Characterizing demographic variation and contributions to population growth rate in a declining population

We studied a population of ring ouzels, a migratory multi-brooding thrush, inhabiting c. 22 km² of southern Glen Clunie (56°56′N 3°25′W), Braemar, Scotland, during 1998–2009. Ring ouzels also inhabit the rest of Glen Clunie and adjacent glens, meaning that the Glen Clunie population is not isolated and estimated demographic rates can be interpreted in the context of the wider population. Demographic decomposition for such a species provides a valuable addition to existing comparative data. Furthermore, since ring ouzel is a red-listed Biodiversity Action Plan priority species in the UK (Sim et al. 2010), understanding demographic causes of variation in λ is also of direct applied value.

To estimate population size we systematically walked through the core study area, covering all ground to ≤200 m, every 1–2 weeks between mid-April and mid-July each year, and recorded the location of all ring ouzels. British ring ouzels occupy distinct breeding sites, typically separated by ≥240 m, with conspicuous territorial behaviour that allowed individuals to be detected at long range using binoculars. Individuals regularly make two, rarely three, breeding attempts per season (Burfield 2002). Each breeding attempt takes on average 29 days from first egg laying (3 days laying, 13 days incubation and 13 days to fledging; Burfield 2002). The number of ‘early’ pairs was defined as those present within 30 days of the first laying date in each year. Late pairs were defined as pairs present on or after day 31 in each year (Fig. 1). Initial sightings of pairs were substantiated by stronger evidence of breeding (e.g. nest-building, active nest, recently fledged young) in about 90% of cases. Where no further evidence of breeding was obtained, pairs were assumed to have failed early in the breeding attempt. Population size in each year (N_t) was estimated with high confidence as the maximum number of early pairs observed in that year. Resightings of marked individuals suggested that the detection rate was effectively one (see Results). Although any pairs that failed early in a breeding attempt and immediately dispersed may have gone unrecorded, any such cases were probably very rare. Estimates of N_t are therefore likely to be accurate, and population growth rate (λ) for each year during 1998–2009 was calculated as N_t+1/N_t.

To quantify links between demographic variation and λ, assuming an equal primary sex ratio, we used the following equation:

All demographic parameters are defined in Table 1. We then attempted to estimate all demographic rates required to parameterize this equation assuming a female-based cycle and that all ouzels first bred age one.

Laying dates were recorded directly from nests found during laying or hatching, estimated using known relationships between chick age and wing-length and weight (Burfield 2002), or by comparison with photographs of known-age nestlings. Nests were typically visited every 5–7 days until chicks fledged to record clutch and brood size. These regular nest visits enabled calculation of daily nest survival rates (DNSR) using the Mayfield (1975) method, which accounts for variation in the times at which nests are found, and thus in the length of the period over which they are monitored and exposed to risk of failure. As DNSR may vary through the season (Mayfield 1975), we calculated separate estimates for early and late nests, and tested for among-year variation and linear change across years in both estimates separately and combined. Overall DNSR was calculated as the product of DNSR (egg stage) and DNSR (chick stage). To calculate the proportion of nests surviving the egg and chick stages, we raised the appropriate DNSR to the powers of 16 (3 days laying plus 13 days incubation) and 13 respectively. The overall nest survival rate (ONSR) was calculated as the product of the proportion of nests surviving the egg and chick stages.

All females were assumed to make an early breeding attempt (C_e=1). Two methods were used to estimate the proportion of females that made more than one breeding attempt (C_l– re-nesting rate) within each year. First, the annual proportion of individually colour-ringed females from early nests that were observed making second (or rarely third) breeding attempts was calculated directly. However, sample sizes of individually colour-ringed females were small (range 7–19 per year). Therefore, to substantiate estimates based on colour-ringed females, we calculated the ratio of the number of breeding pairs present during the late season to the early season in each year. This method lacks the precision of monitoring individual females, but benefits from including data from the whole breeding population.

