Study area

The study area (ca 2,000 ha) is located in Brittany (western France) and encompassed the Pont-Calleck State Forest (47°57‘27‘‘N, 3°21‘42‘‘W), adjacent woodlands and surrounding thickets and fields. All make up suitable habitats for the woodcock. The State Forest was composed of 80% deciduous (40-120 years old, including mainly oaks such as Quercus robur and Quercus rubra and beech Fagus sylvatica), and 20% of coniferous stands (15-40 years old, including mainly douglas-fir Pseudotsuga menziesii, sitka spruce Picea sitchensis and Scots pine Pinus sylvestris). The shrub stratum contained holly Ilex aquifolium and chestnut Castanea sativa. Adjacent woodlands were similar in composition and included various successional stages. Surrounding open areas were constituted of maize and cereal stubbles, winter wheat, ryegrass and permanent meadows (20%), oilseed rape and mustard fields. The Pont-Calleck State Forest was a woodcock hunting-free reserve whereas adjacent woodlands were woodcock hunting areas. Hereafter, the forest will be called the ‘reserve’ and the adjacent woodlands the ‘hunting area’. In France, woodcock is mainly hunted using one or two pointing dogs by a solitary hunter. The frequency of hunting trips is highly variable, but usually comprised 1-2 days/week/hunter.

Data collection

Our study was carried out during three consecutive winters (2003/04, 2004/05 and 2005/06). Since woodcock is a solitary, elusive and cryptic species which lives in woodlands, we used radio-telemetry in our study. From the beginning of December to the beginning of January, we captured 54 woodcocks (18 in 2003/04, 16 in 2004/05 and 20 in 2005/06) on feeding sites around the reserve in the first part of the night using a spotlight and a landing net (Gossmann et al. 1988). We chose this timing to ensure that the post-nuptial migration had ceased and that birds remained in the study area (Ferrand & Gossmann 2001). In November, woodcocks are abundant in Brittany; however, it is not possible to distinguish between migrating and wintering birds.

We aged each bird (1st year vs adult) according to wing feather details and moult status (Ferrand & Gossmann 2009a), and we sexed each bird by DNA analysis following the Sambrook et al. (1989) protocol. We fitted each bird with a VHF radio-transmitter (Biotrack® TW3; 12 g) with an activity tiltswitch. We glued the transmitter on the back of the bird using hypoallergenic livestock glue and maintained with a single-loop harness (Mac Auley et al. 1993).

We located each bird using a hand-held antenna by day (approached by circling to 10 m) and by night (approached by circling to 50 m), 5-6 times/week. We plotted the locations on a 1:2,000 map (source: Institut Géographique National) using a GIS package (ArcView® 3.3, ESRI, Redlands, USA). We calculated movement distances between locations using the Animal Movement extension (Hooge et al. 1999) in ArcView.

We recorded activity data for 24-hour periods. Recording started around 12:00 hours to get the activity rate during an afternoon, a full night and a morning. We used an automatic data logger (RX-900; Televilt Positioning AB, Lindesberg, Sweden) connected to a 4-element directional Yagi antenna, or a car omni-directional whip antenna located < 200 m from the bird. Depending on marked individuals' survival, we carried out 1-4 recordings/bird. We processed activity files using a program specially developed under the Visual Basic programming interface of Sigma Plot 2001 V.7.1 (SPSS Inc., Chicago, USA). We defined the beginning and the end of the night as the evening and morning civil twilights, which roughly correspond to the time when the commuting flight occurs. In our analyses, we considered the daylight/night activity rates separately. We estimated the activity duration per day (or night) by multiplying the activity rate (%) and the duration of the day (or night) at this date (see Duriez et al. 2005b for more details).

When nocturnal locations differed from diurnal locations (i.e. open areas vs forest, at a distance of > 50 m from the forest edge), the occurrence of a commuting flight was registered. We defined a commuting flight index as the proportion of nights on which birds left the woodland.

