands, whereas mound size in the mature stands showed a more normal distribution (Fig. 1). The mounds covered 4.0 m2 per ha both in the mature and the 5-year-old stands, which was only 0.04% of the total area. There was no difference in the Table 2. Physical characteristics (mean ± S.E.) of active RWA mounds in the mature Norway spruce stands (n = 8) and the 5-year-old Scots pine stands (n = 4). Statistically significant different averages (p < 0.05) between the mature and the 5-year-old stands are marked by different letters (a and b). 5-year-old stands Mature stands Diameter (m) 1.13 ± 0.12a 1.45 ± 0.16a Height (m) 0.47 ± 0.05a 0.77 ± 0.05b Volume (m3) 0.68 ± 0.13a 1.23 ± 0.19b Base area (m2) 1.26 ± 0.28a 1.83 ± 0.42a Fig. 1. Relative volume distribution of active RWA mounds in different volume classes in the mature and in 5-year-old forest stands. 280 Domisch et al. • ANN. ZOOL. FENNICI Vol. 42 functioning (active or abandoned) of mounds between the mature and the 5-year-old stands (df = 1, F = 1.008, p = 0.339). Discussion The RWA mound density in the mature and 5- year-old stands was consistent with that found in other studies carried out in Finland. Using the National Forest Inventory data collected during the early 1950s, Rosengren et al. (1979) reported an average density of three RWA mounds per ha in the most common forest type (Myrtillus type). Similar mound densities have been reported for planted coniferous forest stands in northern Eng- land (Sudd et al. 1977), while studies conducted in Ireland, Germany and Poland found much lower mound densities (Breen 1979, Klimetzek 1981, Szczepanski & Podkowka 1983, Travan 1990). However, these studies reported mound densities for large forest areas (hundreds or thousands of hectares), and were not grouped by forest-site types or compartments, as were those of Sudd et al. (1977) and Rosengren et al. (1979). If the Finnish data from the 1950s were reported for the total forest area of south- ern Finland, the RWA mound density would be 1.2 mounds ha–1 (Wuorenrinne 1975), which is still considerably higher than the densities found in Ireland or Germany. Reasons for the low RWA mound densities in central Europe could be combinations of forest fragmentation, nest destruction (e.g. Gößwald 1971), recrea- tional pressure (e.g. Nageleisen 1999) or air pollution and heavy metal deposition (Migula & Głowacka 1996, Rabitsch 1997). Another reason for the low mound densities in Germany could be collection of ant pupae as food for cage birds or for medical purposes, thus reducing the vital- ity of RWA colonies (Gößwald 1944, Wuoren- rinne 1978). No RWA mounds were found in the 20-year- old Scots pine stands. The mounds originally present on these sites may have been destroyed by clear-cutting and site preparation (plough- ing) used when these stands were regenerated. Clear-cutting is known to have detrimental effects on RWA colonies, as foraging distances become longer or change (Rosengren & Pamilo 1978), and aphid colonies disappear (Rosen- gren & Pamilo 1978, Rosengren et al. 1979). Scots pine seedlings were also planted, and the changed stand composition from Norway spruce dominance to Scots pine dominance could have affected ant colony vitality, since RWAs live in a close symbiosis with aphids, and intensively tend them for honeydew. Since aphids are host tree species specific (e.g. Dixon 1973), a change in aphid species could have broken the specific symbiosis between aphids and RWAs. Other ant species, such as two of the most abundant ant species in mature boreal forests, Campono- tus herculeanus and Myrmica ruginodis, benefit from the disappearance of RWAs and the micro- climatic changes after clear-cutting (Punttila et al. 1991). However, when forest succession proceeds, these areas will presumably be colo- nised again by the shade-tolerant RWA species Formica aquilonia (Punttila et al. 1994, Punttila 1996). The RWA mound density did not differ between the mature and the 5-year-old forest stands, but the mounds in the latter ones had a smaller volume. A more extreme microcli- mate on clear-cut areas aggravates temperature regulation in the mound (Rosengren et al. 1979). Clear-cutting results in higher soil surface tem- perature and increased precipitation reaching the forest floor. This may result in a faster decom- position of mound material, as there are already more decomposer microbes in the mound than in the soil (Laakso & Setälä 1997, 1998). This, and possible compaction of the mound mate- rial (since RWAs no more maintain the porous mound structure) could decrease mound height, as was indicated in Table 2. Clear-cutting can also cause the splitting of large mounds into smaller colonies (Rosengren & Pamilo 1978), which could explain the high number of smaller mounds in the 5-year-old stands (Fig. 1). Current logging practices and site preparation in Finland are less intensive (Forestry environment guide 1994, Korhonen et al. 1998) than some 20 years ago. 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