Mean RS [the number of young fledged per female, estimated as the product of mean brood size at fledging in successful nests (Y) and nest survival rate] was estimated for both early (RS_e) and late (RS_l) nests, and mean overall RS was calculated as RS_e + (RS_lC_l). Standard errors were calculated following Hensler (1985):

where SE is the standard error of Y² and σN is the variance in ONSR.

We used generalized linear models and appropriate post hoc tests to test whether each component of RS (excluding DNSR, for which see above) varied among years. Error structures and link functions were Gaussian and identity for laying date (measured as Julian date from 1 April), Poisson and log for clutch and fledged brood size and binomial and logit for re-nesting rate. We tested for among-year variation in mean RS using Student’s t tests with appropriate Bonferroni adjustments, following Bailey (1981). We then tested for linear increase or decrease across years in the annual means of each variable (excluding DNSR) using least squares regression. Means were weighted by annual sample size for laying date, clutch size and fledged brood size, and by the minimum annual value of DNSR and fledged brood size for RS_e, RS_l and overall RS.

During 1999–2008, 221 adult ring ouzels marked with British Trust for Ornithology (BTO) metal rings and individual combinations of 3–4 colour rings were used to estimate ϕ_ad. These comprised 22 males and 23 females originally ringed as chicks within or outside Glen Clunie, and 81 male and 95 female previously unringed individuals that were trapped and ringed as breeding adults in Glen Clunie (Sim & Rebecca 2003). These adults were aged as either first-year (hatched the previous year) or adult (hatched two or more years previously) at capture (Svensson 1992). Substantial effort was made to resight all colour-ringed adults each year, both at nests during territory visits and in nearby feeding areas. Resighting effort was intensive across the study area throughout each season, resulting in a very high local resighting rate each year (see Results). Any within- or between-year dispersal between consecutive breeding attempts may result in underestimation of adult apparent survival (Paradis et al. 1998; Winkler et al. 2004). However, little dispersal was observed during opportunistic visits to nearby breeding areas, suggesting that breeding dispersal was relatively rare. Furthermore, the high annual resighting probability within Glen Clunie suggests little temporary emigration among years. To estimate ϕ_ad, we initially fitted a fully sex- and year-dependent Cormack–Jolly–Seber (CJS) model (Lebreton et al. 1992; White & Burnham 1999). This model fitted the data [goodness-of-fit tests from program release, P = 0·93 (male) and P = 0·54 (female)]. Although there was some evidence of under-dispersion (), this was relatively small and we therefore set (Cooch & White 2008).

To measure ϕ_f during 2006–08, chicks were fitted with 1·8 g TW4 single-celled radio tags (http://www.biotrack.co.uk) just prior to fledging (10–13 days post-hatch). Tags were back mounted using an elastic harness with weak link to allow tag loss after a few weeks. In 2006, 22 late nest chicks were tagged; this trial showed no detrimental effects. A further 23 and 21 early nest chicks and 18 and 26 late nest chicks were therefore tagged in 2007 and 2008 respectively (giving totals of 44 early nest chicks from 25 broods and 66 late nest chicks from 29 broods respectively). Tags had a signal range of up to 10 km with direct line of sight, but more typically 2–3 km depending on terrain, and a battery life of up to 4 months. Tagged fledglings were located once every 2–3 days post-fledging, until the bird was found dead, shed the tag or disappeared and was assumed to have dispersed from the study area. We used the combined 2006–08 data to estimate weekly ϕ_f for chicks from early and late nests, for 5 weeks post-fledging. The signals from nine of the 110 (8·2%) tagged fledglings were lost during the first 5 weeks post-fledging. As these individuals had unknown fates (and may have dispersed), they were censored from subsequent known-fate survival analyses.

