4. OWLS
of the World
Second Edition
Claus König and Friedhelm Weick
with a contribution on molecular evolution by Michael Wink,
Petra Heidrich, Hedi Sauer-Gürth, Abdel-Aziz Elsayed and Javier Gonzalez
Christopher Helm
London
6. Contents
Introduction 12
Acknowledgements 13
Layout of the Book 15
Owls: an overview 18
Morphology and anatomy 18
Topography 22
Food 24
Hunting 24
Behaviour 26
Breeding 29
Vocalisations 32
Systematics and taxonomy 34
How to study owls 39
Conservation 39
Molecular phylogeny and systematics of the owls (Strigiformes)
by Michael Wink et al. 42
Colour plates 64
Systematic section 209
Tyto
Common Barn Owl Tyto alba 209 1
American Barn Owl Tyto furcata 211 2
Curaçao Barn Owl Tyto bargei 212 2
Ashy-faced Barn Owl Tyto glaucops 213 2
Lesser Antilles Barn Owl Tyto insularis 214 2
Galápagos Barn Owl Tyto punctatissima 215 3
Cape Verde Barn Owl Tyto detorta 215 3
São Tomé Barn Owl Tyto thomensis 216 3
Andaman Barn Owl Tyto deroepstorffi 217 2
Madagascar Red Owl Tyto soumagnei 217 3
Australian Barn Owl Tyto delicatula 218 3
Boang Barn Owl Tyto crassirostris 219 3
Golden Masked Owl Tyto aurantia 220 4
Taliabu Masked Owl Tyto nigrobrunnea 220 4
Minahassa Masked Owl Tyto inexspectata 221 6
Lesser Masked Owl Tyto sororcula 222 5
Manus Masked Owl Tyto manusi 222 5
Sulawesi Masked Owl Tyto rosenbergii 223 5
Australian Masked Owl Tyto novaehollandiae 224 5
Tasmanian Masked Owl Tyto castanops 225 5
African Grass Owl Tyto capensis 226 4
Eastern Grass Owl Tyto longimembris 227 4
Lesser Sooty Owl Tyto multipunctata 228 6
page plate
13. 12
Introduction
Owls are fascinating birds. Most species spend the day hidden in the dense foliage of trees, in holes or in the
dusky attics of large buildings. Normally humans, as diurnal beings, are only conscious of their presence from
their vocalisations. Because of their nocturnal habits, owls have been regarded by superstitious people as birds
of ill omen. They have been associated with death, although the Greeks considered them wise. The Little Owl
Athene noctua, abundant in the Mediterranean, was given its generic name Athene because of its association with the
Greek goddess of wisdom, Pallas Athene, the patron deity of Athens. In Central Europe, Little Owls are locally still
considered to be bringers of bad luck, portending sickness and approaching death. But times have changed,
and owls now hold a great fascination, both for birders and for academics. Many owl species are protected by
law worldwide but, through the destruction of their habitats and the use of pesticides, many others are severely
endangered.
An increasing number of ornithologists (amateur and professional) go out at dusk or before dawn in order to
study owls in the wild. Groups of owl enthusiasts in many countries exchange the results of their investigations and
international meetings of owl specialists are no longer rare. Through international cooperation and research our
worldwide knowledge of owls has increased. Nevertheless there are still gaps in our understanding of owl biology
and behaviour. Some species are known almost entirely by skins in museums. Several species are extinct and their
biology will remain a mystery. Studies of endangered species are much needed and adequate measures for their
conservation must be devised.
Many bird books are published every year but owls are treated cursorily in most of them. Books devoted to
the order are rare and none of them deals with all the species. This demonstrates a lack of information on owl
taxonomy and stresses the fact that it is still very difficult to identify several species correctly. Many species show a
great degree of variation in plumage and coloration. Taxonomic studies based on comparing museum specimens
alone cannot solve the problem and species limits in some genera are still poorly defined. Studies on ecology,
behaviour and vocalisations are of overwhelming importance. We have tried to address these problems in this
book, which describes all known owl species with illustrations and distribution maps.
The first (1999) edition of this book was well received and is now out of print, which has encouraged the
publishers to ask us to prepare this revised and enlarged second edition. The text and bibliography have been
brought up to date and new colour plates have been added, to reflect changes in the taxonomic literature and a
number of species entirely new to science. Moreover, all 64 of the original colour plates have been revised and cor-
rected where necessary, and eight new plates added. The chapter on DNA evidence has been updated by Michael
Wink and colleagues.
