Population counts

Population count data were sourced from 17 countries, spanning the entirety of the Great Black-backed Gull’s breeding range (Figure 1 and Table 1). For a small number of countries, states, or regions, where total population counts were not available, a sample from selected breeding colonies was used (see “Data analysis” for how missing populations were incorporated in the analysis). All population counts represented the number of breeding pairs only, excluding data from the non-breeding season and non-mature birds, in line with IUCN criteria.

Figure 1. Global breeding range of Great Black-backed Gulls Larus marinus (areas coloured black) and countries where population counts were obtained (dark grey). Breeding range data were obtained from BirdLife International and Handbook of the Birds of the World (Del Hoyo et al. Reference Del Hoyo2019).

Table 1. Parameters used in the analysis. These include: two population counts per region (Count 1 and Count 2), the years these counts were obtained (Year 1 and Year 2), the error associated with each count (Error 1 and Error 2; see Table 2 for more information about error categories), and the locations each population count represents.

¹ BirdLife International (2000)

² BirdLife International (2015)

³ BirdLife International/European Bird Census Coucil (2020)

⁴ Bond et al. (Reference Bond, Wilhelm, Robertson and Avery-Gomm2016)

⁵ Cotter and Rail (Reference Cotter and Rail2007)

⁶ Lock (Reference Lock1979)

⁷ Fauchald et al. (Reference Fauchald, Anker-Nilssen, Barrett, Bustnes, Bårdsen, Christensen-Dalsgaard, Descamps, Engen, Erikstad, Hanssen and Lorentsen2015)

⁸ New York State Department of Environmental Conservation; unpubl. data

⁹ Lorentsen (Reference Lorentsen, Gjershaug, Thingstad, Eldøy and Byrkjeland1994)

¹⁰ Guzzwell et al. (Reference Guzzwell, Wilhelm and Gjerdrum2015)

¹¹ Hario and Rintala (Reference Hario and Rintala2016)

¹² Massachusetts Division of Fisheries and Wildlife; unpubl. data

¹³ Mittelhauser et al. (Reference Mittelhauser, Allen, Chalfant, Schauffler and Welch2016)

¹⁴ Nager and O’Hanlon (Reference Nager and O’Hanlon2016)

¹⁵ North Carolina Wildlife Resources Commission; unpubl. data

¹⁶ Ronconi et al. (Reference Ronconi, Stephens, Crysler, Pollet, Fife, Horn and Taylor2016)

¹⁷ Watts et al. (Reference Watts, Paxton, Boettcher and Wilke2019)

¹⁸ Watts et al. (Reference Watts, Byrd, Watts and Byrd1998)

¹⁹ Rail (Reference Rail2018)

²⁰ Washburn et al. (Reference Washburn, Elbin and Davis2016)

²¹ Chapdelaine and Brousseau (Reference Chapdelaine and Brousseau1991)

²² These population estimates were calculated as 10% of the global population in 1985. See “Data analysis” section.

²³ CWS unpubl. data (Wilhelm)

²⁴ Cotter et al. (Reference Cotter, Rail, Boyne, Robertson, Weseloh and Chaulk2012)

²⁵ Lock (Reference Lock2003)

²⁶ Regular et al. (Reference Regular, Wilhelm, Gjerdrum, Boyne and Robertson2015)

²⁷ Boyne et al. (Reference Boyne, Toms and McKnight2006).

The geographical resolution of population counts varied across the species’ range. Country-level counts were available for Europe, whereas for the United States and Canada counts were generally available at a higher resolution (state or region; Table 1). Population estimates were collected using a variety of methods of different accuracy. Methods of higher accuracy included individual counts carried out at ground level, as well as boat and aerial surveys of breeding individuals. Methods of lower accuracy were typically linked to some European countries, where the data had already been classed by BirdLife International as “based on extrapolation from a subset of colonies” or “based on expert opinion” (see references from Table 1 for sources).

