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Importance of dead wood resources for woodpeckers in coniferous stands of the Białowieża Forest

Published online by Cambridge University Press:  09 August 2012

DOROTA CZESZCZEWIK*
Affiliation:
Siedlce University of Natural Sciences and Humanities, Department of Zoology, Prusa 12, 08-110 Siedlce, Poland.
WIESŁAW WALANKIEWICZ
Affiliation:
Siedlce University of Natural Sciences and Humanities, Department of Zoology, Prusa 12, 08-110 Siedlce, Poland.
CEZARY MITRUS
Affiliation:
Department of Zoology, Rzeszów University, Ćwiklińskiej 2, 35-601 Rzeszów, Poland.
TOMASZ TUMIEL
Affiliation:
Towarowa 2a/48, 15-007 Białystok, Poland.
TOMASZ STAŃSKI
Affiliation:
Siedlce University of Natural Sciences and Humanities, Department of Zoology, Prusa 12, 08-110 Siedlce, Poland.
MUSTAPHA SAHEL
Affiliation:
Siedlce University of Natural Sciences and Humanities, Department of Zoology, Prusa 12, 08-110 Siedlce, Poland.
GRZEGORZ BEDNARCZYK
Affiliation:
Siedlce University of Natural Sciences and Humanities, Department of Zoology, Prusa 12, 08-110 Siedlce, Poland.
*
*Author for correspondence; e-mail: [email protected]
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Summary

Many woodpecker species are known to be sensitive to the removal of dead wood. In 1999–2001 and 2007–2009 woodpeckers and dead wood abundance were studied in coniferous stands of the Białowieża Forest, Poland. Transects (3.9–6 km long) were established in three zones of different types of management: 1) primeval, unmanaged stands (BNP); 2) partially managed nature reserve (RES); 3) heavily managed stands (MAN). Woodpeckers were counted along transects three times per season, and tree stand measurements (number of standing and fallen trees, diameter at breast height, volume of fallen logs) were made once every three years. Woodpecker indices were highest in BNP and lowest in RES in both three-year study periods. The highest number of species (seven) was recorded in RES. Indices of four woodpeckers including two focal species (Three-toed Woodpecker Picoides tridactylus and White-backed Woodpecker Dendrocopos leucotos) were dependent on the basal area of dead standing trees. The same relation was found for the whole woodpecker assemblage. The highest indices were recorded in BNP, where the highest density of dead standing trees was recorded, and the lowest in the MAN transect with the lowest density of dead trees. However in the RES plot the amount of dead wood was much lower than in the national park. We recommend that the management regulations in Polish nature reserves be changed. In coniferous reserves, it would be best to leave at least 2 m2 ha-1 (basal area) of freshly killed spruce Picea sp. after each bark beetle outbreak.

Type
Articles
Copyright
Copyright © BirdLife International 2013 

Introduction

Dead wood is a very important element of forest ecosystems; it was abundant in the past in forests but now is generally very scarce. In primeval forests, standing and fallen dead trees provide food and shelter for many rare and threatened species, including vertebrates as well as invertebrates (Whiles and Grubaugh Reference Whiles, Grubaugh, McMinn and Crossley1996, Bobiec et al. Reference Bobiec, Gutowski, Zub, Pawlaczyk and Laudenslayes2005, Walankiewicz et al. Reference Walankiewicz, Czeszczewik, Mitrus and Bida2002). The abundance of dead wood also contributes to biodiversity (Ohlson et al. Reference Ohlson, Söderström, Hörnberg, Zackrisson and Hermansson1997) and is an important key element outside, as well as within, traditional protected areas (Jönsson and Jonsson Reference Jönsson and Jonsson2007). Many woodpecker species are associated with dead trees which are used for foraging, roosting or nesting. A positive correlation between the amount of dead wood and woodpecker indices in deciduous stands of the Białowieża Forest was shown by Walankiewicz et al. (Reference Walankiewicz, Czeszczewik, Mitrus and Bida2002). Among the species most sensitive to the removal of dead wood in the forest are two of the rarest European species, Three-toed Woodpecker Picoides tridactylus and White-backed Woodpecker Dendrocopos leucotos (Bütler et al. Reference Bütler, Angelstam, Ekelund and Schlaepfer2004, Czeszczewik and Walankiewicz Reference Czeszczewik and Walankiewicz2006, Roberge et al. Reference Roberge, Angelstam and Villard2008). Dead and dying trees (notably Norway spruce Picea abies in Europe) are usually removed from managed forests as a means of reducing pest species. Obviously, these practices lead to a decrease in forest biodiversity causing conflicts between forest conservation and forestry interests (Wesołowski Reference Wesołowski2005).

