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An assessment of ecological conditions and threats at the Ethiopian wintering site of the last known eastern colony of Critically Endangered Northern Bald Ibis Geronticus eremita

Published online by Cambridge University Press:  29 October 2013

G. SERRA*
Affiliation:
C/o Secretariat of the Pacific Regional Environment Programme, P.O. Box 240, Apia, Samoa.
C. BRUSCHINI
Affiliation:
Dipartimento di Biologia, Università degli Studi di Firenze, via Romana 17,50125, Florence, Italy.
L. PESKE
Affiliation:
Slezska 43, Prague 3, 13000, Czech Republic.
A. KUBSA
Affiliation:
Ethiopian Wildlife and Natural History Society, P.O. Box 13303, Addis Ababa, Ethiopia.
M. WONDAFRASH
Affiliation:
Ethiopian Wildlife and Natural History Society, P.O. Box 13303, Addis Ababa, Ethiopia.
J. A. LINDSELL
Affiliation:
The Royal Society for the Protection of Birds, The Lodge, Sandy, Beds SG19 2DL, UK.
*
*Author for correspondence; email: gianlucas@sprep.org
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Summary

The long-range, migratory eastern relict population of Northern Bald Ibis Geronticus eremita has been steadily declining since the time of discovery in 2002, despite the protection programme in place at the breeding grounds in Syria. Assessing the ecological conditions and threats along the migration route and at the wintering site, both discovered in 2006, has become a priority for this “Critically Endangered” species. Adult ibises spent the winter at the same site on the central Ethiopian highland plateau, from August until mid-February during five consecutive winters (2006-2011). The wintering site was surveyed during four field visits and assessed through a spatial analysis of 1,067 satellite locations. The site is in an agro-pastoral landscape, inhabited by a settled community of people living in relatively poor and isolated conditions. Home range analysis based on kernel distributions showed that the bald ibises used a core range area of 9.1–19.0 km² (confirmed by direct visual observations in the field) and an extended range area of 61.0–126.1 km². These figures are c.20 and 60 times smaller, respectively, than those calculated for the breeding site in Syria. Eighty-one percent of the core area in Ethiopia was used in all five years confirming the birds’ fidelity to this wintering site. Ibises preferred to forage in wet or dry pastures and in recently cut hayfields, and avoided tall grass, uncut hayfields and cultivation. Despite dependence on human-created habitats, human disturbance observed in the field was minimal. The main short-term threat for the ibises was judged to be the potential raising of attention on the part of the local community specifically towards these few individual ibises. In the medium term, the main threat comes from the conversion of pastures into crops and the potential use of fertilisers and pesticides.