We defined disturbance as flushing a bird from its diurnal site. We allocated the radio-tagged woodcocks to three groups: controlled disturbance (CD; N = 16), hunted (H; N = 15) and control (C; N = 23). In the daytime, the radio-equipped woodcocks spread over the reserve and the hunting area, and maintained their daytime ranges throughout the study. We randomly allocated each radio-tagged woodcock staying in the reserve into CD and C birds. We classified all other birds staying in the hunting area in the daytime as H. The H birds were exposed to variable disturbance depending on hunters' activity, with no possibility of precisely registering the number of hunters, dogs, hunting hours and days. This explains the necessity of a CD group to ensure a homogeneous disturbance level. The CD birds were flushed once/day and 5 days/week (maximum number of hunting days allowed in the study area, and more generally in France, according to regional administrative decisions). Disturbance started between the 10th and 15th of January, when post-nuptial migration ceased (Ferrand & Gossmann 2001). Every winter, disturbance concluded at the end of February (closing period for woodcock hunting in France). We flushed the birds between 09:00 and 17:00 hours, as this period corresponds to the usual hunting hours. In most cases, we saw the bird in flight. In other cases, we considered disturbance as effective when the radio signal rapidly diminished.

We restricted the analysis to the period between the beginning of disturbance (mid-January) and the end of February for all behavioural responses, except the date of spring migration departure, which we analysed for woodcocks for which we knew this date. For all woodcocks, at least 30 diurnal locations were available. For the time-budget analysis, we took into account only individual activity recordings for which at least 50% of the time (in the daytime or at night) was actually monitored. We used only data collected at least six days after radio-transmitter fitting to avoid a behavioural impact due only to tagging (Kenward 2001). Disturbance started six days after tagging to allow enough time for observing a real disturbance impact.

Data analysis

For all the statistical tests performed for our study, we did not rely on an arbitrary α-level of statistical significance and strictly interpreted the P-value as the strength of the evidence against the null hypothesis H₀, conditionally to the data at hand (a P-value is defined as the probability, calculated under H₀, of obtaining a test value as extreme as that observed in the sample; see Gibbons 2006). Whatever the magnitude of the P-value, we gave a measure of the effect size, since one always needs to carefully consider the biological significance of a result, not just the statistical significance (Yoccoz 1991).

Space use

To summarise the statistical distribution of the daily distances woodcocks travelled, we used the median as a position measurement and the interquartile range to represent dispersion, because the distances were not symmetrically distributed. Using the median as abscissa and the interquartile range as ordinate allows one to represent the birds as points in a scatterplot. For studying space use during the day and at night, we employed a Multiple Response Permutation Procedure (MRPP; Zimmerman et al. 1985, McCune & Grace 2002:188-197, Mielke & Berry 2007) to test the null hypothesis H₀ of no difference between the three groups CD, H and C. The MRPP test was based on the Euclidean distances defined in the scatterplot, with natural weighting of the groups (McCune & Grace 2002:189, Mielke & Berry 2007:20). Hence, the MRPP statistic δ was the overall weighted mean of within-group means of the pairwise Euclidean distances. No distributional assumptions are required for MRPP testing purposes. We evaluated the P-value by using a randomisation procedure (see Edgington 1995, Manly 1997, Edgington 2006). To obtain an accurate P-value, we used 10⁶ random permutations as in Mielke & Berry (2007:33-35), and the minimum attainable P-value was thus P = 0.000001. We provided an effect size measure using the ‘chance corrected within-group agreement’ (McCune & Grace 2002:190, Mielke & Berry 2007:31):

with δ_obs being the observed value of the statistic δ measuring the within-group homogeneity (see Zimmerman et al. 1985, McCune & Grace 2002:189, Mielke & Berry 2007:14) and μ the expectation of the statistic δ under H₀. The statistic A is a chance-corrected measure of effect size, i.e. A reflects the within-group homogeneity compared to what would be expected by chance. A reaches its maximum value of 1 when the within-group homogeneity is perfect. A = 0 when the within-group homogeneity is equal to what is expected by chance. Like all chance-corrected measures, A could occasionally be slightly negative, i.e. when the within-group homogeneity is smaller than what is expected by chance. In ecology, values for A are commonly below 0.1 even when the δ_obs differs significantly from the expectation under H₀, and A > 0.3 is fairly high (McCune & Grace 2002:191). Furthermore, we used MRPP for testing the null hypothesis of no difference between males and females, and between yearlings and adults.

