Hostname: page-component-cd9895bd7-jn8rn Total loading time: 0 Render date: 2024-12-26T22:09:02.990Z Has data issue: false hasContentIssue false

Habitat use by mixed-species bird flocks in tropical forests of the Western Ghats, India

Published online by Cambridge University Press:  30 August 2022

Priyanka Hariharan*
Affiliation:
Pondicherry University, Pondicherry, India Department of Wildlife Ecology and Conservation, University of Florida, Gainesville, FL, USA School of Natural Resources and Environment, University of Florida, Gainesville, FL, USA
Priti Bangal
Affiliation:
Nature Conservation Foundation, Mysuru, Karnataka, India Centre for Ecological Sciences, Indian Institute of Science, Bengaluru, Karnataka, India
Hari Sridhar
Affiliation:
Centre for Ecological Sciences, Indian Institute of Science, Bengaluru, Karnataka, India National Centre for Biological Sciences, Bengaluru, Karnataka, India
Kartik Shanker
Affiliation:
Centre for Ecological Sciences, Indian Institute of Science, Bengaluru, Karnataka, India
*
Author for correspondence: Priyanka Hariharan, Email: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

While mixed-species flocks of birds (hereafter ‘flocks’) have been widely studied, few studies have looked at the effect of habitat structure on flock presence and flocking propensity within a site. Here, we employ a use-availability approach in locations with flocks and random locations to ask whether habitat characteristics influence the presence of flocks, and whether structurally similar microhabitats support compositionally similar flocks. We also examine the effect of habitat on flock size and species richness, and the effect of intraspecifically gregarious flock participants on habitat selection. We find that flocks use a narrow subset of available tree density and canopy cover variation and prefer relatively less-dense areas with large trees and a complex foliage structure. Similar microhabitats do not result in compositionally similar flocks, and while foliage complexity was associated with flock size, no habitat characteristics influenced species richness. Flocks led by the intraspecifically gregarious western crowned warbler (Phylloscopus occipitalis), a potential nuclear species, showed preference for high foliage complexity and tree density. Thus, habitat preferences of intraspecifically gregarious species, which are followed by other species, could play a strong role in habitat selection in flocks. This suggests that degraded forests that cannot provide a suitable range of tree density, canopy cover, and/or complex vegetation structure may not support some core flock species around which flocks form, which may lead to decreased flocking in those patches.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2022. Published by Cambridge University Press

Introduction

Mixed-species flocks (hereafter ‘flocks’) of birds have been studied in many parts of the world, and have been particularly well-studied in forest habitats. Flocks show wide variation in size, species composition, and duration of association, and participants are believed to derive benefits from one another while moving together through their habitat (Greenberg Reference Greenberg, Boinski and Garber2000). These roving groups offer participants protection from predation both in terms of group-size related advantages (confusion, dilution and ‘many-eyes’ effects, see Foster & Treherne Reference Foster and Treherne1981, Neill & Cullen Reference Neill and Cullen1974, Pulliam Reference Pulliam1973) as well as more species-specific benefits (such as the alarm-calling behaviour of sentinel species and reduced vigilance in other species, and the flushing of insect prey by species, see Goodale & Kotagama Reference Goodale and Kotagama2005, Greenberg Reference Greenberg, Boinski and Garber2000, Sridhar et al. Reference Sridhar, Jordán and Shanker2013). Intraspecifically gregarious species are often nuclear species in flocks (Greenberg Reference Greenberg, Boinski and Garber2000), and larger flocks may only be found when these species are present (Sridhar & Shanker Reference Sridhar and Shanker2014). Nuclear species are present in most flocks (Goodale & Beauchamp Reference Goodale and Beauchamp2010), and they are functionally important within mixed-species flock systems (Goodale & Beauchamp Reference Goodale and Beauchamp2010, Hutto Reference Hutto1994, Sridhar et al. Reference Sridhar, Beauchamp and Shanker2009). They have well-developed alarm call systems (Koenig & Dickinson Reference Koenig and Dickinson2004), and when present, are flock leaders, potentially affecting habitat selection for other species (Mammides et al. Reference Mammides, Chen, Goodale, Kotagama, Sidhu and Goodale2015, Williams & Lindell Reference Williams and Lindell2019) and playing a role in setting the direction of flock movement (Greenberg Reference Greenberg, Boinski and Garber2000).

As a result of flocking, participants may be able to spend less time and energy on vigilance, making available more time for foraging (Sridhar et al. Reference Sridhar, Beauchamp and Shanker2009). For example, sallying species are more vigilant than species that employ more active foraging methods, and their alarm calls may provide warning of approaching predators (Goodale & Kotagama Reference Goodale and Kotagama2005), thereby allowing other flock members to invest more time in foraging (Radford et al. Reference Radford, Bell, Hollén and Ridley2011). Additionally, sallying species may benefit from capturing prey that are flushed out by species with more active foraging techniques (Satischandra et al. Reference Satischandra, Kudavidanage, Kotagama and Goodale2007), and there is some evidence that individuals may observe the locations in which other participants forage and revisit/avoid the same (Beauchamp & Benton Reference Beauchamp and Benton2005, Krebs Reference Krebs1973).

