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Article

Noise Pollution and Urban Birds Breeding in the Center of the Iberian Peninsula: Effects on Diversity and Abundance

by
Paula Almarza-Batuecas
1,* and
Moisés Pescador
2
1
Department of Animal Biology, Ecology, Parasitology, Edaphology, and Organic Chemistry, University of Salamanca, 37007 Salamanca, Spain
2
Department of Physiology and Pharmacology, University of Salamanca, 37007 Salamanca, Spain
*
Author to whom correspondence should be addressed.
Diversity 2025, 17(5), 338; https://doi.org/10.3390/d17050338
Submission received: 3 April 2025 / Revised: 30 April 2025 / Accepted: 1 May 2025 / Published: 8 May 2025
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Abstract

:
In an increasingly urbanized world, biodiversity, and more specifically, birdlife located in urbanized ecosystems, faces several threats. Among these, noise pollution has proven to be one of the most significant, as it affects the effectiveness and efficiency of acoustic communication. We studied the relationship between noise and the diversity and abundance of birds breeding in urban areas in the central region of the Iberian Peninsula (Spain). We analyzed how species diversity and density varied across three levels of noise pollution (high, medium, and low). Species diversity decreased in areas with high noise pollution as compared to sites with medium and low levels of noise. We analyzed the density of the most frequent species found within each category. We identified eight additional noise-tolerant species whose density had significantly increased in environments with high levels of noise (e.g., Blackbird, Eurasian Tree Sparrow, and the Coal Tit). The ten most sensitive species, such as the Common Linnet, House Sparrow, and the European Greenfinch, had significantly decreased densities when the level of noise increased. Identifying the sensitivity (the effect) of urban bird species to acoustic pollution is vital for effective conservation management measures and for the sustainable planning and management of cities.

1. Introduction

Urbanized areas are becoming more abundant and expansive, often replacing other habitat types. Urban development forecasts have predicted that urban areas will continue to grow and human populations will become increasingly concentrated in larger and larger cities [1]. This situation raises conservation concerns about urban change and its effect on wildlife [2,3], as urbanization brings many changes that can threaten wildlife, particularly birds, for example, their diet and seasonality [4,5,6]. Urbanization brings with it many negative effects, such as habitat fragmentation, increased stress, contact with various sources of pollution (chemical, light, and acoustic pollution, even electromagnetic), and novel structures (for example, collisions with glasses and other reflecting surfaces) [7,8,9]. However, urbanization can also be beneficial, leading to situations of a milder microclimate (heat island effect), increased food availability (which may be low quality), and a general decrease in predators (although the presence of cats remains a major threat) [5,10]. Despite the multiple negative effects of urbanization, some bird species are successful in cities, with large and successful populations in urban habitats—synurbic species [3,11,12,13].
Nevertheless, it is also known that birds are particularly sensitive to noise pollution [11,14]. Anthropogenic noise pollution (also called noise in this paper) is closely linked to human activities, and its main source is road traffic (streets, avenues, roads, highways, etc.) and noise produced from other non-vehicle motors [15,16,17,18]. Generally, anthropogenic acoustic pollution is characterized by low-frequency noise, starting from 2 KHz and downwards [11,16]. Birds use acoustic communication as one of the main communication routes to communicate with conspecifics and individuals of other species [14,15]. This acoustic communication is extremely important to different activities of birds, such as territory defense, mate attraction, parental care, and communication in cases of danger, among others [18,19]. Noise can prevent proper and efficient acoustic communication between individuals by masking their vocalizations [14,15,20]. This increase in noise leads to different negative effects for birds, such as increased stress and predation, increased time spent on territory defense, mate attraction, feeding, and vigilance [21,22,23,24]. Noise is an important stress factor for birds and can lead to a decline in their populations as their normal life cycles are hampered [16,18]. Noise can even produce a barrier effect, preventing some birds or bird species from accessing places with high noise pollution [19,25,26]. Urban birdlife has declined in Spain in recent decades [27,28], and a similar trend has been observed in other cities around the world [8]. Acoustic pollution (noise) can mask bird vocalizations, but it does not affect all bird species equally. It depends on the individual characteristics of each species (e.g., body size) and their song (vocal range, frequencies, etc.) [16,18,29,30]. Alternatively, several studies have found that some species can adapt to noise, for example, with changes in their songs and vocalizations or their behavior [14,20,31,32].
The main objective of the present study is to assess the effects of noise on the diversity and density of bird species living and breeding in urban areas in the center of the Iberian Peninsula (Spain). We compared the diversity and density of birds between sites with three different levels of noise (high, medium, and low). We test whether noise has a negative effect on the urban bird population in our study areas. Moreover, we aim to identify which species populations are negatively or positively affected by noise and to study the effect of anthropogenic acoustic pollution on urban bird assemblages.

2. Materials and Methods

2.1. Study Area

Sampling was carried out in 9 cities and towns in the center of the Iberian Peninsula (Spain) (Figure 1), in an area of approximately 1400 Km2 with a Mediterranean climate. The cities and towns were different in population and geographical size. The selected cities and towns were Madrid (324.7 Km2, 3,332,035 inhabitants), Parla (9.1 Km2, 133,004 inhabitants), Aranjuez (7.5 Km2, 60,668 inhabitants), Pinto (10.7 Km2, 55,208 inhabitants), Carranque (2.3 Km2, 5274 inhabitants), Casarrubuelos (0.79 Km2, 4062 inhabitants), Lominchar (1.1 Km2, 2639 inhabitants), Palomeque (0.26 Km2, 1143 inhabitants), and Batres (0.25 Km2, 1872 inhabitants). The study area included a wide variety of urban sites: small and large parks, ranging from squares to streets with minimal vegetation (to ensure a minimum number of bird recordings). We categorized the study area according to anthropogenic acoustic pollution (noise). For prior categorization, we used noise maps and decibel (dB) measurements during previous visits to each location. In addition, we made noise pollution measurements at each bird sampling visit and averaged them before analysis. We measured noise decibels for 1 min using an Extech Instruments sonometer model 407,736 (with an A-weighted filter), one meter above the ground. Noise measurements were taken at each point and each visit, covering different times throughout the morning. These categories were validated by statistical analysis using the Kruskal–Wallis test (H = 928,742; p < 0.001). The categories with their characteristics were the following:
  • High level of acoustic pollution, where noise pollution levels were high and continuous: mean 56.1 dB (range: 49–66 dB).
  • Medium level of acoustic pollution, where noise pollution levels were medium to low, with peaks of high noise pollution corresponding to the start and end of work, schools, rush hours, etc.: mean 49.6 dB (range: 45–59 dB).
  • Low level of acoustic pollution, where noise pollution remained low: mean 43.3 dB (range: 39–48 dB).

