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Nest-boxes for Common Swifts Apus apus as compensatory measures in the context of building renovation: efficacy and predictors of occupancy

Published online by Cambridge University Press:  21 April 2015

TONIO SCHAUB*
Affiliation:
Zoological Institute and Museum, Ernst Moritz Arndt University of Greifswald, Greifswald, Germany.
PETER J. MEFFERT
Affiliation:
Institute for Community Medicine, Ernst Moritz Arndt University of Greifswald, Greifswald, Germany.
GERALD KERTH
Affiliation:
Zoological Institute and Museum, Ernst Moritz Arndt University of Greifswald, Greifswald, Germany.
*
*Author for correspondence; e-mail: tonio.schaub@posteo.de
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Summary

Currently, renovation and thermal insulation of buildings is happening at a high rate in many European countries, driven in part by the political aim to reduce greenhouse gas emissions. Unfortunately, building renovations often lead to a loss of structures, such as accessible cavities, on which synanthropic species, for example house-nesting birds, depend. In Germany, due to legislative regulations, it is a common practice to install nest-boxes as compensation for destroyed nest sites of birds. However, studies on the efficacy of such measures remain sparse. We monitored the occupancy of 477 compensatory nest-boxes for Common Swifts Apus apus, predominantly placed on renovated prefabricated buildings in a city in Germany. We found 24.3% of the boxes occupied by Swifts. On most buildings, the number of occupied boxes was as high as or even higher than the assumed number of breeding sites prior to renovation. Furthermore, in a district where nearly all buildings had been renovated in the past 10 years, we recorded a remarkably high density of Swifts breeding in nest-boxes. Using boosted regression trees, we analysed whether eight different nest-box properties influenced box occupation probability. The number of neighbouring boxes was the most important. Additionally, box age, facade orientation, city district, relative and absolute height, and manner of installation (external/internal) also played a role. Between different nest-box types, we found only negligible differences in occupation probability. Our findings suggest that installing nest-boxes is likely to be an appropriate measure to compensate for nesting sites of Swifts lost during building renovations. Based on our results, we recommend mounting the boxes a few metres apart from each other and close to the roof edge to maximise success. Further studies should be carried out to assess whether our results and conclusions can be confirmed in other situations.

Information

Type
Research Article
Copyright
Copyright © BirdLife International 2015 
Figure 0

Figure 1. A section of a renovated prefabricated apartment-complex in Greifswald with five compensatory nest-boxes for Common Swifts (box type Schwegler 17). The boxes are integrated in the thermal insulation. Photograph by T. Schaub.

Figure 1

Table 1. Comparison of the number of Swift breeding sites prior to renovation and in 2013 for 10 buildings (or sections of buildings). The numbers of breeding sites prior to renovation were taken from expert assessments. For buildings for which counts from two different years prior to renovation were available, the mean and range of breeding sites are indicated. NB = nest-boxes. *: Buildings where not all nest-boxes were surveyed.

Figure 2

Figure 2. The different nest-box types studied. a: Schwegler 17 (single box); b: Strobel 430; c: Schwegler 1MF; d: Strobel 416t; e: Strobel 416b. Additionally, the Schwegler 17 box occurred in different variants: as double box (17C), triple box (17A) and as box with enlarged interior room (17B). Pictures a, c and d show Common Swifts at the box entrance holes. Note the loam traces on picture d indicating previous use by Northern House-martins. Photographs by T. Schaub.

Figure 3

Table 2. Characteristics of the BRT model. CV = cross-validated; AUC = area under curve; ROC = receiver operation characteristic.

Figure 4

Figure 3. Modelled occupation probability of nest-boxes in relation to eight different box properties. Sample sizes for each category are given above the x-axis. Number of neighbours was defined as the number of boxes with which a given box was associated in a group (distance between adjacent boxes < 1 m). Box age was expressed as the number of possible breeding periods for Swifts before 2013. Boxes defined to be “at roof edge” were closer than 2 m to the roof edge. Nest-box types: A = Schwegler 17 group, B = Schwegler 1MF, C = Strobel 416t, D = Strobel 416b, E = Strobel 430.

Figure 5

Table 3. Number of surveyed nest-boxes and number and proportion of occupied boxes in the different categories of the box properties (raw data). NB = nest-box; prop. occ. NB = proportion of occupied nest-boxes. s = single box; d = double box; t = triple box.

Supplementary material: File

Schaub supplementary material

Tables S1-S2

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Supplementary material: File

SCHAUB Supplementary Material

Tables S2

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