Both predator detection and foraging efficiency are influenced by habitat structure. In dense habitats, flocks are well concealed, and a closed canopy and high tree density limit exposure to predators (Thiollay Reference Thiollay1999b). However, in such habitats, ambush predators, the primary threat to these smaller insectivores, are also better hidden. On the other hand, in open habitats, flock participants can scan their surroundings more effectively for predators (Thiollay Reference Thiollay1999b, Zou et al. Reference Zou, Jones, Colorado, Jiang, Lee, Martínez, Sieving, Zhang, Zhang and Goodale2018, but see Linley et al. Reference Linley, Guay and Weston2019). Changes in habitat structure could alter species’ propensity to flock (especially in the case of habitat degradation, when core flock species are absent or less abundant in degraded sites and flocks form less frequently) (Mokross et al. Reference Mokross, Ryder, Côrtes, Wolfe and Stouffer2014, Zhang et al. Reference Zhang, Han, Huang and Zou2013, Zou et al. Reference Zou, Jones, Colorado, Jiang, Lee, Martínez, Sieving, Zhang, Zhang and Goodale2018), but may also indirectly affect flocks by altering prey dispersion and availability, and predation pressure (Martínez et al. Reference Martínez, Parra, Collado and Vredenburg2017, Reference Martínez, Parra, Muellerklein and Vredenburg2018, Ridley et al. Reference Ridley, Wiley and Thompson2014, Sridhar & Sankar Reference Sridhar and Sankar2008). Past research has shown that insectivorous birds are more likely to forage in mixed-species flocks in areas with less protective vegetation (Radford et al. Reference Radford, Bell, Hollén and Ridley2011, Tubelis et al. Reference Tubelis, Cowling and Donnelly2006), and individuals participate in mixed-species flocks less often in dense forests (Jullien & Thiollay Reference Jullien and Thiollay1998, Thiollay Reference Thiollay1999b).

The high species richness of flocks in mature forests is associated with a complex habitat structure, and even small changes in the structural complexity of secondary and early successional forests could have a positive effect on the species richness and abundance of flocks (Zuluaga & Rodewald Reference Zuluaga and Rodewald2015). In degraded habitats, habitat structure may also affect flock composition and size, wherein the overall flocking propensity of insectivorous birds decreases when the canopy is more open as a result of logging gaps and tracks (Thiollay Reference Thiollay1999b). Species that participate in flocks have varying morphologies and preferences in foraging strategies and strata in their habitat (Kotagama & Goodale Reference Kotagama and Goodale2004, Morse Reference Morse1970, Robin & Davidar Reference Robin and Davidar2002), and the lack of a complex forest structure could mean that flocks do not contain certain species, even if they remain present in the habitat (Zou et al. Reference Zou, Jones, Colorado, Jiang, Lee, Martínez, Sieving, Zhang, Zhang and Goodale2018). For example, understory flock participants could have specialised strategies to forage in dim-light conditions of the forest interior, and these strategies may not be suitable in disturbed or open forest patches (Thiollay Reference Thiollay1992). Reduced prey availability can have an effect on flocks (Thiollay Reference Thiollay1999a, Reference Thiollay1992), and vegetation structure could influence flock participation by affecting prey availability (Develey & Peres Reference Develey and Peres2000).

Despite the fact that a majority of the insectivorous species found in tropical forests participate in flocks (King & Rappole Reference King and Rappole2001, Sridhar & Sankar Reference Sridhar and Sankar2008, Zou et al. Reference Zou, Jones, Colorado, Jiang, Lee, Martínez, Sieving, Zhang, Zhang and Goodale2018), there has been little research on the influence of habitat structure on flock presence and flocking propensity of species within sites. Flock size has been shown to be strongly associated with habitat structure and area of fragmented forest (Sridhar & Sankar Reference Sridhar and Sankar2008). Logging can result in species joining flocks less frequently (Thiollay Reference Thiollay1999b), and affect interspecific associations in flocks by altering predation pressure and resource availability (Borah et al. Reference Borah, Quader and Srinivasan2018). Some species become locally extinct in small fragments (Stratford & Stouffer Reference Stratford and Stouffer1999), and if these are nuclear species, flock composition may be indirectly affected by changes in other species’ propensity to flock (Cordeiro et al. Reference Cordeiro, Borghesio, Joho, Monoski, Mkongewa and Dampf2015, Mammides et al. Reference Mammides, Chen, Goodale, Kotagama, Sidhu and Goodale2015).

Habitat heterogeneity is an important factor in maintaining flock richness, and a simplified habitat structure brought about by anthropogenic disturbance could cause a decline in flocking (Lee et al. Reference Lee, Soh, Sodhi, Koh and Lim2005, Zhang et al. Reference Zhang, Han, Huang and Zou2013, Zhou et al. Reference Zhou, Peabotuwage, Gu, Jiang, Hu, Jiang, Mammides, Zhang, Quan and Goodale2019). While there have been studies on the effects of habitat degradation and fragmentation at the landscape level (Borah et al. Reference Borah, Quader and Srinivasan2018, Sridhar & Sankar Reference Sridhar and Sankar2008), little is known about how flock characteristics are affected by habitat structure within the relative homogeneity of a single forest site. Hence, we examined within-site variation in habitat structure to explore changes in flock composition and structure. We also examined whether flock habitat use might reflect habitat choice of the most commonly occurring intraspecifically gregarious species – brown-cheeked fulvetta (Alcippe poioicephala), orange minivet (Pericrocotus flammeus), and western crowned warbler (Phylloscopus occipitalis) – one or more of which are usually found leading flocks in the Western Ghats (Sridhar et al. Reference Sridhar, Jordán and Shanker2013).

First, we used a habitat use-availability approach in locations where flocks were encountered and random locations to test whether specific habitat characteristics influence the presence of flocks. We then asked whether structurally similar microhabitats support flocks with similar species composition and tested whether these habitat characteristics might have an effect on flock size and richness. Finally, we examined the effect of the presence of intraspecifically gregarious species on habitat selection.