2.2. Bird Sampling

The sampling unit used was a point-count station with a 25 m fixed radius. This method was selected because it provides a standardized protocol, especially at sites with high environmental heterogeneity [33]. In this study, only a 25 m radius was used to avoid the problem of decreasing species detectability at farther away distances. We established 72 point counts, divided into three categories of acoustic pollution, high, medium, and low, with 24 count points per category. The point counts were established according to town size, ranging from 22 (the biggest city, Madrid) to 3 (the smallest, Batres, Lominchar, and Palomeque). The 72 point-count stations were at least 250 m apart to avoid overlapping and duplicated point counts. The locations of the point-count stations were randomly selected, and the three groups of points had similar and comparable characteristics. Several habitat factors were considered, primarily to balance the sampling points between different noise levels. These main factors were vegetation cover area, urban cover area, building type (approximate height and age), presence or absence of the three strata types, existence of sandy surfaces, presence of water, use of mulch in gardening, human activity (type and quantity), the area of the municipality, and the distance to the municipal border. The bird species, either heard or seen, and their abundance were recorded for 10 min. This sampling time frame was chosen because it was proven optimal for collecting a complete bird count without overestimating in previous studies. Sampling was conducted early in the morning, before sunrise, until noon (or 10 am during the hottest months), in optimal weather conditions, with no or low wind and no rain [33]. Sampling was conducted during the breeding season between March 2019 and August 2021 (15 March to 15 August). Sixteen sampling visits were made to each point-count station, and between 1 and 2 samplings were performed per month (a total of 8 visits in 2019, 6 in 2021, and only 2 visits in 2020 because of COVID-19 restrictions).

2.3. Statistical Analysis

We estimated the species diversity and density of each species for each noise level. To estimate species diversity, we calculated species richness using species accumulation curves. Species accumulation curves for each plot were constructed to measure the completeness of the sampling and to compare the species richness [34,35]. These curves enabled us to establish a compromise among the different plot surveys since counts exclusively based on the number of species observed without reference to the effort invested would have obtained false results [36]. The number of point counts was taken as a measure of the sampling effort and randomized 100 times to construct smoothed accumulation species curves [36]. We constructed and used 95% confidence intervals of the curves to compare species diversity among the three smoothed accumulation species curves [37,38]. We used EstimateS v 9.1.0 software to construct the smoothed species accumulation curves [35].
Moreover, we also calculated the density of the 33 most frequent species, those species that had a greater presence in the total number of count points and samples. We chose these most frequent species to ensure a sufficient data set for analysis. To calculate the density (individuals per hectare) per species and point, we used the following equation proposed by Shiu and Lee [39]:
D = n/(πr2) × 10,000,
where D is the density, n is the number of individuals of a species, and r is the sampling unit radius (in meters).
We analyzed the density of each species for the three categories of acoustic pollution using a non-parametric Kruskal–Wallis test [40]. For species that showed significant differences, a pairwise Dunn test with Bonferroni correction was performed to detect which pairs of noise levels were significantly different. All statistical analyses were performed using IBM SPSS Statistics v 28.0.1.1 software.

3. Results

3.1. Species Diversity

A total of 29,934 individuals from 81 species belonging to 37 families were recorded (Table 1 and Table A1). The comparison of species diversity for the three levels of noise produced smoothed species accumulation curves with a 95% confidence interval, as shown in Figure 2. Sites with a high noise level had fewer species and less diversity (49 bird species) than the sites with a medium or low level of noise (with 71 and 67 bird species, respectively). In our analysis, the 95% confidence interval of the high noise level curve did not overlap with the confidence intervals of the other two curves. Of the 81 species, 17 species were absent in at least one noise category, such as the Hawfinch (Coccothraustes coccothraustes), which was not registered in the high-noise sites (Table 1 and Table A1). On the other hand, 19 species were unique to a particular noise level and appeared in only one of the categories (Table A1). For example, the European Crested Tit (Lophophanes cristatus) was only recorded in sites with a low level of noise. The analysis of trends in population size over the last decade showed that 21 species (Table 1 and Table A1) were in decline in all Spanish territories, such as the House Sparrow (Passer domesticus), Eurasian Magpie (Pica pica), European Serin (Serinus serinus), Common Linnet (Linaria cannabina), Eurasian Tree Sparrow (Passer montanus), White Wagtail (Motacilla alba), and the Iberian Green Woodpecker (Picus sharpei) [41]. Although these species are experiencing a decrease in population size, they can be found in urban habitats. Of the 81 species, 15 species are listed in the Spanish legislation as endangered or near endangered (Table 1 and Table A1), such as the Barn Swallow (Hirundo rustica), which is classified as vulnerable (VU), and the Western Jackdaw (Corvus monedula), classified as endangered (EN) [42]. We also found two rare species: Hawfinch and Pied Flycatcher (Ficedula hypoleuca) [27]. Three allochthonous species were recorded, including the Monk Parakeet (Myiopsitta monachus), which was one of the most frequent and abundant species found. Another species observed was the Common and Pallid Swift (Apus apus and A. pallidus); however, they were not included in the density analysis because of their biology, as they spend most of their lives away from the ground and noise.

3.2. Response to Noise

In the density analysis, we observed that birds responded differently to the level of noise. Out of the 33 species studied, only 18 species showed a clear response. For the other 15 species, significant results were not obtained from the statistical analysis, or the results did not clearly explain the response of these species to noise. Moreover, the species that did show a clear result could be divided into two groups or responses. One group or response consisted of species whose density responded negatively to noise. The density of these species was higher when the noise level was low than when it was high (Figure 3). This group had statistically significant values and consisted of 10 bird species (Table 2): European Greenfinch (Chloris chloris), Common Chaffinch (Fringilla coelebs), Barn Swallow (Hirundo rustica), Common Linnet (Linaria cannabina), Spotted Flycatcher (Muscicapa striata), House Sparrow (Passer domesticus), Black Redstart (Phoenicurus ochruros), European Serin (Serinus serinus), Eurasian Collared Dove (Streptopelia decaocto), and the Spotless Starling (Sturnus unicolor). Table 2 shows the results of the pairwise analysis of noise levels for each species.
The other group or response consisted of species whose density responded positively to noise. The density of these species was greater when the noise level was high than when it was low (Figure 4). This group had statistically significant values and consisted of eight bird species (Table 3): Rock Dove (Columna livia), Common Wood Pigeon (Columba palumbus), Monk Parakeet (Myiopsitta monachus), Eurasian Tree Sparrow (Passer montanus), Coal Tit (Periparus ater), Eurasian Magpie (Pica pica), Iberian Green Woodpecker (Picus sharpei), and the Common blackbird (Turdus merula). Table 3 shows the results of the pairwise analysis of noise levels for each species.