Type
Articles
Copyright
Copyright © BirdLife International 2013 

Introduction

Persistent population declines in Palearctic breeding birds are disproportionately concentrated in long distance migrants (Sanderson et al. Reference Sanderson, Donald, Pain, Burfield and van Bommel2006). Many causes for migrant declines have been proposed. One leading hypothesis is that unfavourable conditions at the wintering grounds or along migration routes cause reduced survival (Newton Reference Newton2004). Palearctic migrants wintering in Africa are one group that may be particularly vulnerable to changes on the wintering grounds given the impacts of climate change at the edges of the Sahara which are critical areas for migrants (Zwarts et al. Reference Zwarts, Bijlsma, van der Kamp and Wymenga2009) and the effects of population growth and economic development on land-cover throughout the continent (Tilman et al. Reference Tilman, Cassman, Matson, Naylor and Polasky2002, Soderstrom et al. Reference Soderstrom, Kiema and Reid2003, FAOSTAT database of the UN FAO). Declines in bird species breeding in the UK have been more pronounced for migrants over-wintering within African humid zones (Thaxter et al. Reference Thaxter, Joys, Gregory, Baillie and Noble2010). Ascertaining the cause of any population decline is difficult (Sanderson et al. Reference Sanderson, Donald, Pain, Burfield and van Bommel2006) and the wintering grounds and ecology of most species are very poorly known (Bairlein Reference Bairlein2003). Demonstrating the impact of wintering conditions on breeding declines requires explicit connections to be made between wintering and breeding populations (Webster et al. Reference Webster, Marra, Haig, Bensch and Holmes2002, Thaxter et al. Reference Thaxter, Joys, Gregory, Baillie and Noble2010). Long-term ringing datasets have provided connections to some degree (Wernham et al. Reference Wernham, Toms, Marchant, Clark, Siriwardena and Baillie2002) though many species remain poorly sampled in the wintering areas. More recently, satellite tracking has allowed direct observation of these connections (Meyburg and Meyburg 2007) which has allowed assessment of specific wintering sites used by specific breeding populations, though the occasions on which this has been done explicitly are rather few (Bobek et al. Reference Bobek, Hampl, Peske, Pojer, Simek and Bures2008). However, this kind of detailed diagnosis will be essential if declines in migratory species are to be stemmed. The “Critically Endangered” Northern Bald Ibis Geronticus eremita (BirdLife International 2004) has been considered sedentary on the basis of the majority Moroccan population though the eastern population has long been known to seasonally migrate from their breeding areas. Recent work has demonstrated that they are long distance migrants (Lindsell et al. Reference Lindsell, Serra, Abdallah, al Qaim and Peske2009). In the east their breeding population fell catastrophically during the 20th century, finally being declared extinct in the region in 1989 (Akcakaya Reference Akcakaya1990). Remarkably, a small relict colony of wild birds was discovered in 2002 still breeding in Syria (Serra et al. Reference Serra, Abdallah, Abdallah, Al Qaim, Fayed, Assaed and Williamson2004), but despite intensive protection it had declined to just one pair in 2011. There is an urgent need to identify what is driving the decline of this particular population to have a chance of saving them from extinction. Breeding productivity between 2002 and 2011 averaged 1.3 fledglings per nesting attempt (Serra et al. Reference Serra, Peske, Abdallah, Al Qaim and Kanani2009a and unpubl. data), which compares favourably with the Moroccan population (Bowden et al. Reference Bowden, Smith, El Bekkay, Oubrou, Aghnaj and Jimenez-Armesto2008). Deaths of fully-grown and immature birds were concentrated outside the breeding grounds and the mortality rate of immature birds during the 2-4 year period before their return to the natal site (Serra et al. Reference Serra, Nahaz, Idan, Peske, Savioli, Bruschini and Alomari2009b, Reference Serra, Lindsell, Peske, Fritz, Bowden, Bruschini, Welch, Tavares and WondafrashSerra et al. in press) seems significantly higher than those recorded in similar species (Bairlein Reference Bairlein1981, Schultz et al. Reference Schultz, Cooper and Zicus1988, Menu et al. Reference Menu, Gauthier and Reed2005, Pistorius et al. Reference Pistorius, Follestad and Taylor2006, Gauthier et al. Reference Gauthier, Milot and Weimerskirch2010). The ecology of the Northern Bald Ibis at the Syrian breeding site is well known (Serra et al. Reference Serra, Abdallah and Al Qaim2008, Reference Serra, Nahaz, Idan, Peske, Savioli, Bruschini and Alomari2009b, Lindsell et al. Reference Lindsell, Shehab and Anderson2011) but no data are available about the species’ behavioural ecology, habitat requirements and potential threats on their wintering grounds. In the present study, we sought to determine whether conditions at the wintering site could underlie the failure of this population to improve its status in recent years (Kanyamibwa et al. Reference Kanyamibwa, Schierer, Pradel and Lebreton1990, Berthold and Terrill Reference Berthold and Terrill1991, Saino et al. Reference Saino, Szep, Ambrosini, Romano and Pape Moller2004).

Methods

Study area

The Northern Bald Ibis wintering range (hereafter IWR) is located north of Addis Ababa, Ethiopia, in a remote part of Oromia Regional State, near the border with Amhara Regional State. The site is on the central Ethiopian highland plateau, and is relatively flat and undulating with an altitude ranging between 2,600 and 3,100 m asl. The geographical coordinates of the site are not disclosed for conservation reasons. Settled communities live in scattered settlements located on the tops of gently undulating hills. Mainly teff but also wheat, barley and oats are cultivated on slopes around settlements. Hay is grown in wetter areas along watercourses beside pastures that are also found in higher drier areas. The native vegetation cover of the IWR has been almost totally removed – except for some scattered Acacia trees and some scrub on the fringes of settlements left for protection and shade. Introduced Eucalyptus trees grown for shade and wood predominate around settlements. Observations in other parts of the Ethiopian highlands suggest that the proportion of pastures compared with cultivated fields is relatively high in IWR. There are two wet seasons in this part of the Ethiopian highlands with long rains between July and November and short rains between February and April. At other times it is largely dry. The highest daily temperature range is experienced during the long dry season (November–February). The climate in November 2006 and 2008 was sunny during daytime but cold at night, with an average temperature of 12.6°C (min: -6°C; max: 24°C).