Methods

Flock sampling

Fieldwork was carried out in the Anshi Range of Kali Tiger Reserve (formerly Anshi-Dandeli Tiger Reserve, 15°00′97.8″N, 74°38′72.2″E) in the Western Ghats (Figure 1), a 1500 km mountain range that runs north to south along the western coast of peninsular India. Data were collected from the evergreen forest site from December 2017 to March 2018, which corresponds to the non-breeding season for the bird species studied. Ten trails (Figure 1), ranging from 1.8 – to 5 km in length, were walked 3 to 9 times to observe mixed-species flocks, within a limit of 30 m on either side of a trail. All trails used for sampling were around Anshi village (14°59'33.0713''N, 74°22'3.2358''E) and Anshi nature camp (15°0'34.0693''N, 74°23'4.551''E).

Figure 1. Location of Kali Tiger Reserve in the Western Ghats (inset) and trails (brown lines) around Anshi village (blue triange) and Anshi nature camp (yellow circle).

Data were collected from 8h to 14h by PH. A group of birds was considered to be a flock if it comprised two or more species that stayed together for at least five minutes and moved in the same direction (Sridhar et al. Reference Sridhar, Jordán and Shanker2013). Each species observed also had to be within 10 m of at least one other individual belonging to a different species to qualify as a flock participant. The five-minute cut-off ensured that random associations of birds were not considered mixed-species flocks. Each flock was observed only until all species were identified, to obtain a ‘snapshot’ of the flock and to reduce the possibility of species turnover. Prior to the start of the study, PH, PB, and HS had observed flocks in this area and determined that it would take around 15 minutes to identify the majority of participating species in flocks. Frugivorous species of birds were not considered to constitute a mixed-species flock, as they are likely to have been feeding aggregations (Greenberg Reference Greenberg, Boinski and Garber2000). Hence, observations were restricted to insectivorous species only. It is possible that some individuals were observed in multiple flocks, but since they were part of flocks with different compositions, such repetitions were considered valid for the purpose of the study.

A total of 72 flocks were recorded over the study period, with species composition and abundance being noted in each case. When it was not possible to identify the exact number of individuals of a species, an appropriate size class of abundances (1–5, 5–10, 10–15, 15–20, 20–25) was assigned. Birds were identified using calls as well as sightings.

Habitat structure sampling

Since flocks were observed only long enough to get a snapshot of the participating species, it was possible to assign a central location for each flock. This was considered the ‘flock location’ and was roughly the centre of where most participants were foraging. In addition to flock data, the following habitat variables were measured in each of the flock locations: density and basal area of trees (with girth at breast height (gbh) more than 30 cm), density of plants above 2 m in height but less than 30 cm gbh (hereafter, plants), percentage cover of plants under 1 m in height (hereafter, saplings), canopy cover, and foliage complexity.

Density and basal area of trees was calculated by using the point-centered quarter (PCQ) method (Hill et al. Reference Hill, Fasham, Tucker, Shewry and Shaw2005), wherein gbh (in cm) and distances (in m) of the four closest trees from a central point were noted. Plants were counted in a 5 × 5 m plot. Sapling cover was estimated in a 1 × 1 m plot. Foliage complexity was estimated by imagining a cylinder of radius 0.5 m around the observer in the centre of the PCQ plot and noting the presence or absence of foliage in the following size classes (in m, aboveground): 0-1, 1-2, 2-4, 4-8, 8-16, 16-32, >32 (Sridhar & Sankar Reference Sridhar and Sankar2008). A rangefinder was used to ensure that the height of foliage was measured accurately. Following Daniels et al. (Reference Daniels, Joshi and Gadgil1992), canopy cover was assigned one of four ranks: 1 (no canopy overhead), 2 (canopies barely touch), 3 (there is overlap of canopies, but the sky is still visible) or 4 (complete overlap, no sky visible).

Each trail where sampling for flocks was carried out was mapped on QGIS. The fixed distance buffer tool was used to draw a polygon around these trails, with a 30 m belt on each side of the trails. Random points were generated inside these polygons to represent available habitat. A total of 149 random points (approximately twice the number of use locations observed) was generated on ten trails, with 10 to 16 points occurring on each trail. Nineteen of these points occurred in fields, villages or water bodies and were not considered to be representative of available habitat for flocks. The remaining 130 random locations were visited (with an accuracy of 2 m), and measurements of all the habitat variables detailed above were taken.

Statistical analysis

Analysis was primarily carried out in R (R Core Team 2018). Density of trees was calculated using the formula density = 1/Dm2 where ‘Dm’ is the mean of distances from a central point to each tree (Hill et al. Reference Hill, Fasham, Tucker, Shewry and Shaw2005). Plant and sapling cover were assigned to size classes. Basal area was calculated using π(d/2)2 where ‘d’ is the diameter of trees at breast height. To obtain a measure of basal area with respect to the PCQ data, the average basal area at each flock location/random location was multiplied by the density of trees (JoVE Science Education Database 2018). Each flock location and random point was assigned a score for foliage complexity by summing up the number of classes in which foliage was present. We used a combination of multivariate and univariate statistics to test our three objectives, as appropriate.