4. Discussion

A total of 81 breeding species belonging to 37 families were recorded. This diversity was to be expected based on similar studies on urban avifauna [43,44,45]. Even though urban habitat is one of the most altered with several sources of stress for birds [5], we found bird species classified as being endangered, rare, or declining in population [27,41,42]. These results were expected and are in line with other similar studies [44,46,47] and highlight the role of the urban ecosystem in maintaining bird diversity and conservation [48,49]. The species that stand out because of their density and frequency are similar (Table 1, Figure 3 and Figure 4) and are typically urban species (synanthropic species). Other similar studies highlight these species for their high frequency and abundance [47,50,51,52]. We see that the frequency and density of species decrease rapidly, a finding that is coherent with the effect of urbanization on the homogenization of biodiversity, with synanthropic species being the most abundant and frequent [18,53]. One of the most abundant species found in this study was the invasive exotic species Monk Parakeet (Myiopsitta monachus). This and the other invasive exotic species found, despite not being in their natural habitat, have succeeded mainly due to changes caused by urbanization [5,53,54], which has caused problems for other bird species and even humans [55].
We found lower bird diversity at sites with high noise levels. Noise seems to negatively affect bird diversity, rarefying some species and even making them absent in places with a high level of noise [9,25,30]. This rarefying of species with increasing noise was also observed by Herrera-Montes and Aide [56], who found that some species disappeared in areas close to the noise source (road) and reappeared when the noise decreased. In this study, we obtained a similar species diversity at low and medium noise levels. High species diversity has been related to medium and low disturbance levels in several studies [25,51,53,57]. In this case, noise (anthropogenic acoustic pollution) is detrimental to birds because it masks their vocalizations, and this noise can be a barrier to their dispersion [11,14,18,58]. However, this relationship between species richness and noise is not always clear; for example, Ghadiri Khanaposhtani et al. [26] show that avian richness could decrease in some cases and increase in others in relation to noise increments.
In this study, the response of species to noise differed. These differential responses were expected based on the literature, which indicates that the response depends on many species-specific factors, such as the vocalization characteristics of each species [16,18,30]. We found two main groups: species that, at high noise levels, decreased or increased in density. The species whose density was negatively affected by noise behaved as noise-sensitive species. For these species, it could be possible that acoustic pollution impedes their proper communication by masking their vocalizations and may produce a barrier effect on their distribution, making these areas with high noise pollution inaccessible [11,20,59]. The species whose density increased with increasing noise behaved as noise-tolerant (or less sensitive) in this study. The increased density of some species may be explained by them occupying the niche space left by more sensitive species, increasing avian homogeneity [53,58]. We found results similar to this study for several species [23,25,43,44,57]. Despite similar results in the literature, we also found other studies with different, sometimes opposite, results for the same bird species [25,44,57], for example, blackbird, which, in some studies, is more abundant in non-urban places.
On the other hand, we identified species with no clear relationship with noise, which is frequently reported in the literature [17,56,57]. These species seem to not be affected, either negatively or positively, but the reason behind this depends on each species, its characteristics, and its history [3,18,58]. These results may change with a larger pool of data or with specific or more concrete studies on these species without a clear relationship to noise. Discrepancies and species with no clear relationship may be due to a lack of knowledge about song characteristics and how noise affects them. Species may not be equally susceptible to masking by noise (anthropogenic acoustic pollution), and this will depend on their song characteristics [14,18,60], which may also be an explanation for some noise-tolerant species in this study. Another possible factor for these discrepancies may be the differences between road and city noise (more localized and continuous, and usually more intense). Another cause of discrepancies is the possible song adaptation of the species [20,30,58], which may blur the relationship with noise. This may be the case of the Great Tit. In our study, its density did not vary with the level of noise, and several studies have found that Great Tits can adapt their vocalizations to avoid masking by noise [11,18,61]. The acoustic adaptation hypothesis [19] may also be a reason for the increased density of tolerant species. These species can avoid the negative effects of noise and increase their population where other species cannot. Song adaptation has been described in different species by various authors; for example, the great tit, the blackbird [14,62,63], the European robin [31,64,65], and other species [23,66,67]. What is not clear is whether these changes are permanent or not [32,68,69]. These adaptations can be found in different song characteristics [20,60,70], and these changes can give rise to various dialects in different populations [71]. Song adaptation to acoustic pollution is a broad topic, and although there are numerous studies on the subject, there is a need to further improve our knowledge.
In this study, only noise pollution was considered by comparing three different noise categories (high, medium, and low). However, this research should be complemented using other multivariate studies, where different characteristics of the urban habitat are evaluated simultaneously, as well as the effect of other collateral noise (stress, energy expenditure) [23,72] on each species. The urban ecosystem is a heterogeneous environment, and many urban variables can affect birds. We randomly choose points with different characteristics to balance the urban characteristics and make the categories comparable. Although in our study, we aim for the chosen points to be a representative sampling of urban ecosystems, we cannot rule out stochastic random effects. This point is a weakness of our study; however, we believe that the differences found are caused by differences in acoustic pollution. This type of study should be combined with other studies that analyze noise with other characteristics of the urban ecosystem and how it affects birds. Another important focus for urban bird conservation, aside from our study, is the quality of the populations regardless of abundance and how cities can become ecological traps [72]. Urban bird conservation is an important issue that can be addressed using various strategies, which underline the need for further research and expanding our knowledge on this topic.
Despite the dependency of birds on effective and efficient acoustic communication, only 54.5% of the species tested responded clearly to noise. Similar results can be found in different studies [23,44,57], although other authors report a higher proportion [26]. This highlights the complexity of the relationship between noise and birds and the need for further research to test whether these birds have adapted their songs or other factors important for their survival.
Recently, urbanization efforts have shifted toward integrating cities into the natural environment, creating “greener” and more eco-friendly cities [73,74] through structures and tools such as green roofs, vertical gardens, and biodiversity corridors [75,76,77]. Part of the studies on urban biodiversity are focused on being a management tool for “ecofriendly” cities [78,79]. More eco-friendly management of cities, together with a general decrease in noise pollution linked to urbanized environments, promotes an increase in biodiversity and the role of cities in conservation [46,74,76]. These changes would also benefit city dwellers, who would have a better quality of life, both physically and mentally. This eco-friendly approach promotes the well-being of inhabitants [80], connects them to nature, and produces benefits through various ecosystem services (temperature regulation and mitigation, cleaning up air pollution, etc.) [74,81]. Identifying the sensitivity (how it is affected) of bird species to acoustic pollution may allow urban birds to be used as bioindicators of noise. The use of birds as bio-indicators of human health and quality of life and as a useful tool for urban management and biodiversity conservation [82] is becoming increasingly common.

5. Conclusions

Noise pollution seems to be a key factor for birds, as well as other animal species, that can lead to evolutionary pressure or increased energy expenditure. Noise decreased the diversity of birds and increased their homogenization, and some species also experienced a decrease in density. The variety of responses to noise pollution may be due to several factors, including the song characteristics of each species, their adaptive capacity, and other possible factors, such as behavior adaptation. The characteristics of urban environments are similar in many cities around the world, making the management of cities and their green spaces relevant to the adjacent landscape for their biodiversity conservation.
The effects of noise on birds need to be taken into account, especially when managing green spaces, planning cities, and promoting less noisy cities. Various actions can be taken to reduce the level of noise pollution on several fronts, promoting less use of motor vehicles (mainly private), encouraging the use of other non-noisy transport (such as bicycles), pedestrianizing more streets, and better planning of infrastructure (main roads, etc.) are actions that reduce noise pollution. Noise barriers can also be palliative measures, which can be artificial or natural, such as lines of vegetation on the edges of large parks. These are just a few concrete examples, as more and more research is being carried out to reduce noise pollution and its propagation in urbanized environments with different and new focuses.

Author Contributions

Conceptualization, P.A.-B. and M.P.; methodology, P.A.-B. and M.P.; software, P.A.-B.; validation, M.P.; formal analysis, P.A.-B.; investigation, P.A.-B.; resources, M.P.; data curation, P.A.-B.; writing—original draft preparation, P.A.-B.; writing—review and editing, M.P.; visualization, P.A.-B.; supervision, M.P.; project administration, M.P.; funding acquisition, M.P. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the University of Salamanca, grant number R010/463AD04.