During 1998–2002, 805 chicks (464 from early nests and 341 from late nests), comprising 85% of those known to have fledged from the study area, were ringed with BTO metal rings and a single plastic colour ring to allow year cohort but not individual identification. During 2003–08, 581 chicks (335 from early and 246 from late nests), comprising 90% of those known to have fledged from the study area, were ringed with three or four colour rings to allow individual identification without need for recapture. It was not possible to calculate resighting probability (P) for returning chicks marked with single cohort rings during 1998–2002, as they could not be individually identified until trapped and fitted with individual colour-ring combinations in later years. However, P for returning chicks marked with individual combinations during 2003–08 was estimated to be 1·00 (see Results). Hence, we assumed a constant P of 1·00 for all first-years during 1998–2009, and estimated the apparent probability of first-year survival (ϕ_1App) as for ϕ_ad (see above).

Estimates of ϕ_1App were low (see Results), probably reflecting natal dispersal away from the study area. We therefore used annual estimates of N_t, ϕ_ad, C and RS to estimate ϕ_1True (following eqn 1). The ratio of ϕ_1eTrue to ϕ_1lTrue was assumed to equal the ratio of ϕ_1eApp to ϕ_1lApp (see Results). Estimates of ϕ_1eTrue and ϕ_1lTrue therefore include immigration into Glen Clunie. Prospective and retrospective analyses based on these estimates therefore reflect demographic variation across the wider ring ouzel population (from which immigrants must originate), not across Glen Clunie specifically.

To quantify the expected proportional change in λ given a proportional change in each demographic rate and hence each rate’s elasticity (Benton & Grant 1999a; de Kroon, van Groenendael & Ehrlén 2000), we simulated a 5% increase in each individual rate (ϕ_ad, C_e, C_l, RS_e, RS_l, ϕ_1eTrue and ϕ_1lTrue) while holding the others constant and recorded the proportional change in N_t+1/N_t (eqn 1). This analysis assumes that all demographic rates vary independently (Benton & Grant 1999b; de Kroon, van Groenendael & Ehrlén 2000), which may be simplistic (van Noordwijk & de Jong 1986; Stearns 1992; Tavecchia et al. 2005). To assess the possible degree of demographic covariation, we calculated pairwise parametric correlations between observed annual demographic rates. Correlations between ϕ_ad, ϕ_1eTrue and ϕ_1lTrue were calculated for 2000–09, and those between C_l, RS_e and RS_l were calculated for 1998–2009. However, ϕ_ad, ϕ_1eTrue and ϕ_1lTrue during 2000–09 were correlated with C_l, RS_e and RS_l during 1999–2008 (i.e. with a 1-year lag) due to the expected effect of reproductive success in year N_t on survival to year N_t+1. The only correlation we could not estimate directly was that between ϕ_1eTrue and ϕ_1lTrue. As estimates of ϕ_1App probably underestimated ϕ_1True (due to likely natal dispersal from the study area), the estimated correlation between ϕ_1eApp and ϕ_1lApp (−0·11) was of uncertain interpretation relative to the correlation between ϕ_1eTrue and ϕ_1lTrue. Indeed, a positive correlation between ϕ_1eTrue and ϕ_1lTrue might be expected since fledglings from early and late broods most likely experience correlated over-winter conditions. We therefore ran analyses assuming correlations of 0·25, 0·50 and 0·75 between ϕ_1eTrue and ϕ_1lTrue and assessed the sensitivity of conclusions to the assumed value.

To assess effects of demographic covariation on estimated elasticities, we calculated integrated elasticities (IEs). For a demographic rate x,

where r_xy is the correlation between rates x and y, and e_y and CV_y are the basic elasticity and coefficient of variation of y respectively (van Tienderen 1995; Sæther & Bakke 2000).