Satellite data collection and analysis

Ibises were tagged with satellite PTTs at breeding grounds in Syria in 2006 (Lindsell et al. Reference Lindsell, Serra, Abdallah, al Qaim and Peske2009). Three satellite tags operated for two winters and one operated discontinuously for five winters. Satellite tags had VHF transmitters attached that operated during the first winter only. Satellite-acquired locations in five consecutive winters (2006–2011; n = 1,067) were filtered to retain only LC class 0–3 (Argos User’s Manual: http://www.cls.fr/manual). We used all LC 0–3 locations (diurnal and nocturnal) for estimating the total IWR, but only LC 2–3 diurnal locations were used for estimating the foraging range because the error associated with less accurate locations is greater than the distances between foraging areas. In order to minimise autocorrelation in the location data we only retained locations that were closer than 3 km to each other, provided more than three hours had lapsed between them. This was in response to field observations indicating that birds often remained in a single foraging area (c.1–3 km in diameter) for protracted periods of time. In order to deal with the high rates of error in Argos location classes (an estimate of 33.3% as indicated in the Argos User’s Manual) we further filtered the location data to discard isolated locations which implied very rapid long distance movements or repeated crossing back and forth across the range; isolated locations that were considered unlikely based on field observations and observed ibis behaviour; isolated nocturnal locations that were distant from the known (or any potential) roost site. Satellite locations were mapped and analysed using ArcGIS 9.2 software (Ackerman et al. Reference Ackerman, Leban, Garton and Samuel1989, Rodgers and Carr Reference Rodgers and Carr1998). We used the fixed-kernel range estimator (Worton Reference Worton1989, Reference Worton1995) to estimate the 50% and 95% utilisation distribution with Hawth’s Analysis Tools extension (www.spatialecology.com/htools/index.php). Satellite telemetry in combination with kernel fitting has been widely employed for the purpose of estimating the spatial range used by wildlife (e.g. Hobbs et al. Reference Hobbs, Laidre, Vos, Mahoney and Eagleton2005, Vashon et al. Reference Vashon, Meehan, Jakubas, Organ, Vashon, Laughlin, Matula and Crowley2008).We selected a smoothing parameter (H) of 1,500 as it minimised the formation of unrealistic isolated clusters at the range edge. Kernel distributions were considered to be the most reliable means of estimating the central area of the IWR (50% core range) and the closest approximation of the total IWR (95%, wider or extended range) (Wiktander et al. Reference Wiktander, Olsson and Nilsson2001, Broomhall et al. Reference Broomhall, Mills and Du Toit2003). The areas concerned (based on 50% and 95% volume contours) were compared with those from breeding grounds in Syria by using the same smoothing parameter (least squares cross-validation; Seaman and Powell Reference Seaman and Powell1996, Hooge et al. Reference Hooge, Eichenlaub and Solomon2004).

Field surveys

Four surveys were carried out at the IWR in November 2006 (11 days), October 2007 (2 days), November 2008 (7 days) and January 2009 (4 days) guided by satellite locations. Besides the three tagged birds there was one untagged adult bird present during 2006–2009 (at least two different individuals during the period) but in 2011 two unidentified subadult birds were also present (Dellelegn Reference Dellelegn2011). The total number of birds present declined during the study, across subsequent winters, which was attributed to mortality (Table 1). Great care was taken to ensure the attention of the local population was not drawn towards the ibises by our activities. The roost site used by the ibises was monitored at roosting time (17h30–18h00) and during the pre-dawn period (06h00–06h15) on at least three different days in 2006. On four different days across three surveys (2006, 2008 and 2009) the birds were observed continuously from their time of departure from their roost until they returned to it after sunset, recording every 10 minutes their behaviour, habitat use and any other significant observation. Due to the VHF transmitters (in 2006 only), their relatively small home range and their repetitive behaviour, the birds’ locations could be identified at any time. Foraging habitat use was assessed by recording the proportion of time spent foraging by birds in each habitat, within 10-minute intervals across the whole day. The average use over two days was calculated for November 2006 and for November 2008–January 2009, separately. Relative availability of foraging habitats was assessed using a GPS for two foraging areas (November 2006) and for the whole IWR (November 2008 and January 2009). The chi-squared goodness-of-fit test was used to test the null hypothesis that habitat usage by ibises occurred in proportion to availability (alpha level of 0.05).We distinguished foraging areas and foraging sites (sensu Bowden and Smith Reference Bowden and Smith1997) such that foraging areas were the overall areas used by the birds either by walking or by short-distance flights (< 200 m) in the course of a day but excluding areas of obviously unsuitable topography. Foraging sites were the smaller individual portions of habitat covered by foraging birds moving on foot within a particular area. The survey in October 2007 was aimed at confirming that the same birds were wintering at the same site, and at briefly assessing the habitats and home range used. The surveys in November 2008 and January 2009 were aimed at supplementing behavioural ecology and conservation observations carried out in 2006. Since the VHF tags were not operational after 2006, birds were located by observing their direction of flight from their roots at dawn and by searching all suitable habitats within the area known to be used by ibises in the past. A preliminary socio-economic and cultural survey was conducted during the 2008 and 2009 field trips (Kubsa Reference Kubsa2009). Forty-three household representatives out of c.153 households in the IWR were randomly sampled and interviewed using a standard questionnaire. Additional information was gained by consulting local authority officers and community leaders.