Institutional Review Board Statement

Not applicable.

Data Availability Statement

The raw data supporting the conclusions of this article will be made available by the authors upon request.

Acknowledgments

We would like to acknowledge the University of Salamanca for funding and administrative support.

Conflicts of Interest

The authors declare no conflicts of interest.

Appendix A

Table A1. The bird species that were recorded but not used for the density analysis. The table lists the common name of each species, as well as its scientific name, conservation status (c. status), and the number of times it was recorded in each of the three noise level categories (high, medium, and low). The asterisk (*) marks those species whose populations are in decline in Spain, and ALLOC is the allochthonous species. E marks those species excluded from the density analysis. In c. status are the IUCN (The International Union for Conservation of Nature) categories of LC (Least Concern), NT (Near Threatened), VU (Vulnerable), and EN (Endangered).
Table A1. The bird species that were recorded but not used for the density analysis. The table lists the common name of each species, as well as its scientific name, conservation status (c. status), and the number of times it was recorded in each of the three noise level categories (high, medium, and low). The asterisk (*) marks those species whose populations are in decline in Spain, and ALLOC is the allochthonous species. E marks those species excluded from the density analysis. In c. status are the IUCN (The International Union for Conservation of Nature) categories of LC (Least Concern), NT (Near Threatened), VU (Vulnerable), and EN (Endangered).
English NameScientific NameC. StatusHigh LevelMedium LevelLow LevelTotal
White StorkCiconia ciconiaLC46313
Western Bonelli’s WarblerPhylloscopus bonelliLC45413
Iberian ChiffchaffPhylloscopus ibericusLC64111
MallardAnas platyrhynchosLC *44210
European Bee-eaterMerops apiasterLC21710
Eurasian HoopoeUpupa epopsLC *21710
Black KiteMilvus migransLC2248
Iberian ChiffchaffPhylloscopus collybitaNT2248
Great Spotted WoodpeckerDendrocopos majorLC2237
Common NightingaleLuscinia megarhynchosLC0156
Eurasian NuthatchSitta europaeaLC3126
Red-rumped SwallowCecropis dauricaLC0145
Zitting CisticolaCisticola juncidisNT0235
Red KiteMilvus milvusEN0145
HawfinchCoccothraustes coccothraustesLC0134
Eurasian WrenTroglodytes troglodytesLC0224
Common Reed WarblerAcrocephalus scirpaceusLC0123
Carrion CrowCorvus coroneLC1113
Eurasian Golden OrioleOriolus oriolusLC1023
Rose-ringed ParakeetPsittacula krameriALLOC1113
European StonechatSaxicola rubicolaLC *0033
Garden WarblerSylvia borinLC0123
Greylag GooseAnser anserLC0112
Montagu’s HarrierCircus pygargusVU *0022
Corn BuntingEmberiza calandraLC *0112
Peregrine FalconFalco peregrinusNT1102
Common KestrelFalco tinnunculusEN *0022
European Crested TitLophophanes cristatusLC0022
Spanish SparrowPasser hispaniolensisLC1102
Common RedstartPhoenicurus phoenicurusLC1102
Common FirecrestRegulus ignicapillaLC0112
Song ThrushTurdus philomelosLC0022
Red-legged PartridgeAlectoris rufaVU *0101
Little OwlAthene noctuaNT *0101
Muscovy DuckCairina moschataALLOC0011
Cetti’s WarblerCettia cettiLC0101
Lesser KestrelFalco naumanniVU0101
Common MoorhenGallinula chloropusLC0011
Griffon VultureGyps fulvusLC0011
Woodchat ShrikeLanius senatorEN0101
Red CrossbillLoxia curvirostraLC0101
Great CormorantPhalacrocorax carboLC0101
Wood WarblerPhylloscopus sibilatrixDD0101
Willow WarblerPhylloscopus trochilusDD0101
Common WhitethroatSylvia communisLC *0011
Dartford WarblerCurruca undataEN0101
Common SwiftApus apusVU *EEEE
Pallid SwiftApus pallidusLCEEEE