We estimated the realized contribution of each demographic rate to variation in λ as e_x²CV_x² (assuming no covariance among rates) or IE²_xCV²_x (assuming covariance among rates), thereby giving a variance-standardized elasticity (van Tienderen 1995). The total variance in λ can be estimated as the sum of this quantity across all demographic rates (x):

or

and hence the proportional contribution of each rate x to total variation in λ (X_x; Horvitz, Schemske & Caswell 1997; Gaillard et al. 2000; Caswell 2001) is:

or

We calculated CV to quantify and compare among-year variation in demographic rates that were measured on scales without upper limit (laying date, clutch size, fledged brood size and RS). However, CV is not suitable for comparing variation in proportions or probabilities since the maximum variance is constrained at α(1–α) for a proportion α. We therefore quantified the variability in demographic rates measured as proportions or probabilities (DNSR, C_l, ϕ_ad,ϕ_1App) as the ratio of the observed variance to the maximum possible variance [i.e. variance α(1−α); Gaillard & Yoccoz 2003; Morris & Doak 2004]. However, we additionally present CV to facilitate comparison with other studies that have used this approach.

Survival analyses were run in program mark 5.1 (White & Burnham 1999) using the nest survival (DNSR), known fate (ϕ_f) and recapture (ϕ_ad and ϕ_1App) models. Goodness-of-fit tests were not necessary for the DNSR and ϕ_f models as the saturated models fitted the data perfectly (Cooch & White 2008). For all models Akaike’s Information Criterion, adjusted for small sample size (AICc), was used to identify the best supported model that included the survival parameters of interest (Burnham & Anderson 2002). The model with the lowest AICc is the best supported model, and provides the best description of the data given the balance between over-fitting (hence loss of precision) and under-fitting (hence bias, Burnham & Anderson 2002).

We first tested for year effects on P, and then year effects on ϕ. Random effects models were used to estimate process variance in ϕ_ad and generate shrunk estimates (Burnham & White 2002; Loison et al. 2002). All other analyses were run in sas v8 (SAS Institute 2001). Means are presented as ±1 standard error (SE). Summaries of all main results and parameter estimates are presented in the main text. Further details of survival models and annual sample sizes are provided in Supporting information. To provide comparative context, estimated mean demographic rates were compared with published data from related species (see Discussion).

The number of breeding pairs (N_t) decreased from 39 in 1998 to 13 in 2009 (−67%, Fig. 2). There was a particularly large decrease (−37%) from 27 pairs in 2004 to 17 pairs in 2005 (Fig. 2). Mean population growth rate (λ) was 0·91 (range 0·63–1·00, SE = 0·03) during 1998–09, and N_t never increased from one year to the next.

Estimates of the mean, among-year variation and linear change across years in components of RS are described in Table 2 and Fig. 3. Sample sizes are given in Table S1 (Supporting information). In summary, early nest laying date varied significantly among years (being earlier in 2005 than in 2007 or 2008), whilst among-year variation in late-nest laying date approached significance. However, there was no significant tendency for either to become progressively earlier or later through the study period (Table 2, Fig. 3a). For clutch and fledged brood size, only early nest fledged brood size varied significantly among years (being smaller in 2006 than in 1998), and also showed a marginally non-significant tendency to decrease through the study period (Table 2, Fig. 3b,c). Although there was moderate support for models indicating greater early nest DNSR than late-nest DNSR, and that late-nest DNSR increased across years (ΔAICc = 1·0–1·5), the best supported model included constant DNSR across all nests (Table S2, Supporting information). Mean ONSR was 0·65 ± 0·04 (early nests) and 0·57 ± 0·05 (late nests; Fig. 3d).

The mean proportion of colour-ringed females recorded re-nesting was 0·64, while the mean ratio of the number of pairs present during the late vs. early season was 0·63 (Table 2, Fig. 3e). These two measures of re-nesting frequency were closely correlated across years (Spearman r₁₁ = 0·76, P = 0·007), suggesting that the latter provides a good measure of the overall re-nesting rate (C_l). Over 12 years, only five females were observed to make three breeding attempts in a season: one reared three broods, two reared two broods, and two reared one brood. Triple brooding therefore contributed little to λ. Re-nesting rate did not vary significantly among years, or increase or decrease significantly across years (Table 2, Fig. 3e).