For the first objective, we carried out 10,000 iterations of 72 randomly selected points out of 130 random availability points and calculating the means and standard deviations of each of the six habitat variables. Habitat variables were not highly correlated (Spearman’s correlation ≤  ± 0.5). The distributions of the bootstrapped standard deviations and means were compared to those of the use sites, one variable at a time. Following this, a binomial generalized linear model (GLM) was run to determine whether use sites (the response variable) were characterised by a combination of the predictor variables (Beyer et al. Reference Beyer, Haydon, Morales, Frair, Hebblewhite, Mitchell and Matthiopoulos2010, Edwards et al. Reference Edwards, Loeb, Guynn, Steele, Merritt and Zegers1994, Keating and Cherry Reference Keating and Cherry2004).

For the second objective, namely to examine similarities between habitat variables of the use sites and flock composition, we used the Bray–Curtis dissimilarity index from the ‘vegan’ package in R. Based on this, the data were transformed into distance matrices, and a Mantel test was carried out with 999 permutations, to understand whether similarities in flock composition corresponded to similarities in habitat structure of the use sites, and assess the statistical significance of the regression coefficients. We also carried out a Poisson GLM with habitat structure variables as predictors, and flock size and species richness as response variables.

For the final objective, the habitat structure of flocks with and without particular intraspecifically gregarious species was compared with a Mann-Whitney U test, one variable at a time. This was done to see if flocks differed in habitat use based on the presence or absence of a particular gregarious species.

Results

Forty-four species were observed across 72 flocks, with an average of 5.43 (±2.41 SD) species and 17.6 (±8.77 SD) individuals in each. Seventy-two flock locations constituted ‘use’ points. The 130 randomly generated points were considered ‘availability’ points.

Species composition of flocks broadly corresponded with earlier studies (Sridhar et al. Reference Sridhar, Jordán and Shanker2013) in the same site. Core species included the black-naped monarch (Hypothymis azurea) which was found in 41 flocks (57%), the brown-cheeked fulvetta (Alcippe poioicephala) in 35 (49%), the greater racket-tailed drongo (Dicrurus paradiseus) in 36 (50%), the orange minivet (Pericrocotus flammeus) in 29 (40%), the western crowned warbler (Phylloscopus occipitalis) in 45 (63%) and the yellow-browed bulbul (Acritillas indica) in 28 (39%).

Use and availability

In order to compare both the means and standard deviations of use sites and the distributions of bootstrapped availability sites for the first objective, we carried out univariate comparisons for the six predictor variables (Figures 3 and 4). The means of basal area (Figure 2b) and foliage complexity (Figure 2f) were significantly higher in the use sites (bootstrapped CI 95%). Use site mean tree density was lower than that of availability sites (Figure 2a). When the same analysis was carried out for the bootstrapped standard deviations to determine whether use sites formed a narrow subset of availability sites (Figure 3), use site tree density (Figure 3a) had a significantly lower standard deviation than availability sites (bootstrapped CI 95%). Canopy cover (Figure 3e) also differed, with use sites having a lower standard deviation than availability sites.

Figure 2. Distribution of bootstrapped means of availability (green) and use (purple) for (a) density of trees (per m2), (b) basal area (cm2 per sq. m), (c) plant cover (count), (d) sapling cover (percentage cover), (e) canopy cover (score) and (f) foliage complexity (score).

Figure 3. Distribution of bootstrapped standard deviations of availability (green) and use (purple) for (a) density of trees (per m2), (b) basal area (cm2 per sq. m), (c) plant cover (count), (d) sapling cover (percentage cover), (e) canopy cover (score) and (f) foliage complexity (score).

Figure 4. (a) Density of trees and (b) foliage complexity in all use sites, sites with flocks in which warblers were absent, and sites with flocks in which warblers were present. **indicates p < 0.01 and *indicates p < 0.5.

The GLM (r2 = 0.2) showed that tree density was slightly, but significantly lower (p = 0.047) in use sites (mean = 0.08 per m2, SE = 0.007) compared to use sites (mean = 0.07 per m2, SE = 0.007). While there was some variation in foliage complexity, this was not statistically significant (p < 0.1). Other habitat variables did not differ significantly between use and availability sites (Table S1).

Species composition, flock size and species richness

The dissimilarity matrices of habitat structure and flock composition had no zeros, indicating that sites were at least somewhat similar in habitat structure and flock composition, and were not significantly correlated to each other (Mantel’s r = −0.2, p = 0.67). The GLM of habitat structure variables and flock size (r2 = 0.2) showed that foliage complexity was significantly associated with the number of individual birds in flocks (p < 0.01), and slightly associated with plant density (p < 0.1). The GLM of habitat structure variables and flock species richness (r2 = 0.2) did not reveal any significant patterns (Table S2).

Gregarious species and habitat selection

Three intra-specifically gregarious species were found in at least 40% of flocks that were observed: western crowned warbler (hereafter ‘warbler’), brown-cheeked fulvetta (hereafter ‘fulvetta’) and orange minivet (hereafter ‘minivet’). While other gregarious species were present, they were not as frequently encountered as these three and were not considered for further analysis.

Western crowned warbler was found in 63% of all flocks, and was the only gregarious species and leader in 15 flocks. Density of trees (Mann-Whitney U = 836, p < 0.01) and foliage complexity (U = 781, p = 0.03) were significantly higher in use sites in which warblers were present compared to use sites in which warblers were absent (n = 27) (Table S3). The mean tree density value of flocks with warblers (0.08) was slightly higher than that of use sites (0.07), while flocks without warblers had a lower mean density of 0.05 (Figure 4a). The mean use site foliage complexity was between that of flocks with and without warblers (Figure 4b).

