Study site

Sanderlings were studied at five different transects along the Belgian coast (centred at 51°13′N, 2°54′E; Fig. 1), namely at Heist (Baai van Heist — BH, 700 m long), De Haan (Vosseslag — VOS, 350 m), Raversijde (RAV, 630 m), Lombardsijde (LBS, 345 m) and Oostduinkerke (Schipgat — SG, 400 m). An alternation of ridges and runnels was present at BH, VOS and SG. Beach profiles of VOS and SG are furthermore characterised by an interrupted slope at about 4 m above mean low water spring level (MLWS), separating the beach into a wide, gently sloping lower part, and a narrow, steep upper part (Degraer et al. 2003).

Data collection

We collected information on habitat selection, foraging behaviour and diet of Sanderlings during 47 observation days between 23 February 2005 and 25 March 2006, during the months with highest numbers of Sanderling (October–March). On each observation day, numbers of Sanderlings present at the transect were counted each hour and the percentage of birds involved in foraging activities was estimated. It was noted whether the birds were associated with the water line or located on the emerged parts of the intertidal zone. In between these hourly ‘transect scans’, detailed behavioural observations of randomly chosen individual birds were made for up to five minutes, making use of a telescope and a tape recorder. While observing individual birds, their location on the beach (water line, intertidal, supralittoral) and activity (searching for food, feeding, running, resting, sleeping, preening, flying) was assessed continuously. Each foraging event was recorded. Foraging events were subdivided in ‘pecking’ (superficial pecks, bill not clearly penetrating the sediment), ‘probing’ (bill clearly penetrating the sediment) and “spooning” (bill clearly penetrating the substrate, bill swishing from side to side). The success of these foraging attempts was deducted from “snatching” movements of the bill. Obviously, our measure for foraging success is a minimum estimate as we may have missed ingestion of the smallest items.

Figure 1.

Location of the study transects along the Belgian coast.

Whenever possible, the caught prey was identified. During the observations of individual birds, the bird's location on the beach relative to the water line was assessed continuously. Thus, for birds foraging close to the water line, the time at which they were observed in combination with actual water levels gave the exact location on the beach expressed in height above MLWS. To link foraging characteristics of Sanderling to food densities we used macrobenthos data by Degraer et al. (2003), collected in the same transects. These results need to be interpreted with care since benthos sampling took place in 1997.

We defined foraging rate as the total number of foraging events per min of foraging time (searching and feeding). Foraging efficiency was defined as the percentage of successful foraging events. Similarly, we distinguished probe percentage as the percentage of probes to the total number of foraging events, and probing efficiency as the percentage of successful probes to the total amount of probes.

Statistics

To compare numbers of Sanderling and foraging characteristics among environmental factors (transects, tidal cycle and height above MLWS), the non-parametric Mann—Whitney U test (for pair-wise comparisons) and Kruskal—Wallis test were used (SPSS 9.0).

Foraging activity

The total number of Sanderlings present per km of shoreline averaged 10.0 (n = 303, SE 1.5) and varied between 2.6 individuals per km at LBS and 14.6 at RAV (Fig. 2). On average, 87.8% of the birds present at the transects were foraging. Of all foraging birds, 85% were located within 2 m of the water line, 13% on emerged parts of the intertidal area, and only 2% were seen on the tide line (supralittoral). Total numbers and foraging numbers of Sanderling significantly differed among the transects (total number: χ²₄ = 54.7, P < 0.0005; foraging number: χ²₄ = 53.1, P < 0.0005).

Foraging birds were present at the transects throughout the entire tidal cycle. Nevertheless, abundance on the beach and foraging numbers tended towards a tidal pattern, with highest numbers from 4 to 10 hours after high tide (or coinciding with low tide; total number: χ²₁₁ = 17.8, P = 0.085; foraging number: χ²₁₁ = 18.9, P = 0.061; Fig. 3).

Mean foraging rates ranged from 13.4 in BH to 24.4 in RAV, and mean foraging efficiency from 1% in LBS to 11% in BH (Table 1). A Kruskal-Wallis analysis revealed a significant difference between foraging rates and foraging efficiencies at the transects (foraging rate: χ²₄ = 17.7, P = 0.001; foraging efficiency: χ²₄ = 82.4, P < 0.0005). Pair-wise comparisons indicated that foraging performance of birds at BH differed from those at the other transects (Table 1). Averaged over all transects, foraging efficiency was 7%. Foraging efficiency was highest during probing (15%), and less so during pecking (6%) and spooning (1%).