This new edition may be used both as an identification guide and as a source of information on owl ecology
and biology, especially for some of the lesser known species. It also points out where gaps in information exist. We
hope to stimulate ornithologists to research these poorly known taxa and provide material for future editions. The
book is a companion for all who research owls in the field; at home or in the laboratory it is a reference book for
comparing observations and voice recordings.
July 2008
Claus König & Friedhelm Weick
14. 13
Acknowledgements
The authors are greatly indebted to many institutions and people for their kind and very helpful cooperation.
Without their assistance it would not have been possible to undertake the large amount of work involved. We
thank the following museums and other scientific institutions: Administración de Parques Nacionales, Buenos
Aires, Iguazú, Salta, and Santa Cruz, Argentina (M. Jannes); American Museum of Natural History, New York, USA
(M. LeCroy); Asociación Ornitológica del Plata, Buenos Aires, Argentina (R. Guerra, T. Narosky); British Museum
of Natural History (Natural History Museum, Bird Section), Tring, UK (Dr M. Adams, P. R. Colston); British Li-
brary, National Sound Archive, London, UK (R. Ranft); Laboratory of Ornithology, Cornell University, NY, USA;
Dept. Biology, York College, PA, USA (Prof. R. Clark); Deutsche Forschungsgemeinschaft (German Research
Foundation), Bonn, Germany; Florida State Museum of Natural History, Gainesville, USA (Dr J. W. Hardy, Dr T.
Webber); Forschungsinstitut und Naturmuseum Senckenberg, Frankfurt a.M., Germany (the late Dr J. Steinba-
cher, Dr G. Mayr, Prof. Dr D. Peters); Fundación Vida Silvestre Argentina, Buenos Aires, Argentina (A. Johnson);
Gesellschaft zur Förderung des Naturkundemuseums, Stuttgart, Germany; Institut für Pharmazeutische Biologie
der Universität Heidelberg, Germany (Dr. P. Heidrich, Prof. Dr M. Wink); Institut für Zoologie der Universi-
tät Heidelberg, Germany (Prof. Dr H. Moeller); Institute of Zoology, Taipeh, Taiwan (Dr L. Liu-Severinghaus);
IRSNB-Section Evol. Birds, Bruxelles, Belgium (Dr R. Lafontaine); Instituto Miguel Lillo, Tucumán, Argentina
(Lic. E. Alabarce); Instituto Nacional de Entomología INESALT, Rosario de Lerma, Argentina (the late Dr M.
Fritz); Instituto de Zoologia, Universidade de Campinas, SP, Brazil (Prof. J. Vielliard); Kansas Museum of Natural
History, Kansas, USA (Dr M. Robbins); Konnikligh Museum van Midden Afrika, Tervuren, Belgium (Dr M. Lou-
ette); Louisiana State Museum of Natural History, Baton Rouge, USA; Museo Argentino de Ciencias Naturales,
Buenos Aires, Argentina (Dr J. Navas, R. Straneck); Museo de Historia Natural de la Universidad de San Marcos,
Lima, Peru (Dr I. Franke); Museo Nacional, Rio de Janeiro, Brazil (the late Prof. Dr H. Sick, D. Teixeira), Museo
de Ciencias Naturales, University of Salta, Argentina (the late G. Hoy, Prof. Dr L. Novara); Museo de La Plata, La
Plata, Argentina (Dr N. Bó); Museum für Naturkunde, Berlin, Germany (the late Dr G. Mauersberger, Prof. Dr B.
Stephan, Prof. Dr D. Wallschläger, the late Dr K. Wunderlich); Museum Heineanum, Halberstadt, Germany (Dr
Nicolai); Muséum d’Histoire Naturelle, St. Denis, Réunion (Dr M. Le Corre); Musée Zoologique de l’Université
de Strasbourg, France (M. Wandhammer); Nationaal Naturhistorisch Museeum, Leiden, The Netherlands (Dr R.