The fulvetta was a participant in 49% of all observed flocks, and in seven flocks, this was the only gregarious species. When these sites were compared to 37 use sites in which they were absent, none of the habitat characteristics tested were significantly different (Table S3). Similarly, the minivet, which was found in 40% of all flocks, was the only gregarious species in six flocks. When these use sites were compared to 43 sites in which minivets were absent, there were no significant differences (Table S3).

Foliage complexity of use sites in which warblers were the only gregarious species (n = 15, mean = 5) was somewhat higher than that of use sites with only fulvettas as the gregarious species (n = 7, mean = 3.71), but this difference was marginally non-significant (Mann-Whitney U = 78.5, p = 0.06). In comparison, the average foliage complexity of all use sites was 4.39 (±1.32 SD).

Discussion

In this study, we aimed to examine habitat selection of mixed-species flocks within a single site in the Western Ghats of India. We directly compared use and availability sites and also assessed the effect of habitat structure variables on flock composition, size, and richness. Finally, we examined flocks that were led by different gregarious species.

Mixed-species flocks are one among many groups of animals to show habitat selection, with many mammal and bird species across different taxonomic groups preferentially selecting habitat for a variety of reasons (Jain & Balakrishnan Reference Jain and Balakrishnan2011, Liu et al. Reference Liu, Toxopeus, Skidmore, Shao, Dang, Wang and Prins2005, McLoughlin et al. Reference McLoughlin, Walton, Cluff, Paquet and Ramsay2004, Morales et al. Reference Morales, Traba, Carriles, Delgado and De la Morena2008). Insects show strong selection for microhabitats within forested habitats (Jain & Balakrishnan Reference Jain and Balakrishnan2011) where species may be specialised to forage. Mammal habitat selection can vary seasonally (Liu et al. Reference Liu, Toxopeus, Skidmore, Shao, Dang, Wang and Prins2005), and their selection may also be limited by the availability of resources such as denning sites (McLoughlin et al. Reference McLoughlin, Walton, Cluff, Paquet and Ramsay2004). Such habitat selection is not restricted to a single species at a time — in the case of terrestrial mixed-species bird flocks, past work has shown that participating species move through edge-dominated habitats and interior forest habitats at different speeds, with movement slowing in the former, perhaps because food availability is higher in such habitats (Rodewald & Brittingham Reference Rodewald and Brittingham2002).

In our study site, ‘use’ sites showed relatively lower variability in tree density and canopy cover, suggesting that flocks form in a narrow subset of available tree density and canopy cover variation. Flock presence was associated with relatively less dense microhabitats, indicated by low mean tree density of use sites, and with a complex, heterogenous foliage structure with large trees, indicated by the high mean basal area of use sites. This is consistent with other findings in which mixed-species flocks have been found to prefer structurally complex forests (Lee et al. Reference Lee, Soh, Sodhi, Koh and Lim2005, Zhang et al. Reference Zhang, Han, Huang and Zou2013), and insectivorous species were less likely to participate in flocks in densely forested areas (Jullien & Thiollay Reference Jullien and Thiollay1998, Thiollay Reference Thiollay1999b, Tubelis et al. Reference Tubelis, Cowling and Donnelly2006). Degraded forests are often characterised by an open canopy and reduced density of mature trees, and our study suggests that such homogenous reduction in these habitat variables do not provide a suitable habitat for mixed-species flocks. Considering that many nuclear species participating in flocks are forest-specialists particularly sensitive to disturbance, it is unlikely that flocks led by these species will be found in significantly human-modified landscapes.

Overall habitat use by flocks could be strongly influenced by gregarious species’ preferences. Williams and Lindell (Reference Williams and Lindell2019), for example, found that greater racket-tailed drongos might lead flocks to forage in relatively less densely vegetated areas. In our study, we encountered flocks led by western crowned warblers in particularly complex microhabitats with a high average tree density. When this gregarious species was not present and other species such as the brown-cheeked fulvetta and the orange minivet led flocks, flocks foraged in less dense habitats. If gregarious species do have strong habitat preferences, given their role as nuclear species, it is likely that flock habitat choice might reflect gregarious species habitat choice and influence where other species forage. Just as there are costs of activity matching in mixed-species bird flocks (Hutto Reference Hutto1988), there may also be costs associated with such microhabitat matching, which merits further investigation.

Species that are important in mixed-species flocks, such as gregarious nuclear species, create opportunities in terms of new ecological niches for other birds which flock with them (Harrison & Whitehouse Reference Harrison and Whitehouse2011). If such species had specific preferences within forests, then the loss of these conditions could lead to a reduction in the number of nuclear species, which could lead to compromised foraging niches that the flock creates. This may in turn lead to reduced flock participation of other species in the area. Since participating in flocks is known to have an effect on fecundity and survival (Goodale et al. Reference Goodale, Ding, Liu, Martínez, Si, Walters and Robinson2015, Jullien & Clobert Reference Jullien and Clobert2010), reduced flocking could adversely affect obligate flock participants that rely on flocks to forage. Degraded forests, with their simplified vegetation structure, may be particularly vulnerable to the loss of mixed-species flocks, and studying the response of these complex social organisation structures to any subsequent restoration or succession in such habitats would provide us with a better understanding of tropical bird communities (Kotagama & Goodale Reference Kotagama and Goodale2004). Several species that participate in mixed-species flocks in the Western Ghats are long-distance migrants (such as the greenish warbler and western crowned warbler) or endemic species (such as the white-bellied blue flycatcher), and studying their response to habitat change in the context of the larger bird community in this biodiverse region would be particularly valuable (Zhang et al. Reference Zhang, Han, Huang and Zou2013).