References

  1. United Nations Department of Economic and Social Affairs. The World’s Cities in 2018—Data Booklet; United Nations: New York, NY, USA, 2018. [Google Scholar]
  2. Lepczyk, C.A.; La Sorte, F.A.; Aronson, M.F.J.; Goddard, M.A.; MacGregor-Fors, I.; Nilon, C.H.; Warren, P.S. Global Patterns and Drivers of Urban Bird Diversity. In Ecology and Conservation of Birds in Urban Environments; Murgui, E., Hedblom, M., Eds.; Springer International Publishing: Berlin/Heidelberg, Germany, 2017; pp. 13–33. ISBN 9783319433141. [Google Scholar]
  3. Murgui, E.; Hedblom, M. Ecology and Conservation of Birds in Urban Environments; Murgui, E., Hedblom, M., Eds.; Springer International Publishing: Cham, Switzerland, 2017; ISBN 978-3-319-43312-7. [Google Scholar]
  4. Ditchkoff, S.; Saalfeld, S.; Gibson, C. Animal Behavior in Urban Ecosystems: Modifications Due to Human-Induced Stress. Urban Ecosyst. 2006, 9, 5–12. [Google Scholar] [CrossRef]
  5. Díaz, M.; Ramos, A.; Concepción, E.D. Changing Urban Bird Diversity: How to Manage Adaptively Our Closest Relation with Wildlife. Ecosistemas 2022, 31, 2354. [Google Scholar] [CrossRef]
  6. Soifer, L.G.; Donovan, S.K.; Brentjens, E.T.; Bratt, A.R. Piecing Together Cities to Support Bird Diversity: Development and Forest Edge Density Affect Bird Richness in Urban Environments. Landsc. Urban Plan. 2021, 213, 104122. [Google Scholar] [CrossRef]
  7. Chace, J.F.; Walsh, J.J. Urban Effects on Native Avifauna: A Review. Landsc. Urban Plan. 2006, 74, 46–69. [Google Scholar] [CrossRef]
  8. Balmori, A.; Hallberg, Ö. The Urban Decline of the House Sparrow (Passer Domesticus): A Possible Link with Electromagnetic Radiation. Electromagn. Biol. Med. 2007, 26, 141–151. [Google Scholar] [CrossRef] [PubMed]
  9. Marzluff, J.M. A Decadal Review of Urban Ornithology and a Prospectus for the Future. Ibis 2016, 159, 1–13. [Google Scholar] [CrossRef]
  10. Bernat-Ponce, E.; Gil-Delgado, J.A.; López-Iborra, G.M. Efectos de Las Características de Las Ciudades Occidentales Contemporáneas Sobre La Avifauna Urbana. Ecosistemas 2022, 31, 2158. [Google Scholar] [CrossRef]
  11. Slabbekoorn, H.; Ripmeester, E.A.P. Birdsong and Anthropogenic Noise: Implications and Applications for Conservation. Mol. Ecol. 2008, 17, 72–83. [Google Scholar] [CrossRef]
  12. Kark, S.; Iwaniuk, A.; Schalimtzek, A.; Banker, E. Living in the City: Can Anyone Become an “Urban Exploiter”? J. Biogeogr. 2007, 34, 638–651. [Google Scholar] [CrossRef]
  13. Jokimäki, J.; Suhonen, J.; Kaisanlahti-Jokimäki, M.L. Urbanization and Species Occupancy Frequency Distribution Patterns in Core Zone Areas of European Towns. Eur. J. Ecol. 2016, 2, 23–43. [Google Scholar] [CrossRef]
  14. Nemeth, E.; Brumm, H. Birds and Anthropogenic Noise: Are Urban Songs Adaptive? Am. Nat. 2010, 176, 465–475. [Google Scholar] [CrossRef]
  15. Slabbekoorn, H. Singing in the Wild: The Ecology of Birdsong. In Nature’s Music; Marler, P., Slabbekoorn, H., Eds.; Elsevier: Amsterdam, The Netherlands, 2004; pp. 178–205. ISBN 9780124730700. [Google Scholar]
  16. Warren, P.S.; Katti, M.; Ermann, M.; Brazel, A. Urban Bioacoustics: It’s Not Just Noise. Anim. Behav. 2006, 71, 491–502. [Google Scholar] [CrossRef]
  17. Parris, K.M.; Schneider, A. Impacts of Traffic Noise and Traffic Volume on Birds of Roadside Habitats. Ecol. Soc. 2008, 14, 29. [Google Scholar] [CrossRef]
  18. Slabbekoorn, H. Songs of the City: Noise-Dependent Spectral Plasticity in the Acoustic Phenotype of Urban Birds. Anim. Behav. 2013, 85, 1089–1099. [Google Scholar] [CrossRef]
  19. Patricelli, G.L.; Blickley, J.L. Avian Communication in Urban Noise: Causes and Consequences of Vocal Adjustment. Auk 2006, 123, 639–649. [Google Scholar] [CrossRef]
  20. Oden, A.I.; Brandle, J.R.; Burbach, M.E.; Brown, M.B.; Gerber, J.E.; Quinn, J.E. Soundscapes and Anthromes: A Review of Proximate Effects of Traffic Noise on Avian Vocalization and Communication. In Encyclopedia of the World’s Biomes; Elsevier: Amsterdam, The Netherlands, 2020; Volume 5, pp. 203–208. ISBN 9780128160978. [Google Scholar]
  21. Brumm, H. The Impact of Environmental Noise on Song Amplitude in a Territorial Bird. J. Anim. Ecol. 2004, 73, 434–440. [Google Scholar] [CrossRef]
  22. Eens, M.; Rivera-Gutierrez, H.F.; Pinxten, R. Are Low-Frequency Songs Sexually Selected, and Do They Lose Their Potency in Male-Female Interactions under Noisy Conditions? Proc. Natl. Acad. Sci. USA 2012, 109, 1. [Google Scholar] [CrossRef] [PubMed]
  23. Gil, D.; Honarmand, M.; Pascual, J.; Pérez-Mena, E.; Macías Garcia, C. Birds Living near Airports Advance Their Dawn Chorus and Reduce Overlap with Aircraft Noise. Behav. Ecol. 2014, 26, 435–443. [Google Scholar] [CrossRef]
  24. Sweet, K.A.; Sweet, B.P.; Gomes, D.G.E.; Francis, C.D.; Barber, J.R. Natural and Anthropogenic Noise Increase Vigilance and Decrease Foraging Behaviors in Song Sparrows. Behav. Ecol. 2022, 33, 288–297. [Google Scholar] [CrossRef]
  25. Wiacek, J.; Polak, M.; Kucharczyk, M.; Bohatkiewicz, J. The Influence of Road Traffic on Birds during Autumn Period: Implications for Planning and Management of Road Network. Landsc. Urban Plan. 2015, 134, 76–82. [Google Scholar] [CrossRef]
  26. Ghadiri Khanaposhtani, M.; Gasc, A.; Francomano, D.; Villanueva-Rivera, L.J.; Jung, J.; Mossman, M.J.; Pijanowski, B.C. Effects of Highways on Bird Distribution and Soundscape Diversity around Aldo Leopold’s Shack in Baraboo, Wisconsin, USA. Landsc. Urban Plan. 2019, 192, 13. [Google Scholar] [CrossRef]
  27. SEO/BirdLife. Tendencia de Las Aves En Primavera. SACRE Resultados 1998–2013. (Bird Trend in Spring. SACRE Results 1998–2013.); SEO/BirdLife: Madrid, Spain, 2013. [Google Scholar]
  28. SEO/BirdLife. Programas de Seguimiento de Avifauna y Grupos de Trabajo de SEO/BirdLife 2018; SEO/BirdLife: Madrid, Spain, 2019. [Google Scholar]
  29. Mendes, S.; Cavalcante, K.; Colino Rabanal, V.; Peris, S.J. Evaluación Del Impacto de La Contaminación Acústica En El Rango de Vocalización de Paseriformes Basado En El SIL-“Speech Interference Level”. Rev. Acúst. 2010, 41, 33–41. [Google Scholar]
  30. Francis, C.D.; Ortega, C.P.; Cruz, A. Noise Pollution Filters Bird Communities Based on Vocal Frequency. PLoS ONE 2011, 6, 8. [Google Scholar] [CrossRef]
  31. Fuller, R.A.; Warren, P.H.; Gaston, K.J. Daytime Noise Predicts Nocturnal Singing in Urban Robins. Biol. Lett. 2007, 3, 368–370. [Google Scholar] [CrossRef] [PubMed]
  32. Mockford, E.J.; Marshall, R.C. Effects of Urban Noise on Song and Response Behaviour in Great Tits. Proc. R. Soc. B Biol. Sci. 2009, 276, 2979–2985. [Google Scholar] [CrossRef]