In the Białowieża Forest which served as a protected hunting area for centuries, heavy logging started late, i.e. during the First World War and is still ongoing. Only c.16% of the forest is protected as a national park while the rest, including nature reserves, is managed by the state forestry service and quotas of logged timber were as high as 150,000 m3 year-2 (Wesołowski Reference Wesołowski2005). Although the intensity of management is lower in nature reserves, during sanitary cutting due to outbreaks of spruce bark beetle Ips typographus a lot of infested spruce trees were removed. As a result, the amount of dead wood in the nature reserves is much lower than in the strictly protected stands of the Białowieża National Park (Bobiec Reference Bobiec2002, Walankiewicz et al. Reference Walankiewicz, Czeszczewik, Mitrus and Bida2002). Despite long-term protection, in some reserves lasting even for 90 years, old-growth stands, large snags and fallen logs are present only rarely. Such selective cutting and removal of dead spruce in managed stands and nature reserves has led to habitat destruction for the Three-toed Woodpecker. Removal of infected spruce from whole nature reserve stands was allowed in the Białowieża Forest until spring 2008.

Our goal was to assess the impact of dead wood resources and type of forest management with three levels of protection, national park, nature reserve and managed stands, on woodpecker communities in coniferous stands of lowland forest. We also make recommendations on management of dead wood resources in forests, especially in Polish nature reserves to improve habitat quality for woodpeckers.

Study area and methods

The study was conducted during two three-year periods (1999-2001 and 2007–2009) in the Białowieża Forest, north-east Poland. Białowieża Forest (52°29′–52°57′N, 23°31′–24°21′E) is located on the border between Poland and Belarus and covers c.1,500 km2 in total. This forest was protected for centuries as a royal hunting area but its intensive exploitation started during the First World War. The whole Polish section of the Białowieża Forest is a Natura 2000 site. Its central part (47.47 km2) is very well preserved and protected by law since 1921 as the Białowieża National Park, which was enlarged to 105.2 km2 in 1996. Most of the national park tree stands and some small fragments outside the park have a primeval origin. Tree stands are multispecies, multilayer and uneven-aged, with large amounts of standing and fallen dead wood. The most common type of forest is lime-hornbeam-oak stands dominated by hornbeam Carpinus betulus, lime Tilia cordata, oak Quercus robur, Norway spruce, Norway maple Acer platanoides and some other species. River valleys and some depressions are covered with ash-alder stands (with ash Fraxinus excelsior, alder Alnus glutinosa and spruce). Coniferous spruce-pine forests (with spruce and Scots pine Pinus sylvestris and some admixture of broad-leaved trees) are located on sandy soils (Faliński Reference Faliński1986).

Most (c.82%) of the Polish part of the Białowieża Forest is managed by the State Forestry Service. Within this area, 21 nature reserves (c.120 km2) are located – about 20% of the total forest area. In nature reserves outside Białowieża National Park, some management activity is allowed e.g. sanitary cutting and planting new trees. Removal of all infested and susceptible spruce was allowed according to the law in most nature reserves until March 2008.

Three transects were set out in coniferous stands, dominated by Norway spruce and Scots pine and representative of various types of forest management i.e. national park, nature reserve and managed stands (Figure 1):

  • − BNP (3.9 km) – in primeval stands of the Białowieża National Park. The transect consisted of two sections (due to a lack of a sufficiently long single stretch in one site) along forest roads. Spruce-pine forest with an admixture of oak, birch Betula spp. and hornbeam. It was an old-growth stand with the oldest trees exceeding 200 years in age. No management, except for removal of fallen trees from the road.

  • − RES (5.5 km) – in the nature reserve, along the Hajnówka–Białowieża road. Spruce-pine forest (old and middle age) with an admixture of hornbeam, oak and aspen Populus tremula. The age of the forest was c.80–150 years. Until the beginning of 2008 some so-called “sanitary cutting” was done there (mainly removal of infected and dead trees).