Due to these patterns of variation in the lower level rates, both RS_e and RS_l varied significantly among years (being higher in 1998 than 2000, and in 2009 than 2000 respectively, Table 2, Fig. 3f). Overall RS also varied among years, being significantly higher in 1998 than in 2000 and 2008, and significantly higher in 2005 and 2009 than in 2000. Neither RS_e, RS_l nor overall RS increased or decreased significantly across years (Table 2, Fig. 3f,g). RS_l varied more among years than RS_e, followed by early laying date, late fledged brood size and early fledged brood size (Table 2).

Estimates of the mean, among-year variation and linear change across years in survival are described in Table 2 and Fig. 4a. The annual resighting probability (P) was estimated as 0·98 ± 0·02. The probability that a returning adult would remain undetected was therefore low. The best supported model included year-independent but sex-specific ϕ_ad (Tables 2 & S3, Fig. 4a). However, four further models received moderate support (ΔAICc = 1·3–2·0), including linear decreases in male and/or female ϕ_ad, or among-year variation in female ϕ_ad (Table S3, Supporting information).

The best supported model included week-independent ϕ_f that differed between fledglings from early (0·88 ± 0·03) and late (0·74 ± 0·03) nests (Table S4, Supporting information Fig. 4b). However, two further models received moderate support (ΔAICc = 0·9–1·3), including among-week variation in ϕ_f of fledglings from early or late nests (Table S4, Supporting information). ϕ_f across the first 5 weeks post-fledging was 0·57 ± 0·08 and 0·22 ± 0·06 for early and late-nest fledglings respectively.

Of 805 chicks ringed with single cohort colour rings during 1998–2002, 35 returned as adults, of which 26 were trapped and individually identified. Of these, 21 (81%) and five (19%) were from early and late nests respectively. The best supported model for ϕ_1App included linear decreases in both ϕ_1eApp (0·01/year) and ϕ_1lApp (0·004/year) during 1999–2009 (Table S5, Supporting information Fig. 4c). However, a model with no change across years received almost as much support (ΔAICc = 0·6, Table S5, Supporting information), and suggested that mean ϕ_1eApp (0·053 ± 0·008) was higher than mean ϕ_1lApp (0·022 ± 0·006). Mean estimated ϕ_1True during 2000–09, calculated from eqn 1, was 0·36 ± 0·04 (early broods) and 0·15 ± 0·02 (late broods, assuming that ϕ_1eTrue = 2·4xϕ_1lTrue, as observed for ϕ_1eApp). However, estimates of ϕ_1True will be sensitive to error in estimates of other demographic rates and N_t, and process variance cannot be estimated (see Discussion).

Basic elasticities indicated that λ was most sensitive to ϕ_ad, followed by RS_e and ϕ_1eTrue, and was relatively insensitive to C, RS_l and ϕ_1lTrue (Table 3). Population stability (λ = 1·0) would require increases in either ϕ_ad to 0·51 (21%), RS_e to 2·83 (22%), ϕ_1eTrue to 0·42 (22%), RS_l to 4·20 (100%) or ϕ_1lTrue to 0·27 (100%) over the mean observed rates. Increasing C_l to the maximum possible value of 1·0 would result in λ=0·96.

There were strong negative correlations between estimated ϕ_1eTrue and RS_e, and ϕ_ad and estimated ϕ_1eTrue, and strong positive correlations between ϕ_ad and RS_l, and C_l and RS_e (Table 3). Integrated elasticities indicated that λ was most sensitive to ϕ_1eTrue, closely followed by C_l, RS_e, ϕ_1lTrue and ϕ_ad. IE(ϕ_1eTrue) was qualitatively robust to changing the assumed correlation between ϕ_1eTrue and ϕ_1lTrue, but IE(ϕ_1lTrue) was less so (Table 3).