  33. Bibby, C.J.; Burgess, N.D.; Hill, D.A.; Mustoe, S.H. Birds Census Techniques, 2nd ed.; Elsevier: London, UK, 2000. [Google Scholar]
  34. Soberón, J.; Llorente, J. The Use of Species Accumulation Functions for the Prediction of Species Richness. Conserv. Biol. 1993, 7, 480–488. [Google Scholar] [CrossRef]
  35. Colwell, R.K.; Coddington, J.A. Estimating Terrestrial Biodiversity through Extrapolation. Philos. Trans. R. Soc. Lond. B Biol. Sci. 1994, 345, 101–118. [Google Scholar] [CrossRef] [PubMed]
  36. Gotelli, N.J.; Colwell, R.K. Quantifying Biodiversity: Procedures and Pitfalls in the Measurement and Comparison of Species Richness. Ecol. Lett. 2001, 4, 379–391. [Google Scholar] [CrossRef]
  37. Gotelli, N.J.; Colwell, R.K. Estimating Species Richness. In Biological Diversity: Frontiers in Measurement and Assessment; Magurran, A.E., McGill, B.J., Eds.; Oxford University Press: Oxford, UK, 2010; pp. 39–54. [Google Scholar]
  38. Quesada, J.; MacGregor-Fors, I. Avian Community Responses to the Establishment of Small Garden Allotments within a Mediterranean Habitat Mosaic. Anim. Biodivers. Conserv. 2010, 33, 53–61. [Google Scholar] [CrossRef]
  39. Shiu, H.; Lee, P. Assessing Avian Point-Count Duration and Sample Size Using Species Accumulation Functions. Zool. Stud. 2003, 42, 357–367. [Google Scholar]
  40. Sokal, R.; Rohlf, F. Biometry. The Principles and Practice of Statistics in Biological Research; W.H. Freeman: New York, NY, USA, 1994. [Google Scholar]
  41. SEO/BirdLife. Programas de Seguimiento y Grupos de Trabajo de SEO/BirdLife 2021; SEO/Birdlife: Madrid, Spain, 2022. [Google Scholar]
  42. SEO/BirdLife. Libro Rojo de Las Aves de España 2021; López-Jiménez, N., Ed.; SEO/Birdlife: Madrid, Spain, 2021. [Google Scholar]
  43. Caula, S.A.; Sirami, C.; Marty, P.; Martin, J.-L. Value of an Urban Habitat for the Native Mediterranean Avifauna. Urban Ecosyst. 2010, 13, 73–89. [Google Scholar] [CrossRef]
  44. Patón, D.; Romero, F.; Cuenca, J.; Escudero, J.C. Tolerance to Noise in 91 Bird Species from 27 Urban Gardens of Iberian Peninsula. Landsc. Urban Plan. 2012, 104, 1–8. [Google Scholar] [CrossRef]
  45. Carral-Murrieta, C.O.; García-Arroyo, M.; Marín-Gómez, O.H.; Sosa-López, J.R.; Macgregor-Fors, I. Noisy Environments: Untangling the Role of Anthropogenic Noise on Bird Species Richness in a Neotropical City. Avian Res. 2020, 11, 32. [Google Scholar] [CrossRef]
  46. Ives, C.D.; Lentini, P.E.; Threlfall, C.G.; Ikin, K.; Shanahan, D.F.; Garrard, G.E.; Bekessy, S.A.; Fuller, R.A.; Mumaw, L.; Rayner, L.; et al. Cities Are Hotspots for Threatened Species. Glob. Ecol. Biogeogr. 2016, 25, 117–126. [Google Scholar] [CrossRef]
  47. Sorace, A.; Gustin, M. Species Richness and Species of Conservation Concern in Parks of Italian Towns. In Ecology and Conservation of Birds in Urban Environments; Springer International Publishing: Berlin/Heidelberg, Germany, 2017; pp. 425–448. ISBN 9783319433141. [Google Scholar]
  48. Jokimäki, J.; Jukka, S.; Marja-Liisa, K.J. Urban Core Areas Are Important for Species Conservation: A European-Level Analysis of Breeding Bird Species. Landsc. Urban Plan. 2018, 178, 73–81. [Google Scholar] [CrossRef]
  49. Villaseñor, N.R.; Chiang, L.A.; Hernández, H.J.; Escobar, M.A.H. Vacant Lands as Refuges for Native Birds: An Opportunity for Biodiversity Conservation in Cities. Urban For. Urban Green. 2020, 49, 10. [Google Scholar] [CrossRef]
  50. Fernández-Juricic, E. Avian Spatial Segregation at Edges and Interiors of Urban Parks in Madrid, Spain. Biodivers. Conserv. 2001, 10, 1303–1316. [Google Scholar] [CrossRef]
  51. Kontsiotis, V.J.; Valsamidis, E.; Liordos, V. Organization and Differentiation of Breeding Bird Communities across a Forested to Urban Landscape. Urban For. Urban Green. 2019, 38, 242–250. [Google Scholar] [CrossRef]
  52. Morelli, F.; Reif, J.; Díaz, M.; Tryjanowski, P.; Diego Ibáñez-Álamo, J.; Suhonen, J.; Jokimäki, J.; Kaisanlahti-Jokimäki, M.-L.; Pape Møller, A.; Bussiere, R.; et al. Top Ten Birds Indicators of High Environmental Quality in European Cities. Ecol. Indic. 2021, 133, 108397. [Google Scholar] [CrossRef]
  53. McKinney, M.L. Urbanization as a Major Cause of Biotic Homogenization. Biol. Conserv. 2006, 127, 247–260. [Google Scholar] [CrossRef]
  54. Blair, R.B. Birds and Butterflies Along Urban Gradients in Two Ecoregions of the United States: Is Urbanization Creating a Homogeneous Fauna? In Biotic Homogenization; Lockwood, J.L., McKinney, M.L., Eds.; Springer: Boston, MA, USA, 2001; pp. 33–56. [Google Scholar]
  55. Molina, B.; Postigo, J.L.; Muñoz, A.R.; Del Moral, J.C. La Cotorra Argentina En España, Población Reproductora En 2015 y Método de Censo; SEO/Birdlife: Madrid, Spain, 2016. [Google Scholar]
  56. Herrera-Montes, M.I.; Aide, T.M. Impacts of Traffic Noise on Anuran and Bird Communities. Urban Ecosyst. 2011, 14, 415–427. [Google Scholar] [CrossRef]
  57. Peris, S.J.; Pescador, M. Effects of Traffic Noise on Paserine Populations in Mediterranean Wooded Pastures. Appl. Acoust. 2004, 65, 357–366. [Google Scholar] [CrossRef]
  58. Brumm, H.; Slabbekoorn, H. Acoustic Communication in Noise. Adv. Study Behav. 2005, 35, 151–209. [Google Scholar] [CrossRef]
  59. Marler, P.; Slabbekoorn, H. Nature’s Music: The Science of Birdsong; Marler, P., Slabbekoorn, H., Eds.; Elsevier: Amsterdam, The Netherlands, 2004; ISBN 9780124730700. [Google Scholar]
  60. Hu, Y.; Cardoso, G.C. Which Birds Adjust the Frequency of Vocalizations in Urban Noise? Anim. Behav. 2010, 79, 863–867. [Google Scholar] [CrossRef]
  61. Dominoni, D.; Smit, J.A.H.; Visser, M.E.; Halfwerk, W. Multisensory Pollution: Artificial Light at Night and Anthropogenic Noise Have Interactive Effects on Activity Patterns of Great Tits (Parus Major). Environ. Pollut. 2020, 256, 113314. [Google Scholar] [CrossRef] [PubMed]
  62. Mendes, S.; Colino-Rabanal, V.; Peris, S. Bird Song Variations along an Urban Gradient: The Case of the European Blackbird (Turdus Merula). Landsc. Urban Plan. 2011, 99, 51–57. [Google Scholar] [CrossRef]
  63. Sierro, J.; Schloesing, E.; Pavón, I.; Gil, D. European Blackbirds Exposed to Aircraft Noise Advance Their Chorus, Modify Their Song and Spend More Time Singing. Front. Ecol. Evol. 2017, 5, 68. [Google Scholar] [CrossRef]
  64. McMullen, H.; Schmidt, R.; Kunc, H.P. Anthropogenic Noise Affects Vocal Interactions. Behav. Process. 2014, 103, 125–128. [Google Scholar] [CrossRef]
  65. Polak, M. Relationship between Traffic Noise Levels and Song Perch Height in a Common Passerine Bird. Transp. Res. D Transp. Environ. 2014, 30, 72–75. [Google Scholar] [CrossRef]