Space use

For both C (N = 22) and H (N = 15) groups, the median distance between successive diurnal locations per bird was always < 150 meters (average median = 63.9 and 51.4 m, respectively, SD = 28.7 and 30.5, respectively, range: 23.1-132.8 and 0-99.7 m, respectively). For these two groups, the maximal distances between successive diurnal locations for any bird were 1.1 km and 3.24 km, respectively. For the CD group (N = 15), the distances between successive locations were in most cases very large and irregular (average median = 241.3 m, SD = 174.8, range: 48.9-731.6 m; Fig. 1). For 10 CD birds, the median was > 150 m and the maximal distance between successive diurnal locations was 4.03 km. For five CD birds, the median was < 150 m. One CD bird left the study area after 13 days of disturbance (last distance between two locations = 5,510 m). The representation of birds on a scatterplot according to their median and interquartile range of distances led us to separate CD from the C and H groups (MRPP test: P = 0.000002, A = 0.225; Fig. 2). The dispersion of birds on the scatterplot appeared to be not mainly related to age and sex since the levels of evidence against H₀ and the effect sizes were much lower in comparison with the disturbance groups (MRPP test: P = 0.056, A = 0.025 and P = 0.017, A = 0.044, respectively).

At night, space use appeared to be very similar among groups (MRPP test: P = 0.51, A = −0.004). In spite of the impact of disturbance on diurnal space use, CD birds did not change their nocturnal sites (see Fig. 1). The representation of birds according to their median and interquartile range of distances did not lead us to separate any group (Fig. 3). The maximal distance between successive nocturnal locations was 3.33 km.

Time budgets

The mean of diurnal activity duration was 49.0 minutes (range: 2.0-231.0) for the CD group (13 birds, 24 measures), 65.9 minutes (range: 2.7-192.9) for H group (15 birds, 26 measures) and 78.4 minutes (range: 2.3-266.8) for C group (20 birds, 32 measures). We found no evidence of a difference between disturbance groups (P = 0.47; F = 0.76; ${\eta }_{\text{p}}^2$ = 6.23%). We found weak evidence that diurnal activity duration differed according to age (P = 0.16; F = 2.97; ${\eta }_{\text{p}}^2$ = 10.80%) or sex (P = 0.091, F = 2.07; ${\eta }_{\text{p}}^2$ = 8.13%). The occurrence of a commuting flight can have an impact on the time budget in so far as birds shared their activity between day and night. However, even weaker effects were obtained for a subset of the data taking into account only diurnal data including a commuting flight, between disturbance groups (P = 0.55, F = 0.61, ${\eta }_{\text{p}}^2$ = 5.77%), age (P = 0.49, F = 0.47, ${\eta }_{\text{p}}^2$ = 2.34%) and sex (P = 0.30, F = 1.09, ${\eta }_{\text{p}}^2$ = 4.95%).

The mean of nocturnal activity duration was 127.4 minutes (range: 4.8-297.8) for CD group (12 birds, 22 measures), 94.75 minutes (range: 5.0-224.8) for H group (12 birds, 25 measures) and 142.8 minutes (range: 3.3-302.9) for C group (21 birds, 31 measures).We found weak evidence that nocturnal activity durations significantly differed between groups (P = 0.14, F = 2.07, ${\eta }_{\text{p}}^2$ = 12.75%), and no evidence with respect to age (P = 0.45, F = 0.57, ${\eta }_{\text{p}}^2$ = 2.03%) or sex (P = 0.60; F = 0.28; ${\eta }_{\text{p}}^2$ = 1.04%). We obtained similar results for birds that commuted from forest to fields at night, for the disturbance groups (P = 0.11; F = 2.29; ${\eta }_{\text{p}}^2$ = 16.65%), age (P = 0.80; F = 0.07, ${\eta }_{\text{p}}^2$ = 0.31%) and sex (P = 0.96, F = 0.00, ${\eta }_{\text{p}}^2$ = 0.01%).