  • − MAN (6 km) – in managed stands, along the Jagielloński forest road. Spruce-pine forest of mixed age covered this part of the forest, with some admixture of birch, oak and hornbeam. This forest was about 40–80 years old and it represents most of the managed coniferous tree stands in Białowieża Forest. Typical management was conducted here (clear-cuts and spruce-pine fenced plantations).

Figure 1. Location of transects in the Białowieża Forest.

Woodpeckers were counted along transects using the bike-transect method described in detail by Walankiewicz et al. (Reference Walankiewicz, Czeszczewik, Mitrus and Bida2002). Three times per season (31 March–22 May), in the early morning (04h30–07h45), all woodpeckers seen or heard drumming or calling were recorded. Transects were conducted at an average speed of c.5.5 km h-1. For each species, the maximum number of records from one of the three counts was included in the analysis in each season (as an index we used the mean number of woodpeckers recorded per 1 km). For other analyses, the average values of the annual maxima from the three consecutive years were used.

Along all transects, dead wood resources were measured twice (in 2000–2001 and 2008–2009). All standing and fallen trees (logs) were recorded and measured within rectangular (20 x 25 m) plots evenly distributed along both sides of the transect (20 plots in BNP, 28 in RES, 31 in MAN). Each sample plot was located 20 m away from the road so they could be considered as representative of the forest structure away from roads. Diameter at breast height (DBH) for all standing trees, their condition (alive or dead), and species were recorded. For each fallen log, the length of the main trunk and the diameter at each end were also measured. Then, the volume of the fallen logs was calculated using the cut-cone formula. The basal area of standing trees was calculated using the circumference of the tree trunk section at breast height. For all calculations, only trees with at least 11 cm DBH were included. For comparisons, average values recalculated for each plot per hectare were used. Therefore, the sample size for each transect was equal to the number of the measured plots i.e. 20 (BNP), 28 (RES) and 31 (MAN). The effects of basal area of dead and live trees, transect location, and time of study on the numbers of woodpeckers were analysed with generalised linear mixed models (GLMM) using restricted maximum likelihood. Generalised linear models (GLZ) with Poisson distribution and logarithmic link function were constructed to analyse the relationships between transect location and study period on characteristics of tree stands. Statistical analyses were performed using Statistica® version 9.0.

Results

Woodpeckers

The highest number of species (seven) was observed in RES and the lowest in the MAN transects (four species in 1999–2001, and only two – Great Spotted Woodpecker Dendrocopos major and Black Woodpecker Dryocopus martius in 2007–2009). In BNP, five species of woodpeckers were recorded during the study (Table 1) and no differences in the number of woodpecker species between two three-year study periods were recorded on all study plots (χ2 = 0.71, df = 2, P= 0.70).

The average total indices of all woodpeckers combined (and without the Great Spotted Woodpecker) increased on all transects in 2007–2009 compared to 1999–2001, and their numbers depended on the effects of basal area of snags but not on the basal area of live trees, study period and location of transect (Table 2). The highest indices were recorded in the BNP in both three-year study periods (Table 1), where the highest density of dead standing trees was recorded and the lowest in the MAN transect in the second study period with the lowest density of dead trees (Table 3).

Table 1. Indices of woodpeckers (individuals km-1) on three transects during six years of study.

The Great Spotted Woodpecker was the most numerous species. Its density was dependent on the basal area of snags but not on the basal area of live trees, the study period and location of transect (Table 2), and no interaction between study period and location was recorded. The same pattern was observed in the Black Woodpecker, Three-toed Woodpecker and White-backed Woodpecker where their density was dependent on the basal area of snags but not on the basal area of live trees, the study period, or location of transect (Table 2). In the case of the Middle Spotted Woodpecker Dendrocopos medius and Grey-headed Woodpecker Picus canus no effect of any analysed factors was found (Table 2). Only Lesser Spotted Woodpecker Dendrocopos minor density depended on transect location, but not on the basal area of snags or study period, and interaction between study period and location was recorded (Table 2). In comparison to 1999–2001, indices of the other species combined, except for Great Spotted Woodpecker in 2007–2009, decreased only in the transect MAN (Figure 2), where density of snags was the lowest (Table 3).

Table 2. Effects of basal area of dead and live trees, transect location and time of study on the numbers (indices = individuals km-1) of woodpeckers (F-tests for linear mixed model fits); df: denominator degrees of freedom. Bold P-values indicate significant effects.