  66. Arroyo-Solís, A.; Castillo, J.M.; Figueroa, E.; López-Sánchez, J.L.; Slabbekoorn, H. Experimental Evidence for an Impact of Anthropogenic Noise on Dawn Chorus Timing in Urban Birds. J. Avian Biol. 2013, 44, 288–296. [Google Scholar] [CrossRef]
  67. Sheldon, E.L.; Ironside, J.E.; de Vere, N.; Marshal, R.C. Singing under Glass: Rapid Effects of Anthropogenic Habitat Modification on Song and Response Behaviours in an Isolated House Sparrow Passer Domesticus Population. J. Avian Biol. 2020, 51, 1–8. [Google Scholar] [CrossRef]
  68. Derryberry, E.P.; Phillips, J.N.; Derryberry, G.E.; Blum, M.J.; Luther, D. Singing in a Silent Spring: Birds Respond to a Half-Century Soundscape Reversion during the COVID-19 Shutdown. Science 2020, 370, 575–579. [Google Scholar] [CrossRef]
  69. De Framond, L.; Brumm, H. Long-Term Effects of Noise Pollution on the Avian Dawn Chorus: A Natural Experiment Facilitated by the Closure of an International Airport. Proc. R. Soc. B Biol. Sci. 2022, 289, 20220906. [Google Scholar] [CrossRef] [PubMed]
  70. Ripmeester, E.A.P.; Mulder, M.; Slabbekoorn, H. Habitat-Dependent Acoustic Divergence Affects Playback Response in Urban and Forest Populations of the European Blackbird. Behav. Ecol. 2010, 21, 876–883. [Google Scholar] [CrossRef]
  71. Moseley, D.L.; Phillips, J.N.; Derryberry, E.P.; Luther, D.A. Evidence for Differing Trajectories of Songs in Urban and Rural Populations. Behav. Ecol. 2019, 30, 1734–1742. [Google Scholar] [CrossRef]
  72. Raiter, K.G.; Possingham, H.P.; Prober, S.M.; Hobbs, R.J. Under the Radar: Mitigating Enigmatic Ecological Impacts. Trends Ecol. Evol. 2014, 29, 635–644. [Google Scholar] [CrossRef] [PubMed]
  73. Alberti, M.; Marzluff, J.M.; Shulenberger, E.; Bradley, G.; Ryan, C.; Zumbrunnen, C. Integrating Humans into Ecology: Opportunities and Challenges for Studying Urban Ecosystems. Bioscience 2003, 53, 1169–1179. [Google Scholar] [CrossRef]
  74. Dearborn, D.C.; Kark, S. Motivations for Conserving Urban Biodiversity. Conserv. Biol. 2010, 24, 432–440. [Google Scholar] [CrossRef]
  75. Savard, J.P.L.; Clergeau, P.; Mennechez, G. Biodiversity Concepts and Urban Ecosystems. Landsc. Urban Plan. 2000, 48, 131–142. [Google Scholar] [CrossRef]
  76. Ikin, K.; Le Roux, D.S.; Rayner, L.; Villaseñor, N.R.; Eyles, K.; Gibbons, P.; Manning, A.D.; Lindenmayer, D.B. Key Lessons for Achieving Biodiversity-Sensitive Cities and Towns. Ecol. Manag. Restor. 2015, 16, 206–214. [Google Scholar] [CrossRef]
  77. Fernández Calvo, I.C. 100 Medidas Para La Conservación de La Biodiversidad En Entornos Urbanos; SEO/BirdLife: Madrid, Spain, 2019. [Google Scholar]
  78. Fernández-Juricic, E.; Jokimäki, J. A Habitat Island Approach to Conserving Birds in Urban Landscapes: Case Studies from Southern and Northern Europe. Biodivers. Conserv. 2001, 10, 2023–2043. [Google Scholar] [CrossRef]
  79. White, J.G.; Antos, M.J.; Fitzsimons, J.A.; Palmer, G.C. Non-Uniform Bird Assemblages in Urban Environments: The Influence of Streetscape Vegetation. Landsc. Urban Plan. 2005, 71, 123–135. [Google Scholar] [CrossRef]
  80. World Health Organization. Urban Green Spaces and Health. A Review of Evidence; World Health Organization: Copenhagen, Denmark, 2016. [Google Scholar]
  81. Swartz, T.M.; Gleditsch, J.M.; Behm, J.E. A Functional Trait Approach Reveals the Effects of Landscape Context on Ecosystem Services Provided by Urban Birds. Landsc. Urban Plan. 2023, 234, 104724. [Google Scholar] [CrossRef]
  82. Pollack, L.; Ondrasek, N.R.; Calisi, R. Urban Health and Ecology: The Promise of an Avian Biomonitoring Tool. Curr. Zool. 2017, 63, 205–212. [Google Scholar] [CrossRef]
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Figure 1. (A) Map of the study area in central Spain detailing the location of the cities and towns where the point-count stations were located. (B) Zoom in on the location of some point-count stations in one of the towns included in the study (Aranjuez): yellow stars (high-noise level); green circles (medium-noise level), and red squares (low-noise level). ArcGIS, Google Earth, and Eurostat maps were used to produce the maps.
Figure 1. (A) Map of the study area in central Spain detailing the location of the cities and towns where the point-count stations were located. (B) Zoom in on the location of some point-count stations in one of the towns included in the study (Aranjuez): yellow stars (high-noise level); green circles (medium-noise level), and red squares (low-noise level). ArcGIS, Google Earth, and Eurostat maps were used to produce the maps.
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Figure 2. Smoothed species accumulation curves and their 95% confidence interval for each level of noise: high (purple), medium (orange), and low (green).
Figure 2. Smoothed species accumulation curves and their 95% confidence interval for each level of noise: high (purple), medium (orange), and low (green).
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Figure 3. Species with the highest density (birds/ha) at sites with a low level of noise. Average density at sites with high (purple), medium (orange), and low (green) levels of noise for each bird species. Also, error bars are shown. PasDom, Passer domesticus; StuUni; Sturnus unicolor; ChlChl, Chloris chloris; HirRus, Hirundo rustica; SerSer, Serinus serinus; StrDec, Streptopelia decaocto; LinCan, Linaria cannabina; FriCoe, Fringilla coelebs; PhoOch, Phoenicurus ochruros and MusStr, Muscicapa striata.
Figure 3. Species with the highest density (birds/ha) at sites with a low level of noise. Average density at sites with high (purple), medium (orange), and low (green) levels of noise for each bird species. Also, error bars are shown. PasDom, Passer domesticus; StuUni; Sturnus unicolor; ChlChl, Chloris chloris; HirRus, Hirundo rustica; SerSer, Serinus serinus; StrDec, Streptopelia decaocto; LinCan, Linaria cannabina; FriCoe, Fringilla coelebs; PhoOch, Phoenicurus ochruros and MusStr, Muscicapa striata.
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Figure 4. Species with the highest density (birds/ha) at sites with a high level of noise. Average density at sites with high (purple), medium (orange), and low (green) levels of noise for each bird species. Also, error bars are shown. ColLiv, Columba livia; TurMer, Turdus merula; ColPal, Columba palumbus; MyiMon, Myiopsitta monachus; PicPic, Pica pica; PasMon, Passer montanus; PerAte, Periparus ater and PicSha, Picus sharpei.