Assuming basic elasticities, ϕ_1eTrue was estimated to account for most variance in λ, followed by RS_e and ϕ_ad (Table 3). Assuming integrated elasticities, ϕ_1eTrue accounted for by far the most variance in λ, regardless of the assumed correlation between ϕ_1eTrue and ϕ_1lTrue. However, the estimated contribution of ϕ_1lTrue was sensitive to this assumption (Table 3).

Basic elasticities indicated that λ was most sensitive to variation in ϕ_ad, closely followed by RS_e and ϕ_1eTrue. These results are broadly consistent with previous studies of relatively long-lived vertebrates, which reported that λ was most sensitive to variation in ϕ_ad (e.g. Gaillard, Festa-Bianchet & Yoccoz 1998; Gaillard et al. 2000; Sæther & Bakke 2000; Reid et al. 2004; Ezard, Becker & Coulson 2006; Morrison & Hik 2007). However, basic elasticities do not consider covariation between demographic rates, which can account for a significant proportion of total variation in λ (Coulson, Gaillard & Festa-Bianchet 2005; Ezard, Becker & Coulson 2006). Calculating integrated elasticities, which do incorporate covariation, requires data describing the degree to which all demographic rates are constrained to covary. Demographic covariation is generally estimated across short time series from observational studies, and hence with substantial uncertainty over magnitude and causation (Reid et al. 2004; Ezard, Becker & Coulson 2006). However, integrated elasticities estimated from such data are still valuable in indicating whether conclusions based on basic elasticities are likely to be robust; yet remarkably few empirical studies have estimated integrated elasticities despite the clear need to do so (van Tienderen 1995; Coulson, Gaillard & Festa-Bianchet 2005).

There were substantial correlations among ring ouzel demographic rates, albeit across only 10–12 years and reflecting uncertain biological mechanisms. ϕ_ad was strongly positively correlated with RS_e and RS_l, while ϕ_1True was strongly negatively correlated with ϕ_ad, RS_e and RS_l. Given all provisos, integrated elasticities indicated that λ was most sensitive to variation in ϕ_1eTrue, closely followed by C_l, RS_e, ϕ_1lTrue, and ϕ_ad, but insensitive to variation in RS_l. Given the inevitably large uncertainty over the covariance structure, the integrated elasticities are perhaps best interpreted qualitatively rather than quantitatively. However, the substantial differences between basic and integrated elasticities emphasize the potential importance of accounting for demographic covariation, and the integrated elasticities suggest increased potential for variation in first-year survival to drive variation in λ compared to that predicted by basic elasticities.

Compared to the few other studies that have considered demographic covariation, all of which are subject to similar provisos to our study, our results contrast with Sæther & Bakke (2000), where λ was most elastic to variation in ϕ_ad in seven of eight bird species, and Reid et al. (2004) where λ was most elastic to variation in ϕ_ad, followed by pre-breeding ϕ and RS in red-billed choughs (Pyrrhocorax pyrrhocorax). A similar pattern has emerged in mammals, with integrated elasticities generally remaining highest for ϕ_ad (van Tienderen 1995; Coulson, Gaillard & Festa-Bianchet 2005), although in red deer (Cervus elephas) λ was most elastic to variation in RS (Benton, Grant & Clutton-Brock 1995).

The degree to which any demographic rate causes population change depends on the rate’s variability as well as the sensitivity of λ to this variation (Gaillard, Festa-Bianchet & Yoccoz 1998; Gaillard et al. 2000; Sæther and Bakke 2000). In ring ouzels, ϕ_1eTrue, ϕ_1lTrue and RS_l varied most (Table 2). Notwithstanding the uncertainty around the estimated variance of ϕ_1True and the associated covariance structure, ϕ_1True apparently contributed most to variation in λ based on both basic and integrated elasticities. Previous studies of both avian (Reid et al. 2004; Robinson et al. 2004; Ezard, Becker & Coulson 2006; Schaub et al. 2006) and mammalian (Gaillard, Festa-Bianchet & Yoccoz 1998; Gaillard et al. 2000; Coulson, Gaillard & Festa-Bianchet 2005) demography also concluded that ϕ₁ contributes most to variation in λ, suggesting that variation in first-year or sub-adult survival may be a common demographic cause of population dynamics.