One of the caveats of our study is that the relatively small sample size of 72 flocks could have prevented the detection of significant differences in habitat variables between use and availability sites. Our availability sites were also not ‘absence’ sites, and it is possible that flocks could have used these sites during the field season. The small sample size could have also resulted in limited variation in terms of the species composition and richness, which could explain why we were unable to detect any effect of habitat variables on these flock characteristics. While we did find that foliage complexity played a significant role in the size of flocks, we interpret these results cautiously as the 72 flocks we observed consisted of an average of 18 individuals, and 36 flocks (50%) had 10 – 20 individuals. Moreover, other characteristics that were not measured as part of this study could have also played a role in birds selecting some microhabitats over others. For example, prey abundance and distances from edges of various kinds (clearings, streams, trails, roads, fields and villages) may influence habitat selection (Cuttriss et al. Reference Cuttriss, Maguire, Ehmke and Weston2015). The measurement of these variables was beyond the scope of this study. In the future, it would also be interesting to see how flock characteristics, especially species richness and composition, vary with changes in microhabitat structure, perhaps in a site with greater heterogeneity.

In conclusion, we find that flocks in the Western Ghats may be selectively foraging in the habitat available to them, even within a single seemingly homogenous site. Understanding the habitat preferences of mixed-species flocks is crucial to identifying conditions that are important for the survival of several tropical bird species, many of which are obligate flock participants. Furthermore, intraspecifically gregarious species may have a particularly important role to play in the selection of habitat within sites, and studying their specific habitat requirements may help identify broader patterns of habitat use in flocks as well.

Supplementary material

To view supplementary material for this article, please visit https://doi.org/10.1017/S026646742200030X

Acknowledgements

The authors thank the Karnataka Forest Department for providing permits for field work. PH thanks field assistants who accompanied her in Anshi, and Devica Ranade and Harish Prakash at the Indian Institute of Science who helped with various parts of the analysis.

Financial support

PH was supported by a fellowship from the Nature Conservation Foundation. HS was supported by grants from the Indian National Science Academy and National Centre for Biological Sciences. KS thanks the DBT-IISc Partnership Programme for support.

Conflict of interest

None.