Table 1. Timing of arrival and departure by Northern Bald Ibis at their wintering site in the highlands of Ethiopia, based on location data from satellite tags, and the estimated area they occupied in each year. Note: precise dates are not always known because the satellite tags do not transmit every day.

* two adults were accompanied by two unknown immature as reported by Dellelegn (Reference Dellelegn2011).

Results

Determination of the Ibis Wintering Range (IWR)

The Northern Bald Ibises from Syria used the same wintering site in Ethiopia for five successive winters from 2006 to 2011. The timings and numbers of birds present are shown in Table 1. After filtering, 442 satellite locations (41% of the total) were retained for analysis of home ranges. There was a high degree of overlap in the area used by the birds in each year (Figure 1). The core area (50% volume contour) used by the wintering ibises had a mean area 13.1 km² (CI +/- 3.5) whilst the wider range (95% volume contour) was 80.8 km² (CI +/- 25.3) (Figure 2). The annual areas used by the birds are shown in Table 1.The area used by the ibises from all five years considered together was 10.6 km² for the core and 100.5 km² for the wider range. The core area was thus 10.6% of the wider range. The area shared by the annual 50% volume contours covered 81.1% of the 50% contour calculated from pooling data across all years. The equivalent figure for the 95% contour was 41.5%. More stringent filtering for analysis of the foraging range (LC 2–3 only, nocturnal locations excluded) meant that of 116 acceptable locations only 17 came from the last three winters (and from only one bird), so the pattern is dominated by data from the first two years. The foraging range had a core area (50% volume contour) of 12.1 km² and a wider range (95% contour) of 70.9km² (Figure 3). The satellite data also showed four excursions made outside the main wintering range for limited periods, the nearest being 7.5 km away from the usual roost and the furthest 27 km away. This latter excursion, at its furthest point, came within c.6 km of the last known record of Northern Bald Ibis in Ethiopia from c.30 years ago, when six bald ibises were observed in January 1977 (Ash and Howell Reference Ash and Howell1977). One of these four excursions likely entailed a change of roost for at least seven days in August 2007.

Figure 1. The degree of overlap of annual winter ranges across five consecutive winters in Ethiopia (2006/2007 to 2010/2011). Boundaries shown are volume contours from a kernel analysis of diurnal and nocturnal locations: a) overlap of the 95% volume contours with darker shaded areas being used in more years; b) overlap of the 50% volume contours with the 95% contours shown for reference.

Figure 2. Winter range of N. Bald Ibises in Ethiopia estimated from diurnal and nocturnal satellite locations (n = 442) over five consecutive winters (2006/2007 to 2010/2011). Core and wider winter ranges are expressed by 50% and 95% volume contours of a kernel analysis (dark grey and light grey, respectively). The area of the 50% contour = 10.62 km²; area of the 95% contour = 100.51 km². Individual satellite locations of ibises are shown.

Figure 3. Winter foraging range of N. Bald Ibises estimated from diurnal satellite locations (n = 116) over five consecutive winters (2006/2007 to 2010/2011). Core and wider winter ranges are expressed by 50% and 95% volume contours from a kernel analysis (dark grey and light grey, respectively). Area of 50% kernel = 12.10 km². Area of 95% kernel = 70.89 km². Individual satellite locations of ibises are shown.

Foraging habitats

In November 2006, only two distinct foraging areas were used by all four ibises, located about 3 km apart from each other, with an estimated area of c.30.9 ha (area 1) and 247.6 ha (area 2). Birds were observed commuting between them several times a day. Ibises preferentially selected freshly cut hayfields at area 1 (chi-squared test = 195.33, df = 1, P < 0.001) and overgrazed pastures at foraging area 2 (chi-squared test = 262.17, df = 1, P < 0.001) (Figure 4). Cultivated and fully-grown hayfields in both areas were ignored. Freshly cut hayfields were used by birds for a few days after cutting until they had turned dry and yellowish. Birds used five different patches of pastures within area 2. In November 2008 and January 2009, ibises only used overgrazed pastures, even though 53% of the core IWR comprised cultivated fields and hayfields (both fully-grown and cut) (chi-squared test = 112.77, df = 1, P < 0.001) (Figure 4). Both sloping wet pastures in proximity to streams, and flat and dry higher pastures closer to villages were used. On the higher pastures they focused on drier patches probing cracks in the soil for larvae. Unlike in November 2006, ibises did not use freshly cut hayfields in November 2008, despite being apparently available.