Selection of counts and uncertainty

Generation length, defined as “the average age of parents of the current cohort”, is used in conservation for assessing extinction risk. The IUCN Red List criteria contrast changes in population size over the most recent three-generation period of a species to quantitatively assign each species to an extinction risk category (IUCN 2012). Generation length in Great Black-backed Gulls has been estimated as 12 years (Bird et al. Reference Bird, Martin, Akçakaya, Gilroy, Burfield, Garnett, Symes, Taylor, Şekercioğlu and Butchart2020, IUCN 2022), so we estimated changes in Great Black-backed Gull abundance from 1985 to 2021 (36 years).

Because population counts were available at different geographical scales (country, state, regions), the term “population” is used hereafter to represent any geographical scale for which there was an individual set of counts (i.e. each input to the analysis presented in Table 1). We chose to use two counts per population, as this was the common denominator for all populations. As we were interested in presenting the overall change in abundance over the three-generation period rather than changes in abundance at a higher temporal resolution, the two counts closest to the beginning and end of the study period (1985 and 2021, respectively) were chosen for populations where more than two counts were available. This ensured consistency and the highest degree of accuracy in the analysis (see Data Analysis, below).

Each population count was allocated an estimate of uncertainty based on the method used to produce the count. This was done according to a five-point scale (Croxall and Kirkwood Reference Croxall and Kirkwood1979, Lynch et al. Reference Lynch, Ratcliffe, Passmore, Foster and Trathan2013) ranging from low uncertainty (N1) to high uncertainty (N5). We redefined the N5 category from Lynch et al. (Reference Lynch, Ratcliffe, Passmore, Foster and Trathan2013) to account for a potential margin of error of up to 100% in some instances as we were confident no population estimate would be erroneous by more than twice its size (Table 2). For data from the USA, Canada, and some European countries, where raw population counts were available from count coordinators or published literature, error categories were either assigned by the count coordinators themselves or selected based on the methodology detailed in the literature. Counts from the remaining 12 European countries were obtained from BirdLife International European Red List species factsheets (2021). These data had already been allocated an accuracy/quality classification by BirdLife International according to their own criteria. We therefore translated these classifications into our study’s error categories using a conservative approach whereby the highest possible degree of accuracy issued by BirdLife International (“Good - Based on reliable and complete or representative quantitative data”) was allocated to the third error category in this study (“N3- Estimate of nests with an accuracy of 10–25%”) (see Table 2 for conversion criteria). Such a conservative approach was taken to limit the potential to overestimate the accuracy of population trend estimates calculated from BirdLife International data.

Table 2. Error categories, BirdLife International criteria conversion, and the descriptions used to classify population counts in terms of uncertainty.

Data analysis

All analyses were carried out in R version 4.0.4 (R Core Team 2020). A stochastic simulation was conducted for each population, which allowed us to account for the error associated with each population count to present confidence intervals around the estimated changes in population size. Random draws from the simulation provided two “estimated” counts per population, which were then used to calculate the finite rate of change of the population.

Simulation parameters were adapted from Lynch et al. (Reference Lynch, Ratcliffe, Passmore, Foster and Trathan2013) to fit our data in the following way: A fractional error (representing the uncertainty of the count) was randomly sampled from a uniform distribution defined by the error category associated with each population count.

(Equation 1) $$ {\displaystyle \begin{array}{l}\left(\mathrm{N}1\right)E\sim Unif\;\left(0.00,0.05\right)\\ {}\left(\mathrm{N}2\right)E\sim Unif\;\left(0.05,0.10\right)\\ {}\left(\mathrm{N}3\right)E\sim Unif\;\left(0.10,0.25\right)\\ {}\left(\mathrm{N}4\right)E\sim Unif\;\left(0.25,0.50\right)\\ {}\left(\mathrm{N}5\right)E\sim Unif\;\left(0.50,1.00\right)\end{array}} $$

1. 1. An estimated population count $ (\hat{n} $ ) was randomly sampled from a truncated normal distribution limited at 0 in the lower tail to avoid sampling negative population counts. This truncated normal distribution was defined by the original population count $ (n) $ and the randomly sampled error (E) from the previous step.