There has been debate about whether the demographic rates to which λ is most sensitive, or those which account for most recent variation, are the most appropriate targets for population management (e.g. Benton & Grant 1999a; Wisdom, Mills & Doak 2000; Sibly & Hone 2002; Coulson, Gaillard & Festa-Bianchet 2005). However, when λ < 1 throughout a demographic study, the demographic changes responsible for population decline may pre-date the study period used to directly inform either prospective or retrospective analysis. The most elastic and/or variable rates as currently observed may consequently differ from those which have changed since previous periods of population stability, or could change again in the future. In this situation, demographic comparisons with other appropriate populations and species can help identify rates that were lower than expected given a population’s current life history (Peery et al. 2004).

Table S6 (Supporting information) compares our estimates of mean ring ouzel demography with those from other studies of ring ouzels and related species. These species comprise two closely related European species (blackbird Turdus merula and song thrush Turdus philomelos), and three closely related North American long-distance migrant species (wood thrush Hylocichla mustelina, ovenbird Seiurus aurocapilla and Swainson’s thrush Catharus ustulatus). All data were collected using similar methodology to ours, and thus constitute the most relevant comparative data.

Our estimates of mean clutch and fledged brood size, RS_e, RS_l and ONSR lie within the ranges recently observed in other UK ring ouzel populations (Table S6, Supporting information). These data suggest that these components of reproductive success were not unduly low in our study population, although the comparative data are also from declining populations. Blackbird and song thrush have similar clutch and fledged brood sizes to ring ouzels, but substantially lower ONSR and hence lower RS per attempt (Table S6, Supporting information). However, while female song thrushes in a declining population had overall RS of 2·7, those in a stable population had overall RS of 4·0 (Thomson & Cotton 2000). Thus, our estimate of overall ring ouzel RS (3·6 young fledged/female/year) compares favourably with this stable song thrush population. One challenging component of RS to measure is the re-nesting (or multiple breeding) rate. Although few rigorous comparative data are available, the mean observed re-nesting rate (0·63) was similar to that recorded in wood thrushes (0·61, Friesen et al. 2000). Overall, therefore, there is little compelling evidence that the overall RS observed in our declining ring ouzel population was substantially less than might be expected for such a species.

Our survival probabilities estimated from radiotracking suggested weekly and 5-weekly ring ouzel ϕ_f were similar to those estimated for all song thrush broods from British ringing recoveries (Table S6, Supporting information). In addition, our ring ouzel ϕ_f estimates also lie within those obtained from radiotracking fledgling ovenbird, Swainson’s thrush and wood thrush (Table S6, Supporting information). Our results are thus consistent with previous studies suggesting that ϕ_f is often a key component of avian ϕ_1True (Anders et al. 1997; Naef-Daenzer, Widmer & Nuber 2001; Rush & Stutchbury 2008), but do not suggest that ring ouzel ϕ_f was unusually low.

Mean estimated ϕ_ad was considerably lower than for British blackbirds and song thrushes (Table S6, Supporting information). However, British breeding populations of these species are largely sedentary and therefore not exposed to the same costs of migration as migratory ring ouzels (Wernham et al. 2002). Song thrushes breeding in Russia and Finland and wintering in southern Europe, and migratory wood and Swainson’s thrushes and ovenbirds, also had higher ϕ_ad than ring ouzels (Table S6, Supporting information). Thus, our estimate of ϕ_ad for ring ouzel is substantially lower than for migratory species with otherwise relatively similar life histories.