Figure 4. Three different comparisons are presented of time spent foraging by the four ibises in each habitat (usage/dark bars) versus the proportion of area available of each habitat type (availability/white bars) over three total areas considered: foraging area 1 (FA1), foraging area 2 (FA2) and the IWR core range. Observations collected in FA1 and FA2 were recorded during two full days in November 2006 while those collected within the core IWR were recorded during two full days in November 2008 and January 2009. In each area the remainder of the habitat consisted of cultivated ground or uncut hay (and cut hay in the case of IWR).

Behavioural observations

The ibises moved as a flock on the wintering site. The daily pattern of usage of the two main foraging areas was rather stable during 2006. Few flights were observed and only during transfer from one foraging area to another. At times, foraging Northern Bald Ibises formed mixed flocks with Wattled Ibis Bostrychia carunculata, Cattle Egret Bubulcus ibis and Sacred Ibis Threskiornis aethiopicus especially when on hayfields close to streams. Foraging areas of Northern Bald Ibises and Wattled Ibises overlapped on hayfields, but the latter species also used fully-grown hayfields. Northern Bald Ibises were also seen resting together with Wattled and Sacred Ibises by ponds and streams. The all-day following of the Northern Bald Ibises showed that birds spent 55–85% of the day foraging and the rest on bathing, preening and resting. The roost site used by the Northern Bald Ibises was a patch of c.20m high Eucalyptus grandis trees (c.40–50 years old), in a small settlement on a low hill overlooking most of the IWR. The satellite data confirmed this as the habitual roost site. The trees were shared with roosting Pied Crows Corvus albus and 30–50 Wattled Ibises, Cattle Egrets and Sacred Ibises. The Northern Bald Ibises used the same individual tree during almost three winters (2006–2008) but were forced to move in January 2009 due to the felling of this tree by local people. Beside waterbirds and cranes, the area seems to be an important feeding/wintering site for birds of prey (vultures, eagles, harriers). Alert reaction behaviour and frequent looking at the sky were observed several times in relation to passage of large eagles (Aquila clanga, A. rapax and A. nipalensis). At times, proximity of a raptor would even prompt the sudden flushing of ibises. Northern Bald Ibises are fully dependent on human-modified habitats in the IWR. On most days they are in close proximity to people working in fields or herding livestock. Neither disturbance nor negative interaction was observed between the birds and the local community. We observed no significant difference in Northern Bald Ibis behaviour or their selection of feeding areas with people present or absent in November 2006 (working days versus Sundays). People do not show any interest towards birds foraging on the hayfields and on pastureland. Reportedly, local people, in line with their culture and traditional beliefs, do not usually hunt birds - though in some areas they may trap ground birds such as francolins. The most common observed interaction between birds and humans was a short flight (30–80 m) to avoid the close approach of people or herds of livestock. Most evasion by the ibises was made on foot. As indicated above, the roost sites at times may become vulnerable to human disturbance.

Socio-economic conditions

The local community in the IWR belongs to the Oromo ethnic group, which is the largest in the country. In the IWR people typically subsist on rain-fed agriculture and livestock husbandry. There is neither electricity nor a road network in the area and illiteracy rates are high. Land is owned by the State and people have usage rights either as leaseholders or against payment of land revenue taxes. Most extended families, averaging 6–9 individuals, live in small settlements of straw-roofed huts. The population and household densities in the IWR were 0.55/ha and 0.08/ha respectively (2008–2009). Each household has its own cultivated fields and pastures adjacent to the settlement and owns on average 10–15 cattle, and sometimes also sheep, donkeys and horses. They use water from streams for drinking, cooking, bathing and washing. About 18% of the people living in the IWR and surrounding area are listed as food insecure and thus need some assistance in the form of food-for-work. Rain-fed crop cultivation is subject to nocturnal frost and annual variability in rainfall. The area can produce two harvests a year provided that rainfall is sufficient. However, in certain years the population is subjected to food shortages due to the failure of crops during one or both of the seasons. People interviewed in winter 2008/2009 described their main survival problems as rainfall variability, land shortage, decreasing soil fertility and erosion. Decreasing fertility and soil erosion have induced an increasing number of young people to emigrate to urban centres. Reportedly there had been some use of fertilisers, especially in the past, but this practice is decreasing due to rising costs. The local agricultural office promotes the use of organic fertiliser compost as opposed to inorganic synthetic fertilisers. It was reported that there has never been a significant use of pesticides within the district and no evidence to the contrary was noted during fieldwork.

Estimated threats

We judge that the following issues have the potential to threaten the persistence of ibises at the wintering site:

Short to medium term

  • - external visitors and/or informed local authorities drawing the attention of local people toward the ibises and the markers they carry such as coloured rings and PTTs;

  • - rainfall shortages resulting in reduction in food availability for the local community;

Medium to long term

  • - conversion of hayfields and pastureland into cultivations;

  • - increased use of agricultural fertilisers or pesticides which are believed to be harmful to ibises.