Occurrences of commuting flights

We did not find sufficient evidence that the pattern of occurrences of commuting flights differed between C (N = 21), CD (N= 14) and H (N = 14) groups (MRPP test: P = 0.43, A = 0.0007) or according to the sex (P = 0.14, A = 0.008) or age (P = 0.08, A = 0.011). This allowed us to pool the data and the mean commuting flight index (proportion of nights on which birds left the woodland) was 0.88.

Dates of spring migration departure

The spring migration departure date ranged from 7 March to 6 April with an average date of 21 March (N = 46; Fig. 4A). The ANOVA revealed only weak evidence of an effect of the groups C (N = 20), CD (N = 13) and H (N = 13) on the dates of spring migration departure (P = 0.085; F = 2.62; η² = 10.85%), the order of the average dates being CD < H < C. By contrast, there was more evidence that 1) males (N = 23) departed before females (N = 23) (mean dates:18 March and 24 March, respectively; Fig. 4B; P = 0.003; F = 9.58; η² = 17.87%), 2) adults (N = 13) departed before 1st year birds (N = 33) (mean dates: 16 March and 23 March, respectively; Fig. 4C; P = 0.001; F = 11.96; η² = 21.37%).

Disturbance effects

From our experimental study, the impact of simulated hunting disturbance on woodcock wintering behaviour seemed to be relatively weak. As expected, disturbance increased the space use. However, we found no impact on diurnal and/or nocturnal activity durations, occurrences of commuting flights, and only a weak effect on spring migration departure.

The main impact was a larger space use during the daytime for the CD woodcocks, one of which left the study area. Such large movements were not observed at night. By contrast, whatever the location of the diurnal site, the CD woodcocks kept a previous nocturnal site where most of their feeding occurred (Duriez et al. 2005b). This site fidelity was surprising considering the large distance sometimes separating diurnal and nocturnal sites (> 1.5 km), although closer nocturnal sites were available. Like many other bird species, wintering woodcocks face a trade-off between starvation and predation risk (Duriez et al. 2005b), and previous experience of suitable nocturnal sites with high food resources could encourage birds to continue using these sites. Exploring new nocturnal sites could also increase energy expenditures, which could be detrimental to the birds in the winter period. The nocturnal site fidelity probably explained, to a large extent, the weakness of the disturbance effect in so far as food intake was ensured. Of the woodcocks, four always remained in their diurnal sites in spite of a high level of disturbance. This indicated that the responses to disturbance can vary greatly among individuals, probably in relation to the quality of the occupied site and/or information acquired by the individuals at their sites (Gill et al. 2001).

We found no difference in the occurrence of commuting flights between disturbed and undisturbed birds. Since the main purpose of these flights is feeding in meadows, this shows that disturbance did not force woodcocks to reach nocturnal feeding sites more frequently. Nevertheless, extra diurnal flights of disturbed birds over large distances could imply a higher energy expenditure (as shown for the brent goose Branta bernicla bernicla; Riddington et al. 1996), a decrease in time available for foraging in less suitable sites (as reviewed by Frid & Dill 2002), and we could expect a higher nocturnal activity rate to compensate for this, as has been found for the sanderling Calidris alba (Burger & Gochfeld 1991) and the snow goose Chen caerulescens atlantica (Bélanger & Bédard 1990).We did not observe this in our study, likely because the high available earthworm biomass in meadows (about 1 ton/ha; Granval & Bouché 1993) does not constrain the instantaneous intake rate and easily allows woodcocks to compensate for a loss of diurnal foraging.