References

Beauchamp, G and Benton, T (2005) Does group foraging promote efficient exploitation of resources? Oikos 111, 403407.CrossRefGoogle Scholar
Beyer, H, Haydon, D, Morales, J, Frair, JL, Hebblewhite, M, Mitchell, M and Matthiopoulos, J (2010) Habitat preference: understanding use versus availability designs. Philosophical Transactions of the Royal Society B 365, 22452254.CrossRefGoogle Scholar
Borah, B, Quader, S and Srinivasan, U (2018) Responses of interspecific associations in mixed-species bird flocks to selective logging. Journal of Applied Ecology 55, 16371646.CrossRefGoogle Scholar
Cordeiro, NJ, Borghesio, L, Joho, MP, Monoski, TJ, Mkongewa, VJ and Dampf, CJ (2015) Forest fragmentation in an African biodiversity hotspot impacts mixed-species bird flocks. Biological Conservation 188, 6171.CrossRefGoogle Scholar
Cuttriss, A, Maguire, GS, Ehmke, G and Weston, M (2015) Breeding habitat selection in an obligate beach bird: a test of the food resource hypothesis. Marine and Freshwater Research 66, 841846.CrossRefGoogle Scholar
Daniels, RJ, Joshi, NV and Gadgil, M (1992) On the relationship between bird and woody plant species diversity in the Uttara Kannada district of south India. Proceedings of the National Academy of Sciences 89, 53115315.CrossRefGoogle ScholarPubMed
Develey, PF and Peres, CA (2000) Resource seasonality and the structure of mixed species bird flocks in a coastal Atlantic forest of southeastern Brazil. Journal of Tropical Ecology 16, 3353.CrossRefGoogle Scholar
Edwards, JW, Loeb, SL and Guynn, DC (1994) Use of multiple regression and use-availability analyses in determining habitat selection by gray squirrels (Sciurus carolinensis). In Steele, MA, Merritt, JF and Zegers, DA (eds.), Ecology and Evolutionary Biology of Tree Squirrels: Proceedings of the International Colloquium on the Ecology of Tree Squirrels. Virginia Museum of Natural History, pp. 8797.Google Scholar
Foster, W and Treherne, J (1981) Evidence for the dilution effect in the selfish herd from fish predation on a marine insect. Nature 293, 466467.CrossRefGoogle Scholar
Goodale, E and Beauchamp, G (2010) The relationship between leadership and gregariousness in mixed-species bird flocks. Journal of Avian Biology 41, 99103.CrossRefGoogle Scholar
Goodale, E, Ding, P, Liu, X, Martínez, A, Si, X, Walters, M and Robinson, SK (2015) The structure of mixed-species bird flocks, and their response to anthropogenic disturbance, with special reference to East Asia. Avian Research 6, 111.CrossRefGoogle Scholar
Goodale, E and Kotagama, S (2005) Testing the roles of species in mixed-species bird flocks of a Sri Lankan rain forest. Journal of Tropical Ecology 21, 669676.CrossRefGoogle Scholar
Greenberg, R (2000) Birds of many feathers: the formation and structure of mixed flocks of forest birds. In Boinski, S and Garber, PA (eds.), On the Move: How and Why Animals Travel in Groups. Chicago: University of Chicago Press, pp. 521559.Google Scholar
Harrison, NM and Whitehouse, MJ (2011) Mixed-species flocks: an example of niche construction? Animal Behaviour 81, 675682.CrossRefGoogle Scholar
Hill, D, Fasham, M, Tucker, G, Shewry, M and Shaw, P (2005) Handbook of Biodiversity Methods: Survey, Evaluation and Monitoring. Cambridge: Cambridge University Press.CrossRefGoogle Scholar
Hutto, RL (1988) Foraging behavior patterns suggest a possible cost associated with participation in mixed-species bird flocks. Oikos 51, 7983.CrossRefGoogle Scholar
Hutto, RL (1994) The composition and social organization of mixed-species flocks in a tropical deciduous forest in Western Mexico. The Condor 96, 105118.CrossRefGoogle Scholar
Jain, M and Balakrishnan, R (2011) Microhabitat selection in an assemblage of crickets (Orthoptera: Ensifera) of a tropical evergreen forest in Southern India: microhabitat selection in crickets. Insect Conservation and Diversity 4, 152158.CrossRefGoogle Scholar
JoVE Science Education Database (2018) Tree survey: point-centered quarter sampling method. Available at https://www.jove.com/science-education/10060/tree-survey-point-centered-quarter-sampling-method.Google Scholar
Jullien, M and Clobert, J (2010) The survival value of flocking in Neotropical birds: reality or fiction? Ecology 81, 34163430.CrossRefGoogle Scholar
Jullien, M and Thiollay, J-M (1998) Multi-species territoriality and dynamic of neotropical forest understorey bird flocks. Journal of Animal Ecology 67, 227252.CrossRefGoogle Scholar
Keating, K and Cherry, S (2004) Use and interpretation of logistic regression in habitat-selection studies. Journal of Wildlife Management 68, 774789.CrossRefGoogle Scholar
King, D and Rappole, J (2001) Mixed-species bird flocks in dipterocarp forest of north central Burma (Myanmar). Ibis 143, 380390.CrossRefGoogle Scholar
Koenig, WD and Dickinson, JL (2004) Ecology and Evolution of Cooperative Breeding in Birds. Cambridge: Cambridge University Press.CrossRefGoogle Scholar
Kotagama, SW and Goodale, E (2004) The composition and spatial organisation of mixed- species flocks in a Sri Lankan rainforest. Forktail 20, 6370.Google Scholar
Krebs, J (1973) Social learning and the significance of mixed-species flocks of chickadees (Parus spp.). Canadian Journal of Zoology 51, 12751288.CrossRefGoogle Scholar
Lee, TM, Soh, MCK, Sodhi, N, Koh, LP and Lim, SL-H (2005) Effects of habitat disturbance on mixed species bird flocks in a tropical sub-montane rainforest. Biological Conservation 122, 193204.CrossRefGoogle Scholar
Linley, GD, Guay, PJ and Weston, MA (2019) Are disturbance separation distances derived from single species applicable to mixed-species shorebird flocks? Wildlife Research 46, 719723.CrossRefGoogle Scholar
Liu, X, Toxopeus, AG, Skidmore, AK, Shao, X, Dang, G, Wang, T and Prins, HHT (2005) Giant panda habitat selection in Foping Nature Reserve, China. Journal of Wildlife Management 69, 16231632.CrossRefGoogle Scholar
Mammides, C, Chen, J, Goodale, UM, Kotagama, SW, Sidhu, S and Goodale, E (2015) Does mixed-species flocking influence how birds respond to a gradient of land-use intensity? Proceedings of the Royal Society B: Biological Sciences 282, 20151118.CrossRefGoogle ScholarPubMed
Martínez, AE, Parra, E, Collado, LF and Vredenburg, VT (2017) Deconstructing the landscape of fear in stable multi-species societies. Ecology 98, 24472455.CrossRefGoogle ScholarPubMed
Martínez, AE, Parra, E, Muellerklein, O and Vredenburg, VT (2018) Fear-based niche shifts in neotropical birds. Ecology 99, 13381346.CrossRefGoogle ScholarPubMed
McLoughlin, PD, Walton, LR, Cluff, HD, Paquet, PC and Ramsay, MA (2004) Hierarchical habitat selection by tundra wolves. Journal of Mammalogy 85, 576580.CrossRefGoogle Scholar
Mokross, K, Ryder, TB, Côrtes, MC, Wolfe, JD and Stouffer, PC (2014) Decay of interspecific avian flock networks along a disturbance gradient in Amazonia. Proceedings of the Royal Society B: Biological Sciences 281, 20132599.CrossRefGoogle ScholarPubMed
Morales, MB, Traba, J, Carriles, E, Delgado, MP and De la Morena, ELG (2008) Sexual differences in microhabitat selection of breeding little bustards Tetrax: ecological segregation based on vegetation structure. Acta Oecologica 34, 345353.CrossRefGoogle Scholar
Morse, D (1970) Ecological aspects of some mixed-species foraging flocks of birds. Ecological Monographs 40, 119168.CrossRefGoogle Scholar
Neill, S and Cullen, J (1974) Experiments on whether schooling by their prey affects the hunting behavior of cephalopods and fish predators. Journal of Zoology 172, 549569.CrossRefGoogle Scholar
Pulliam, G (1973) On the possible contribution of mixed species flocks to species richness in neotropical avifaunas. Behavioral Ecology and Sociobiology 24, 387393.Google Scholar
Radford, AN, Bell, MBV, Hollén, LI and Ridley, AR (2011) Singing for your supper: sentinel calling by kleptoparasites can mitigate the cost to victims. Evolution 65, 900906.CrossRefGoogle ScholarPubMed
R Core Team (2018) R: A Language and Environment for Statistical Computing. Vienna, Austria: R Foundation for Statistical Computing.Google Scholar
Ridley, AR, Wiley, EM and Thompson, AM (2014) The ecological benefits of interceptive eavesdropping. Functional Ecology 28, 197205.CrossRefGoogle Scholar
Robin, V and Davidar, P (2002) The vertical stratification of birds in mixed species flocks at Parambikulam, South India: a comparison between two habitats. Bombay Natural History Society 99, 389399.Google Scholar
Rodewald, PG and Brittingham, MC (2002) Habitat use and behavior of mixed species landbird flocks during fall migration. The Wilson Bulletin 114, 8798.CrossRefGoogle Scholar
Satischandra, SHK, Kudavidanage, EP, Kotagama, SW and Goodale, E (2007) The benefits of joining mixed-species flocks for greater racket-tailed drongos Dicrurus paradiseus . Forktail 23, 145148.Google Scholar
Sridhar, H, Beauchamp, G and Shanker, K (2009) Why do birds participate in mixed-species foraging flocks? A large-scale synthesis. Animal Behaviour 78, 337347.CrossRefGoogle Scholar
Sridhar, H, Jordán, F and Shanker, K (2013) Species importance in a heterospecific foraging association network. Oikos 122, 13251334.CrossRefGoogle Scholar
Sridhar, H and Sankar, K (2008) Effects of habitat degradation on mixed-species bird flocks in Indian rain forests. Journal of Tropical Ecology 24, 135147.CrossRefGoogle Scholar
Sridhar, H and Shanker, K (2014) Importance of intraspecifically gregarious species in a tropical bird community. Oecologia 176, 763770.CrossRefGoogle Scholar
Stratford, JA and Stouffer, PC (1999) Local extinctions of terrestrial insectivorous birds in a fragmented landscape near Manaus, Brazil. Conservation Biology 13, 14161423.CrossRefGoogle Scholar
Thiollay, J-M (1992) Influence of selective logging on bird species diversity in a Guianan rain forest. Conservation Biology 6, 4760.CrossRefGoogle Scholar
Thiollay, J-M (1999a) Responses of an avian community to rain forest degradation. Biodiversity and Conservation 8, 513534.CrossRefGoogle Scholar
Thiollay, J-M (1999b) Frequency of mixed species flocking in tropical forest birds and correlates of predation risk: an intertropical comparison. Journal of Avian Biology 30, 282.CrossRefGoogle Scholar
Tubelis, DP, Cowling, A and Donnelly, C (2006) Role of mixed-species flocks in the use of adjacent savannas by forest birds in the central Cerrado, Brazil. Austral Ecology 31, 3845.CrossRefGoogle Scholar
Williams, SM and Lindell, CA (2019) The influence of a single species on the space use of mixed-species flocks in Amazonian Peru. Movement Ecology 7, 37.CrossRefGoogle ScholarPubMed
Zhang, Q, Han, R, Huang, Z and Zou, F (2013) Linking vegetation structure and bird organization: response of mixed-species bird flocks to forest succession in subtropical China. Biodiversity and Conservation 22, 19651989.CrossRefGoogle Scholar
Zhou, L, Peabotuwage, I, Gu, H, Jiang, D, Hu, G, Jiang, A, Mammides, C, Zhang, M, Quan, R-C and Goodale, E (2019) The response of mixed-species bird flocks to anthropogenic disturbance and elevational variation in southwest China. The Condor 121, duz028.CrossRefGoogle Scholar
Zou, F, Jones, H, Colorado, ZGJ, Jiang, D, Lee, T-M, Martínez, A, Sieving, K, Zhang, M, Zhang, Q and Goodale, E (2018) The conservation implications of mixed-species flocking in terrestrial birds, a globally-distributed species interaction network. Biological Conservation 224, 267276.CrossRefGoogle Scholar
Zuluaga, GJC and Rodewald, AD (2015). Response of mixed-species flocks to habitat alteration and deforestation in the Andes. Biological Conservation 188, 7281.CrossRefGoogle Scholar
Figure 0