Discussion

Satellite tracking of Northern Bald Ibises from the last known colony of the eastern population showed a high degree of winter site fidelity across five years (Berthold Reference Berthold2001), similar to that shown by Black Stork Ciconia nigra (Bobek et al. Reference Bobek, Hampl, Peske, Pojer, Simek and Bures2008) and cranes (Berthold Reference Berthold2001), and differing from the partial winter site fidelity observed in the White Stork C. ciconia (Van den Bossche Reference Van den Bossche2002). Field observations, focused on the IWR core area, suggested almost complete overlap of the wintering range from year to year and satellite telemetry confirmed this across the five winters. Data clearly show that the area of overlap is in the centre of the ranges (both at 50 and 95%) confirming IWR core area stability across years and ibis fidelity to it. Integration of satellite data and field observations suggested that within each winter period the home range tends to increase in size as ecological conditions dry out and food presumably becomes scarcer (Serra et al. Reference Serra, Peske and Wondafrash2006, Serra and Wondafrash Reference Serra and Wondafrash2009), as has been observed for wintering Black Storks (Chevallier et al. Reference Chevallier, Le Maho, Baillon, Duponnois, Dieulin, Brossault, De Franclieu, Lorge, Aurouet and Massemin2010a).The IWR location is consistent with past historical records of Northern Bald Ibises belonging to the eastern population (Welch and Welch Reference Welch and Welch2005, Ash and Atkins Reference Ash and Atkins2009). The site is only 30 km from the last recorded observation of Northern Bald Ibises in Ethiopia (Ash and Howell Reference Ash and Howell1977). The highland environment where the IWR is located, and its surroundings, are a mix of croplands, pasturelands and degraded stony savanna, an environment already identified as important for bird conservation (Aerts et al. Reference Aerts, Lerouge, November, Lens, Hermy and Muys2008). Pastures may be more abundant at IWR than in other plateau areas where cultivated fields prevail and there are indications that the IWR is wetter than other areas in the Ethiopian highlands at an equivalent altitude (Kubsa Reference Kubsa2009). The preference of Northern Bald Ibises for a relatively humid environment during winter in Ethiopia contrasts with their extremely arid breeding environment in Syria (Serra et al. Reference Serra, Nahaz, Idan, Peske, Savioli, Bruschini and Alomari2009b) - although at wintering grounds they use both wet habitats (hayfields) and the dry pastures. The core breeding range for Northern Bald Ibis in Syria was estimated at 253 km2 (Serra et al. Reference Serra, Bruschini, Lindsell, Peske and Kanani2011), some 20 times larger than the estimated core wintering range in Ethiopia. The wider breeding range in Syria was 1,313 km2 (Serra et al. Reference Serra, Bruschini, Lindsell, Peske and Kanani2011), which is c.60 times larger than the wider wintering range in Ethiopia. Large differences in breeding and wintering home range size have also been observed in Black Storks (Chevallier et al. Reference Chevallier, Le Maho, Baillon, Duponnois, Dieulin, Brossault, De Franclieu, Lorge, Aurouet and Massemin2010a) though the difference was less pronounced in that species. For the ibises this difference is most easily explained by the substantial ecological contrast between the relatively humid Ethiopian highlands and the arid Syrian desert. The ratio between the core and the wider wintering range is similar in Northern Bald Ibis and Black Stork (Chevallier et al Reference Chevallier, Le Maho, Baillon, Duponnois, Dieulin, Brossault, De Franclieu, Lorge, Aurouet and Massemin2010a) but much smaller than in the ibis breeding grounds. Although these differences could be explained by the need for different food sources and energy requirements during winter versus breeding periods it could also be related to the serious ecological degradation of the Syrian steppe (Serra et al. Reference Serra, Nahaz, Idan, Peske, Savioli, Bruschini and Alomari2009b), which far exceeds any degradation in the wintering site. The ibises proved to be quite consistent in their use of foraging areas and sites. Two feeding habitats were recorded to be used by birds during the field surveys: cut hayfields (as observed in November 2006) and pastures (as observed in November 2006, November 2008 and January 2009). Similarly two kinds of habitats are favoured by wild Northern Bald Ibis in Morocco (Bowden et al. Reference Bowden, Smith, El Bekkay, Oubrou, Aghnaj and Jimenez-Armesto2008) and by hand-raised and semi-captive ibises in Austria and Italy (Zoufal et al. Reference Zoufal, Fritz, Bichler, Kirbauer, Markut, Meran, Wolf and Kotrschal2006). In Syria they complement the use of pastures as a source of food with the shores of artificial reservoirs, seasonally abundant in young frogs (Serra et al. Reference Serra, Abdallah and Al Qaim2008). However, during the two surveys undertaken in winter 2008/2009 only pastures were observed to be used, despite the availability of freshly cut hayfields. It is not clear why the birds did not use cut hayfields that winter but it was possibly because of elevated prey levels in the pasture linked to the delayed termination of the long rainy season in that year. Unlike Wattled Ibis, Northern Bald Ibis avoided tall grass (Bowden et al. Reference Bowden, Aghnaj, Smith and Ribi2003, Kopij Reference Kopij2001) only using hayfields once they were cut. As on the