Figure 2. Average basal area of snags (bars; whiskers show standard deviations) and changes in woodpecker abundance (all but the Great Spotted Woodpecker) in two study periods.

Table 3. Habitat characteristicss on transects during two study periods. Mean and (±) standard deviation are shown. Sample size in parentheses.

Dead wood resources

The basal area of standing dead trees was dependent on the study area (Wald’s statistic = 532.7, P < 0.001) and on study period (Wald’s statistic = 19.63, P < 0.001). The same relation was observed in the case of the volume of fallen wood (Wald’s statistic = 146.5, P < 0.001 and Wald’s statistic = 27.6, P < 0.01, respectively). The greatest amount of dead wood (standing trees and fallen wood) was found in BNP while the lowest was in both: MAN (both periods) and RES (first study period; Table 3).

Discussion

Line transect methods are used relatively often for the estimation of the abundance of common breeding birds in forest landscapes (Solonen and Jokimäki Reference Solonen and Jokimäki2010). The bike-transect method, a variant of the line-transect method, if used for woodpeckers only, is relatively easy to conduct in the field but the observers should be very well trained in distinguishing the calls and drummings of all woodpecker species (Walankiewicz et al. Reference Walankiewicz, Czeszczewik, Mitrus and Bida2002, Reference Walankiewicz, Czeszczewik, Nowak, Chylarecki, Sikora and Cenian2009, Reference Walankiewicz, Czeszczewik, Tumiel and Stański2011). Results obtained by this method do not provide information on the number of territories because both sexes of woodpeckers can drum or call. However, results can be comparable between different plots or years using indices (recorded woodpeckers per kilometre). The bike-transect method was recommended as a fast inventory method for some woodpeckers in lowland stands (Czeszczewik et al. Reference Czeszczewik, Walankiewicz, Nowak, Chylarecki, Sikora and Cenian2009, Walankiewicz et al. Reference Walankiewicz, Czeszczewik, Nowak, Chylarecki, Sikora and Cenian2009).

The highest number of species (seven) was observed on the RES transect while in BNP only five species were found. We might expect the greatest diversity in BNP due to the highest amount of dead wood, but no Lesser Spotted or Grey-headed Woodpeckers were recorded there. Both species clearly prefer deciduous stands, which explains why they are rather sparsely distributed in the national park (Wesołowski et al. Reference Wesołowski, Czeszczewik, Mitrus and Rowiński2003). Three of the five species recorded in BNP are typical of coniferous forests and all these species (Great Spotted, Black and Three-toed Woodpeckers) comprised the basis of the community. White-backed Woodpecker and Middle Spotted Woodpecker are more often associated with deciduous stands and were observed in BNP much less frequently (Wesołowski and Tomiałojć Reference Wesołowski and Tomiałojć1986). Transect MAN was the poorest in both numbers of species and density of woodpeckers. This could be related to forest structure and the small amount of dead wood recorded there. This transect also had the lowest rate of deciduous trees compared to BNP and RES (Table 3). Tree stands along the transect MAN represented typical coniferous stands managed by the forestry service in the Białowieża Forest.

The most common species in all study years and transects was the Great Spotted Woodpecker. It most often uses live trees for both nesting and foraging (e.g. Michalek and Miettinen Reference Michalek and Miettinen2003), though we also showed its relationship to dead trees. The mean density of Great Spotted Woodpecker obtained by a mapping method in 1999–2001 and 2007–2009 in coniferous stands of the Białowieża National Park was 1.5 pairs 10 ha-1, while the other woodpecker species combined together had a mean density of 0.6 pair 10 ha-1 (Wesołowski et al. Reference Wesołowski, Tomiałojć, Mitrus, Rowiński and Czeszczewik2002, Reference Wesołowski, Rowiński, Mitrus and Czeszczewik2006, Reference Wesołowski, Mitrus, Czeszczewik and Rowiński2010). Earlier, the Great Spotted Woodpecker in primeval coniferous stands of Białowieża National Park comprised 71% of the whole woodpecker assemblage (range 58–83; Wesołowski et al. Reference Wesołowski, Tomiałojć, Mitrus, Rowiński and Czeszczewik2002, Reference Wesołowski, Rowiński, Mitrus and Czeszczewik2006, Reference Wesołowski, Mitrus, Czeszczewik and Rowiński2010). Similarly in this study it comprised 65% of all woodpeckers (range 56–78). This proportion was comparable to that in the RES transect (average 72%, range 55–86) but in the most transformed stands of the MAN transect the proportion of the Great Spotted Woodpecker was even higher (average 82%, range 70–94).