Table 1.

Foraging rates (number of foraging events per minute) and foraging efficiency (% successful foraging events) of Sanderling at five transects along the Belgian coast.

Figure 2.

Mean numbers of Sanderling (±SE) at five transects (the numbers above the graph denote the numbers of scans).

Figure 3.

Mean numbers of Sanderling (±SE) per tidal stage (the numbers above the graph denote the numbers of scans).

Diet

In total, we observed 1182 successful foraging events, and in 41% of these cases we were able to identify the prey taken (Table 2). Identification of prey varied by the foraging mode, with 78% of the prey identified when the bird was probing, 62% when spooning, and only 25% of the prey were identified when pecking. Among the identified prey, polychaete worms (most likely Scolelepis squamata, see Discussion) were consumed most (22%), followed by bivalves (17%) that were predominantly eaten as wreck washed ashore by incoming tides. Occasionally, Sanderlings were observed taking small crabs, anemones and insects (washed ashore), or they were taking advantage of foraging Oystercatchers, eating leftovers in broken mussel shells.

Table 2.

Numbers and types of prey taken by Sanderling along the Belgian coast.

Energetic importance of polychaetes

Combining data from all transects, there was a clear tidal effect on probe percentage and probing efficiency (probe percentage: χ²₅ = 28.3, P < 0.0005; probing efficiency: χ²₅ = 27.6, P < 0.0005; Fig. 4A). Generally, probing for worms occurred most often just before high tide. Accordingly, most successful probes were observed during incoming tide, with maximum success occurring right before high tide. While probing was observed during receding tide as well, success was lower (Fig. 4A).

Probing and capture of polychaetes was concentrated at upper intertidal areas (probe percentage: χ²₄ = 40.2, P < 0.0005; probing efficiency: χ²₄ = 25.1, P < 0.0005; Fig. 4B). At all transects, birds were observed probing at lower parts of the intertidal as well. However, this occurred to a lesser extent and probing efficiency was much lower. In general, successful probing was concentrated in the limited area where S. squamata occurred in peak densities (Fig. 5).

Figure 4.

Mean probe percentage (+SE) and mean probing efficiency (-SE) in relation to the tidal stage (A) and height above mean low water spring level (B) (the numbers above the graph denote the number of observation bouts).

Assuming that all caught polychaetes were S. squamata, we can calculate the daily energy intake that this polychaete would support. According to Castro (1987), the basal metabolic rate (BMR) of Sanderling is 48.1 kJ/day. Taking the relationship of Net Energy Intake (NEI) to BMR for waders as reported by Kersten & Piersma (1987) (NEI is 2.4–4.9 multiples of BMR) and assuming an assimilation efficiency of 85% (Kersten & Piersma 1987), a Sanderling's daily energy intake varies between 136 and 277 kJ/day. Furthermore, the mean weight per individual S. squamata has been reported as 1.6 and 3.0 mg AFDW (Degraer et al. 1999 and Dankers et al. 1983, respectively). The caloric content of benthic animals ranges between 22 and 26 kJ/g AFDW, with a mean of 23.7 kJ/g AFDW for the taxon Annelida (Beukema 1997). Taking this variation into account, a daily energy intake of 136–277 kJ corresponds to 5.2–12.6 g AFDW of benthic prey per day, or 1735–7650 inidividuals of S. squamata each day. Based on the variation in probing efficiency with the tide (Fig. 4), and assuming that an individual Sanderling is present at the beach during a full tidal cycle, it follows that polychaetes may fulfil 2.0–9.0% of the bird's daily energy demand per tidal cycle. When the tidal-dependent variation in foraging activity is considered (Fig. 3) an even smaller percentage of the energy needs is covered (Table 3).

Figure 5.

Probe percentage and probing efficiency of foraging Sanderling in relation to height above mean low water spring level (MLWS) for four transects. Indicated are densities of S. squamata as measured in the same transects.

Table 3.

Comparing the total number of polychaetes caught per tidal cycle and the number needed to cover daily energy needs.