breeding grounds (Serra et al. Reference Serra, Abdallah and Al Qaim2008) and unlike on migration (Serra Reference Serra2010), ibises avoided cultivated fields for foraging at IWR, even abandoned fields, despite these being used by other birds such as Wattled Ibis and Common Crane Grus grus. Macro-invertebrates and micro-vertebrates observed in cut hayfields and pastures matched well with the diet of ibises at breeding grounds (Serra et al. Reference Serra, Peske and Wondafrash2006, Reference Serra, Abdallah and Al Qaim2008, Serra and Wondafrash Reference Serra and Wondafrash2009). By contrast, the diet of Black Storks at breeding and wintering grounds differed substantially (Chevallier et al. Reference Chevallier, Le Maho, Baillon, Duponnois, Dieulin, Brossault, De Franclieu, Lorge, Aurouet and Massemin2010a). Occurrence of water-bodies and safe sites along their shores is important for resting of ibis that typically takes place around mid-day, as was also observed at breeding grounds in Syria (Serra et al. Reference Serra, Abdallah and Al Qaim2008) and for White Storks (Van den Bossche Reference Van den Bossche2002). The behaviour of the two ibis pairs at their wintering grounds was consistent across three winter seasons. They were very gregarious at IWR, as noted also at the breeding grounds (Serra et al. Reference Serra, Peske, Abdallah, Al Qaim and Kanani2009a). Ibises started courtship displays at IWR in January 2009, some weeks before the spring migration, consistent with past observations that bald ibises would arrive in Birecik already paired (Pegoraro Reference Pegoraro1996) and with similar observations for cranes (McNulty Reference McNulty1966, Archibald and Meine Reference Archibald, Meine, Del Hoyo, Elliott and Sargatal1996). Satellite tracking observations during return migrations in 2007 and 2008 suggested that one particular established pair migrated northward together, at least during the first part of the migration (unpubl. data). The ibises were also consistent in the use of a specific roost site, similar to what has been observed in the Syrian breeding grounds (Serra et al. Reference Serra, Peske, Abdallah, Al Qaim and Kanani2009a) but differing from White and Black Storks (Van den Bossche Reference Van den Bossche2002, Chevallier et al. Reference Chevallier, Duponnois, Baillon, Brossault, Grégoire, Eva, Le Maho and Massemin2010b). However, whereas they used a tree to roost in Ethiopia as they do along the migration route (Serra Reference Serra2010) in the breeding area they depend on rocky cliffs (Serra et al. Reference Serra, Peske, Abdallah, Al Qaim and Kanani2009a). On people approaching, recorded flight distances seemed quite short (around 30–80 m) compared with that recorded on Syrian breeding grounds (100–150 m), suggesting less fear of humans at IWR. This is consistent with the more severe human disturbance observed in Syria than in Ethiopia (Serra et al. Reference Serra, Peske, Abdallah, Al Qaim and Kanani2009a), despite a lower human density at the former (Chevallier et al. Reference Chevallier, Le Maho, Baillon, Duponnois, Dieulin, Brossault, De Franclieu, Lorge, Aurouet and Massemin2010a): this is due to the greater accessibility of the breeding environment to vehicles and also to the fact that hunting is deeply rooted in the Arab desert culture (and enforcement of regulations is insufficient). Observation of intense gazing at the sky and alarming behaviour during the passage of large eagles (Aquila spp.) over the wintering site, suggested that bald ibises might be preyed upon by these large raptors (Loretto et al. Reference Loretto, Schloegl and Bugnyar2009). Overall, no evident short-term threat was recognised during the winter surveys, except that attracting too much interest on the part of the local community towards the ibises might confer unwelcome attention on them. The chances are that even in these very favourable conditions, it would be extremely difficult to eliminate the potential risks to which 3–4 birds might become suddenly exposed, without establishing an intensive awareness and protection programme. Therefore, subject to periodic reassessment, the most cost-effective conservation approach to maintain the current situation where the birds remain undisturbed seems to consist of not publicising the occurrence of these birds or paying unnecessary visits to the site. A key threat to the birds in the medium and long term comes from the precariousness of the local subsistence economy that seems to be becoming increasingly unsustainable as ecological degradation of the agro-ecosystem proceeds. The typical annual variation in rainfall on the Ethiopian highlands has negatively combined in recent decades with increasing soil infertility and erosion, and with “land shortage” as described by Kubsa (Reference Kubsa2009) relative to IWR. Traditional agriculture has been carried out for millennia on the Ethiopian highlands (Fenta Reference Fenta2000), but population density in Ethiopia has reached unprecedented levels during recent decades (CSA 2008) and the Ethiopian highlands have become among the most densely populated agricultural areas in Africa (WWF 2011). Unlike other parts of Ethiopia, IWR does not seem to present a short-term threat from agricultural intensification through irrigation and the use of fertilisers and pesticides, which are likely to be detrimental to the ibis foraging habitat (Hirsch Reference Hirsch and Temple1977, Akcakaya Reference Akcakaya1990), but this specific issue needs on-going monitoring.