A positive correlation between woodpecker indices and density of snags also in deciduous stands of the Białowieża Forest has been found earlier. The total relative number of woodpeckers recorded in BNP was on average twice as high as in managed deciduous stands. Moreover three species, Three-toed, Black and White-backed Woodpeckers, foraged mostly on dead wood (Walankiewicz et al. Reference Walankiewicz, Czeszczewik, Mitrus and Bida2002). This study also confirmed that the same three woodpeckers were the most associated with dead wood resources in coniferous stands.

In the first years of study, Three-toed and Middle Spotted Woodpeckers were rarely recorded on the transect MAN and we had no such records of these species in the last years of the study. Due to habitat preferences, Middle Spotted Woodpecker occurrence in spruce-pine forest was rather occasional, while the Three-toed Woodpecker is a typical species of coniferous stands. This latter species requires freshly dead and dying spruce for foraging (Bütler et al. Reference Bütler, Angelstam, Ekelund and Schlaepfer2004, Pechacek Reference Pechacek2006). It is also considered as an indicator species in coniferous forests (e.g. Roberge and Angelstam Reference Roberge and Angelstam2006). In most of our studied transects, one-third to two-thirds of standing dead trees were spruces (Table 3) but in the transect MAN only a few dead trees per hectare were left. In the transect RES in the first study period (1999–2001) the Three-toed Woodpecker was only once recorded but in the second period (2007–2009), when a spruce bark beetle outbreak occurred, this woodpecker was regularly observed. This coincided with the prohibition of the removal of dead trees in nature reserves of the Białowieża Forest by the Polish Minister of Environment in March 2008.

In the primeval stands of BNP density of dead spruces was always so high (5–12 times higher than in RES and MAN transects; Table 3) that even spruce bark beetle outbreaks did not result in much increase in the numbers of the Three-toed Woodpecker. In contrast, in the nature reserve (RES) or managed stands (MAN), the amount of dead wood was unusually small, and even a slight increase in snag density (a few snags per hectare) could have a positive effect on woodpecker indices. It was shown earlier that the probability of the presence of Three-toed Woodpeckers increased significantly when basal area of snags increased from 0.6 to 1.3 m2 ha-1 in Switzerland and from 0.3 to 0.5 m2 ha-1 in Sweden (Bütler et al. Reference Bütler, Angelstam, Ekelund and Schlaepfer2004). In our study, snag basal area increased in the RES transect from 0.4 in 1999–2001 to 1.9 m2 ha-1 in 2007–2009, but decreased from 0.5 to 0.2 m2 in the MAN transect (Table 3). It was also shown by Wesołowski et al. (Reference Wesołowski, Czeszczewik and Rowiński2005) that “sanitary” logging, deliberate removal of dying and dead spruces from the forest, negatively affected the distribution of the Three-toed Woodpecker in part of Białowieża National Park.

Bütler et al. (Reference Bütler, Angelstam, Ekelund and Schlaepfer2004) suggested that the volume of dead wood in managed forests in Sweden is too low to sustain Three-toed Woodpeckers in the long-term. The amount of dead wood in managed stands of the Białowieża Forest in comparison to Swedish forests (Fridman and Walheim Reference Fridman and Walheim2000) is even lower and thus the viability of a long-term sustainable population of the Three-toed Woodpecker in the whole Białowieża Fortest is uncertain. The BNP area is too small to assure the long-term survival of the Białowieża Forest population (Wesołowski et al. Reference Wesołowski, Czeszczewik and Rowiński2005). For the existence of the Three-toed Woodpecker, at least 5% of dead standing trees in older forests should be left; this corresponds to a basal area of c.1.3 m2 ha-1 (Bütler et al. Reference Bütler, Angelstam, Ekelund and Schlaepfer2004). In the Białowieża Forest only BNP (in both study periods) and the RES transect (in the second study period) provided these values. Tree stands of Białowieża Forest outside the national park are poor in dead wood resources. Only the ban on so called "sanitary cutting" in nature reserves of the Białowieża Forest by the Polish authorities in 2008 helped to rebuild dead wood resources in these reserves. However, this is not a permanent law.