We found only a weak difference between disturbance groups; however, the order of spring migration departure seemed to be related to the disturbance level, i.e. the higher the disturbance level, the earlier the average date of departure. This suggests that even a high disturbance level does not impair preparation for migration, which is in contrast to the negative effect observed by Madsen (1995) for the pink-footed goose Anser brachyrhynchus. This could be related to the low energetic requirements of woodcock (Duriez et al. 2004) and/or a capacity to quickly increase energetic reserves as suspected by Duriez (2003). As an example, the whimbrel Numenius phaeopus, a similar-sized wader to the woodcock, is known to increase its daily food intake to 1.5 times the winter level a few weeks before spring migration departure (Zwarts 1990). As suggested by Klaassen (2002), another hypothesis could be to consider woodcock as an income breeder owing to its small size and relatively short flight range (< 3,000 km for the majority of woodcocks; Ferrand & Gossmann 2009b). In this case, energetic requirements before migration are rather low and only assigned to flight cost.

Simulation of hunting disturbance

In our study, the disturbance aimed to simulate hunting (without shooting). To apply a standardised protocol, we did not use hunting dogs to flush the birds. This seemed to be appropriate in so far as birds could be tracked using radio-telemetry and pursued till they flushed, i.e. as a hunting dog could have done it. Moreover, owing to radio-telemetry, the approach to the bird is usually direct, which is the most disturbing approach (Frid & Dill 2002). For standardisation, the birds were flushed once/day. This situation could be considered artificial compared with a hunting situation. During hunting, some birds may be flushed several times while others are never flushed. We considered that the regularity (5 days/week) and the duration of the experiment (1.5 month) were sufficient to generate disturbance at a level at least as high as hunting. We showed that H birds staying in the hunting area did not seem to change their behaviour as compared to undisturbed C woodcocks. Since we showed that CD birds increased their space use, this suggests that the controlled disturbance level used in our study was likely higher than the level of disturbance caused by hunting.

However, our study period did not correspond entirely to the woodcock hunting period which really starts at the beginning of November in Brittany. During the two first hunting months, the hunting pressure (number of hunters/day) is higher than in January-February, i.e. our study period (Ferrand & Gossmann 2000). In November-December, both migrating and wintering woodcocks are hunted. Migratory birds stay in the forest during a short period and should not be concerned by disturbance. In contrast, woodcocks that have already reached their wintering sites could be more sensitive. Nothing allows us to assume that the behaviour of wintering woodcocks facing disturbance differs in January-February compared with November-December.

Wintering woodcock behaviour

Our results suggest that the behaviour of the studied population was consistent with wintering woodcock populations in Brittany as described in Duriez et al. (2005c). Space use (for C birds), occurrences of commuting flight, date of spring departure (23 February - 10 April for O. Duriez, unpubl. data) were not different from expectations. The only exception was the time budget with about 200 minutes of activity in our study as compared to 300 minutes reported by Duriez et al. (2005c). This might have resulted from higher availability of food resources in our study area. Weather conditions may have increased the availability of earthworms and/or decreased energy expenditures (Wiersma & Piersma 1994, Duriez et al. 2004) and, therefore, may have reduced the daily period required to feed. During the three winters of our study, no exceptional weather conditions were registered (see  http://www.cdc.noaa.gov - Air temperature/Composite anomalies).

Management implications

In terms of woodcock habitat management, we emphasise the role of nocturnal feeding habitats. Indeed, as shown by Goss-Custard et al. (2006) for the oystercatcher Haematopus ostralegus, the impact of disturbance appears much lower with good feeding conditions. Consequently, we recommend that a special effort be made to maintain grazed meadows in the surroundings of forests in woodcock wintering areas because the earthworm biomass in meadows is five times higher than in cultivated fields (Duriez et al. 2005a). Maintenance of permanent meadows may help woodcock to better withstand disturbance.

Our study addressed disturbance effects on a local scale, for one habitat type and in rather mild weather conditions. This could be different in other wintering conditions, especially with regard to habitat. In Mediterranean regions, for example, woodcock food resources are scarcer than in Brittany and the behavioural responses to disturbance could be different. Additional experiments in different habitats and food resource levels seem to be necessary to estimate the impact of disturbance at a population level, as recommended by Sutherland (2007) and Gill (2007).