We conclude that the steady decline of the colony of Northern Bald Ibis breeding in Syria is most likely not caused by impacts on the wintering grounds in Ethiopia. As a consequence, urgent attention needs to be focused on threats along the migratory route and at its key staging sites.

Recommendations

Short term

  • ▪Undertake low profile visits to monitor the birds and their habitats every 2–3 years

  • ▪ensure contact with local authorities to ensure their cooperation in not publicising the site

  • ▪dissuade birdwatchers from visiting the area (geographic coordinates and the name of the site should not be publicised)

Medium term

  • ▪review any land-use changes in the area bi-annually

  • ▪search for possible additional bald ibises wintering on the central Ethiopian plateau

  • ▪should the Syrian colony start to recover, plan for ecologically sustainable poverty reduction schemes in the area and raise levels of ecological awareness (Dejene et al. Reference Dejene, Zeleke, Abate and Lule2004).

Acknowledgements

We are indebted to the District of Agriculture and Rural Development Office (DARDO), especially to Mr Getiye Girma and Mr Gutta Haleko, and to Mr Getu Robi and Mr Tashome Yifru from Abicu fi Nya’a District Agricultural Office. In particular, we warmly thank Mr Solomon Feyisaa, the Chairperson of Doyo-Dawee Peasant Association, and all the local community interviewed. Field surveys were carried out in cooperation with, and full involvement of, the competent local authority, the Agricultural District of Mendida. The surveys were organised by the Ethiopian Wildlife Natural History Society (EWNHS), with financial support by National Geographic Society, the Italian Development Cooperation Program (DGCS), RSPB, Chester Zoo and the African Bird Club/Wildwings Annual Conservation Award.

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Figure 0

Table 1. Timing of arrival and departure by Northern Bald Ibis at their wintering site in the highlands of Ethiopia, based on location data from satellite tags, and the estimated area they occupied in each year. Note: precise dates are not always known because the satellite tags do not transmit every day.

Figure 1

Figure 1. The degree of overlap of annual winter ranges across five consecutive winters in Ethiopia (2006/2007 to 2010/2011). Boundaries shown are volume contours from a kernel analysis of diurnal and nocturnal locations: a) overlap of the 95% volume contours with darker shaded areas being used in more years; b) overlap of the 50% volume contours with the 95% contours shown for reference.

Figure 2

Figure 2. Winter range of N. Bald Ibises in Ethiopia estimated from diurnal and nocturnal satellite locations (n = 442) over five consecutive winters (2006/2007 to 2010/2011). Core and wider winter ranges are expressed by 50% and 95% volume contours of a kernel analysis (dark grey and light grey, respectively). The area of the 50% contour = 10.62 km²; area of the 95% contour = 100.51 km². Individual satellite locations of ibises are shown.

Figure 3

Figure 3. Winter foraging range of N. Bald Ibises estimated from diurnal satellite locations (n = 116) over five consecutive winters (2006/2007 to 2010/2011). Core and wider winter ranges are expressed by 50% and 95% volume contours from a kernel analysis (dark grey and light grey, respectively). Area of 50% kernel = 12.10 km². Area of 95% kernel = 70.89 km². Individual satellite locations of ibises are shown.

Figure 4

Figure 4. Three different comparisons are presented of time spent foraging by the four ibises in each habitat (usage/dark bars) versus the proportion of area available of each habitat type (availability/white bars) over three total areas considered: foraging area 1 (FA1), foraging area 2 (FA2) and the IWR core range. Observations collected in FA1 and FA2 were recorded during two full days in November 2006 while those collected within the core IWR were recorded during two full days in November 2008 and January 2009. In each area the remainder of the habitat consisted of cultivated ground or uncut hay (and cut hay in the case of IWR).