Figure 4. Species with the highest density (birds/ha) at sites with a high level of noise. Average density at sites with high (purple), medium (orange), and low (green) levels of noise for each bird species. Also, error bars are shown. ColLiv, Columba livia; TurMer, Turdus merula; ColPal, Columba palumbus; MyiMon, Myiopsitta monachus; PicPic, Pica pica; PasMon, Passer montanus; PerAte, Periparus ater and PicSha, Picus sharpei.
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Table 1. The 33 most frequent and abundant bird species whose densities were analyzed. The table lists the common name of each species recorded, as well as its scientific name, conservation status (c. status), and the number of times it was recorded in each of the three noise categories (high, medium, and low) included in this study. The asterisk (*) marks those species whose populations are in decline in Spain, and ALLOC is the allochthonous species in Spain. In c. status are the IUCN (The International Union for Conservation of Nature) categories of LC (Least Concern), NT (Near Threatened), VU (Vulnerable), and EN (Endangered).
Table 1. The 33 most frequent and abundant bird species whose densities were analyzed. The table lists the common name of each species recorded, as well as its scientific name, conservation status (c. status), and the number of times it was recorded in each of the three noise categories (high, medium, and low) included in this study. The asterisk (*) marks those species whose populations are in decline in Spain, and ALLOC is the allochthonous species in Spain. In c. status are the IUCN (The International Union for Conservation of Nature) categories of LC (Least Concern), NT (Near Threatened), VU (Vulnerable), and EN (Endangered).
English NameScientific NameC. StatusHigh LevelMedium LevelLow LevelTotal
Common Wood PigeonColumba palumbusLC24242472
Common BlackbirdTurdus merulaLC24242472
House SparrowPasser domesticusLC *24242472
Spotless StarlingSturnus unicolorLC18242466
European GreenfinchChloris chlorisLC21232266
Eurasian MagpiePica picaLC *23231864
European GoldfinchCarduelis carduelisLC20222163
European SerinSerinus serinusLC *19202261
Barn SwallowHirundo rusticaVU *16222058
Eurasian Collared DoveStreptopelia decaoctoLC15202055
Rock DoveColumba liviaLC *21191353
Common House MartinDelichon urbicumLC12211952
Common LinnetLinaria cannabinaLC *12191950
Eurasian Blue TitCyanistes caerueleusLC1916843
Great TitParus majorLC16141040
Coal TitPeriparus aterLC1815538
White WagtailMotacilla albaLC *1215734
Monk ParakeetMyiopsitta monachusALLOC1911333
European RobinErithacus rubeculaLC1212832
Black RedstartPhoenicurus ochrurosLC6111229
Common ChaffinchFringilla coelebsLC812828
Eurasian BlackcapSylvia atricapillaLC98926
Short-toed TreecreeperCerthia brachydactylaLC136625
Stock DoveColumba oenasLC96722
Sardinian WarblerSylvia melanocephalaLC78722
Eurasian Tree SparrowPasser montanusNT *105722
Iberian Green WoodpeckerPicus sharpeiLC *95216
European Pied FlycatcherFicedula hypoleucaLC47516
Long-tailed TitAegithalos caudatusLC34411
Spotted FlycatcherMuscicapa striataLC22610
Western JackdawCorvus monedulaEN *2338
Crested LarkGalerida cristataLC *0257
Mistle ThrushTurdus viscivorusLC0257
Table 2. Results of the Kruskal–Wallis test for the species with the highest density at sites with a low level of noise. The table shows the results of the analysis among the three noise levels and the pairwise analysis. The species with a p-value of >0.05 are indicated as ns.
Table 2. Results of the Kruskal–Wallis test for the species with the highest density at sites with a low level of noise. The table shows the results of the analysis among the three noise levels and the pairwise analysis. The species with a p-value of >0.05 are indicated as ns.
Species H p High–Low High–Medium Medium–Low
H p H p H p
Chloris chloris41.242<0.001−116.04<0.001−121.268<0.0015.228ns
Fringilla coelebs12.9650.002−32.284<0.001−6.079ns−26.2040.006
Hirundo rustica103.128<0.001−186.353<0.001−32.721ns−153.632<0.001
Linaria cannabina48.4<0.001−101.727<0.001−40.320.006−61.406<0.001
Muscicapa striata9.3510.009−15.0570.0080.034ns−15.0910.008
Passer domesticus17.486<0.001−96.139<0.001−23.732ns−72.4080.003
Phoenicurus ochruros15.315<0.001−37.286<0.001−18.221ns−19.0650.045
Serinus serinus9.6030.008−54.0470.004−8.738ns−45.0390.016
Streptopelia decaocto34.98<0.001−109.415<0.001−77.382<0.001−32.034ns
Sturnus unicolor114.837<0.001−230.449<0.001−122.383<0.001−108.066<0.001
Table 3. Results of the Kruskal–Wallis test for the species with the highest density at sites with a high level of noise. The table shows the results of the analysis among the three noise levels and the pairwise analysis. The species with a p-value of >0.05 are indicated as ns.
Table 3. Results of the Kruskal–Wallis test for the species with the highest density at sites with a high level of noise. The table shows the results of the analysis among the three noise levels and the pairwise analysis. The species with a p-value of >0.05 are indicated as ns.
Species H p High–Low High–Medium Medium–Low
H p H p H p
Columba livia104.682<0.001201.109<0.001132.379<0.00168.73<0.001
Columba palumbus7.8830.01963.7230.00538.488ns25.234ns
Myiopsitta monachus155.597<0.001207.849<0.001110.104<0.00197.745<0.001
Passer montanus12.5970.00227.9340.00835.703<0.001−7.77ns
Periparus ater36.389<0.00179.773<0.00123.836ns55.938<0.001
Pica pica65.316<0.001154.809<0.00137.082ns117.727<0.001
Picus sharpei17.168<0.00134.521<0.00113.604ns20.9170.013
Turdus merula13.50.00185.383<0.00136.145ns49.2380.035
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Almarza-Batuecas, P.; Pescador, M. Noise Pollution and Urban Birds Breeding in the Center of the Iberian Peninsula: Effects on Diversity and Abundance. Diversity 2025, 17, 338. https://doi.org/10.3390/d17050338

AMA Style

Almarza-Batuecas P, Pescador M. Noise Pollution and Urban Birds Breeding in the Center of the Iberian Peninsula: Effects on Diversity and Abundance. Diversity. 2025; 17(5):338. https://doi.org/10.3390/d17050338

Chicago/Turabian Style

Almarza-Batuecas, Paula, and Moisés Pescador. 2025. "Noise Pollution and Urban Birds Breeding in the Center of the Iberian Peninsula: Effects on Diversity and Abundance" Diversity 17, no. 5: 338. https://doi.org/10.3390/d17050338

APA Style

Almarza-Batuecas, P., & Pescador, M. (2025). Noise Pollution and Urban Birds Breeding in the Center of the Iberian Peninsula: Effects on Diversity and Abundance. Diversity, 17(5), 338. https://doi.org/10.3390/d17050338

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