Figure 1. Location of Kali Tiger Reserve in the Western Ghats (inset) and trails (brown lines) around Anshi village (blue triange) and Anshi nature camp (yellow circle).

Figure 1

Figure 2. Distribution of bootstrapped means of availability (green) and use (purple) for (a) density of trees (per m2), (b) basal area (cm2 per sq. m), (c) plant cover (count), (d) sapling cover (percentage cover), (e) canopy cover (score) and (f) foliage complexity (score).

Figure 2

Figure 3. Distribution of bootstrapped standard deviations of availability (green) and use (purple) for (a) density of trees (per m2), (b) basal area (cm2 per sq. m), (c) plant cover (count), (d) sapling cover (percentage cover), (e) canopy cover (score) and (f) foliage complexity (score).

Figure 3

Figure 4. (a) Density of trees and (b) foliage complexity in all use sites, sites with flocks in which warblers were absent, and sites with flocks in which warblers were present. **indicates p < 0.01 and *indicates p < 0.5.

Supplementary material: File

Hariharan et al. supplementary material

Table S3

Download Hariharan et al. supplementary material(File)
File 10.5 KB
Supplementary material: File

Hariharan et al. supplementary material

Table S2

Download Hariharan et al. supplementary material(File)
File 10.8 KB
Supplementary material: File

Hariharan et al. supplementary material

Table S1

Download Hariharan et al. supplementary material(File)
File 11 KB