The average volume of fallen logs in managed productive forest land in Sweden was estimated to be 2.1–7.7 m3 ha-1, and the highest volumes (c.9.3 m3 ha-1) were found in spruce forests in the north (Fridman and Walheim Reference Fridman and Walheim2000). Much smaller volumes of fallen logs were found in the managed stands of Białowieża Forest (MAN) in the last years of our study (1.4 m3 ha-1) and slightly more in the nature reserve (RES) in the second period (11.5 m3 ha-1) compared to the volumes in the BNP (Table 3). In Swedish forests, 73% of the total dead wood volume consisted of logs and 27% of snags (Fridman and Walheim Reference Fridman and Walheim2000). We did not measure the volume of snags, but if we compare the density of snags and logs in all transects their proportion was c.1 : 1. Snags are usually on average larger than fallen dead trees (Nilsson et al. Reference Nilsson, Niklasson, Hedin, Aronsson, Gutowski, Linder, Ljungberg, Mikusiński and Ranius2002). In deciduous managed stands of the Białowieża Forest, the total volume per hectare was larger for snags than for logs (Czeszczewik and Walankiewicz Reference Czeszczewik and Walankiewicz2006). However, in the primeval stands of the Białowieża National Park (Bobiec Reference Bobiec2002, Czeszczewik Reference Czeszczewik2009b) there was a larger volume of logs than snags.

The nature reserve where the RES transect was located was established in 1921 as BNP, however, dead wood resources are much lower there (in the first study period the amount of dead wood in RES was similar to that recorded in MAN transect). Some increase in dead wood was recorded after 2008 (Figure 2), but this is still not enough to meet the needs of woodpeckers. We should keep in mind that dead wood removal practices lasted for more than 80 years. The nature conservation policy formerly applied in Polish forest nature reserves (dead wood removal) was not adequate to fully maintain biodiversity. As a result, with respect to the amount of dead wood, protected stands in forest reserves do not differ much from commercially managed stands. We consider that only the strictest forms of conservation as a national park or reserves where dead wood is not removed for a long time are sufficient to preserve the most valuable parts of the Białowieża Forest.

So, based on the above results, we recommend that the management regulations in nature reserves be changed. In coniferous reserves, it would be best to leave at least 2 m2 ha-1 (basal area) of freshly killed spruce after each bark beetle outbreak. Such outbreaks occur every several to 10 years or so in Białowieża Forest. Coniferous trees can stay as snags for a relatively long time, but are only valuable for some woodpecker species, e.g. White-backed Woodpecker, when in the later stages of deterioration (Czeszczewik Reference Czeszczewik2009a). However, the Three-toed Woodpecker, which is a focal species (Angelstam et al. Reference Angelstam, Bütler, Lazdinis, Mikusiński and Roberge2003), requires freshly dead or dying spruce (Amcoff and Eriksson Reference Amcoff and Eriksson1996). Forestry practices of removal of infested trees to draw the beetles away from healthy trees, as commonly applied in nature reserves and some national parks, can also destroy the habitats of other species threatened by forestry and lower forest biodiversity.

Acknowledgements

We heartily thank our many students for their help in tree stand measurements. Shelley A. Hinsley kindly checked the English. The kind co-operation of the Białowieża National Park administration and Polish State Forestry (Nadleśnictwo Białowieża) are acknowledged as well. The study was financed by a grant from the Polish Committee of Sciences (no. 6P04G05316), Siedlce University and Polish NGO “Pracownia na rzecz Wszystkich Istot” in Białystok.

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Figure 0

Figure 1. Location of transects in the Białowieża Forest.

Figure 1

Table 1. Indices of woodpeckers (individuals km-1) on three transects during six years of study.

Figure 2

Table 2. Effects of basal area of dead and live trees, transect location and time of study on the numbers (indices = individuals km-1) of woodpeckers (F-tests for linear mixed model fits); df: denominator degrees of freedom. Bold P-values indicate significant effects.

Figure 3

Figure 2. Average basal area of snags (bars; whiskers show standard deviations) and changes in woodpecker abundance (all but the Great Spotted Woodpecker) in two study periods.

Figure 4

Table 3. Habitat characteristicss on transects during two study periods. Mean and (±) standard deviation are shown. Sample size in parentheses.