   (Equation 2) $$ \hat{n}\sim N\left(n,{\left[\frac{E}{2}n\right]}^2\right) $$

2. 2. Equations 1 and 2 were bootstrapped 50,000 times for the two counts from each population. Using the estimated population counts in each year, we calculated the finite rate of population change (λ):

(Equation 3) $$ \lambda ={\left(\frac{{\hat{n}}_2}{{\hat{n}}_1}\right)}^{\frac{1}{Year2- Year1}} $$

where Year1 was the year of the first population estimate (n₁), and Year2 was the year of the most recent estimate $ (n $ ₂).

1. 3. Lastly, the estimated population sizes in 1985 and 2021 were calculated as follows:

   1. a. The time gaps between $ n $ ₁ and 1985, and $ n $ ₂ and 2021 were calculated:

      (Equation 4) $$ {Gap}_1= Year1-1985 $$
      (Equation 5) $$ {Gap}_2\hskip0.35em =\hskip0.35em 2021- Year2 $$

   2. b. Once the time gaps had been obtained, the fractional change (Change₁ and Change₂) in population size between $ {\hat{n}}_1 $ and 1985 and $ {\hat{n}}_2 $ and 2021 was then calculated as follows:

      (Equation 6) $$ {Change}_1\hskip0.35em =\hskip0.35em {\lambda}^{Gap_1} $$
      (Equation 7) $$ {Change}_2\hskip0.35em =\hskip0.35em {\lambda}^{Gap_2} $$

   3. c. Lastly, the 1985 start (StartPopulation1985) and the 2021 end populations (EndPopulation2021) were calculated, as well as the fractional change in population size over the three-generation period (3GenPeriod):

   (Equation 8) $$ StartPopulation1985\hskip0.35em =\hskip0.35em \frac{{\hat{n}}_1}{Change1} $$
   (Equation 9) $$ EndPopulation2021\hskip0.35em =\hskip0.35em {\hat{n}}_2\times Change2 $$
   (Equation 10) $$ 3 GenPeriod\hskip0.35em =\hskip0.35em \frac{\left( End\ Population\hskip0.35em 2021- Start\ Population\hskip0.35em 1985\right)}{StartPopulation1985} $$

2. 4. Equations 3 to 10 were repeated for each of the 50,000 bootstrapped population estimates to obtain distributions of estimates for each population for 1985 and 2021.

Due to the large uncertainty associated with the counts of some European countries and the need to use a normal distribution with a truncated lower limit of 0, the resulting distributions for some regions were marginally non-normal. To stop extreme, positive outliers from heavily influencing the mean statistics, counts outside the 2.5% and 97.5% quantiles were excluded in figures involving European data, which resulted in normal distributions.

There were populations for which no trend data were available (unsurveyed populations). These were: 27% of the Quebec population (Canada), approximately 40% of the New York population (USA), and the entirety of Delaware (USA). These figures accounted for <10% of our 1985 global population estimate. Two scenarios were used to include these figures in the analysis. The first approach (Scenario A) was conservative and assumed these populations had remained stable over the three-generation period. The second approach (Scenario B), likely more realistic, assumed unsurveyed populations declined at the same rate as the global average of the surveyed populations (Table 1). Mean statistics for global and continental estimates were calculated from the sum of every iteration from all populations that fell within that geographical area. Unsurveyed populations were only included in global estimates and were excluded from continental, national, and regional estimates. Finally, we compared overall population changes over three generations to IUCN Red List criterion A2, defined as “Population reduction observed, estimated, inferred, or suspected in the past where the causes of reduction may not have ceased OR may not be understood OR may not be reversible” (IUCN 2012). We did not apply criterion A1 because the causes of decline were not known, did not appear to have ceased, and were not reversible (see “Discussion” section). We also did not apply criterion A3 because we did not project populations into the future. Lastly, we did not apply criterion A4 because we used two count estimates per population and therefore a “moving window” scenario would not yield any additional decline estimates. Because we had population trend data for virtually the entire range (90% of the global population), we assumed that population trends appropriately reflected the global population.