Dekker), National Museum of Natural History, Washington, USA (Dr J. T. Marshall); Natural History Museum,
Helsinki, Finland (Dr P. Saurola); Naturhistorisches Museum, Basel, Switzerland (Dr R. Winkler); Naturhistori-
sches Museum, Wien, Austria (Dr K. Bauer, Dr E. Bauernfeind, Dr H. Schifter); Pfalzmuseum für Naturkunde,
Bad Dürkheim (Dr R. Flößer); Staatliches Museum für Naturkunde, Stuttgart, Germany (R. Buob, M. Grabert, Dr
A. Schlüter, Dr. F. Woog); Staatliches Museum für Naturkunde, Karlsruhe, Germany (Prof. Dr S. Rietschel); Staat-
liches Museum für Naturkunde, Dresden, Germany (the late Dr.S. Eck); Tierpark Berlin, Berlin, Germany (the
late Dr Frädrich, Dr W. Grummt, Prof. Dr H. Klös); Übersee-Museum, Bremen, Germany (Dr H. Hohmann); Vo-
gelpark Walsrode, Walsrode, Germany (R. Brehm); Vogelwarte Radolfzell, Möggingen, Germany (R. Schlenker);
Wildlife Conservation Society, New York, USA (J. A. Hast); Zoologisches Forschungsinstitut und Museum Alexan-
der Koenig, Bonn, Germany (Dr R. van den Elzen, the late Prof. Dr C. Naumann); Zoologische Staatssammlung
des Bayerischen Staates, München, Germany (Prof. Dr J. Reichholf); Zoologisches Museum, Hamburg, Germany
(Dr S. Hoerschelmann, the late Prof. Dr H. Koepcke); Zoologisk Museum, Copenhagen, Denmark (Dr J. Fjeldså,
Dr. N. Krabbe), GLOW - Global Owl Project GLOW (David Johnson, Alexandria (Virginia), USA, Conservation In-
ternational, Belo Horizonte (MG), Brazil (A. Margit); Universidade Federal de Pernambuco, Recife, Brazil (Prof.
Dr. J.M. Cardoso da Silva), USDA Forest Service, Northern Region (Dr.M. Nelson, St. Paul, MN, USA)..
We are also indebted for the recording of owl voices to the following for their kind cooperation and advice
on several items: Dr R. Behrstock, Houston, USA; K. D. Bishop, Australia; Dr T. Butynski, Zoo Atlanta, Nairobi,
Kenya; Prof. Dr. R. Clark, York College, USA; G. Dutson, Cambridge, UK; G. Ehlers, Leipzig, Germany; Dr R.
Ertel, Remseck, Germany; R. Foerster, Iguazú, Argentina; Dr J. Haffer, Essen, Germany; Dr J. W. Hardy, Gaines-
ville, Florida, USA; Dr G. P. Hekstra, Harich, The Netherlands; Dr J. C. Heij, Netherlands; Dr D. G. W. Hollands,
Orbost, Australia; the late Dr D. A. Holmes, Indonesia; S. N. G. Howell, Stinson Beach, California, USA; the late
G. Hoy, Salta, Argentina; W. Jörlitschka, Pforzheim, Germany; Juni Adi, Indonesia; H. Kaiser, Villingen, Ger-
many; Dr M. Kessler, Münster, Germany; L. Koerner, Kiel, Germany, Dr N. Krabbe, Quito, Ecuador; R. Krahe,
Smithers, Canada; J. & I. Kuehl, Salta, Argentina; the late O. Lakus, Hambrücken, Germany; Dr F. Lambert,
Bogor, Indonesia; A. Margit, Belo Horizonte (MG) Brazil, Dr J. T. Marshall, Washington, USA; J Mazar Barnett,
Argentina; Prof. Dr B.-U. Meyburg, Berlin, Germany; P. Morris, UK; Y. Muller, Eguelshardt, France; the late Dr
T. A. Parker III, Baton Rouge, USA; Dr M. S. Prana, Indonesia; the late Dr C. C. Olrog, Tucumán, Argentina; Dr
J. Olsen, Canberra, Australia; R. Ranft, National Sound Archive, London, UK; Dr P. C. Rasmussen, Smithsonian
Institution, USA; O. v. Rootselaar, Renkum, The Netherlands; R. J. Safford, Cambridge, UK; R. Schaaf, Ludwigs-
burg, Germany; Prof. Dr W. Scherzinger, St. Oswald, Germany; D. Schmidt, Stuttgart, Germany; S. Smith, UK;
15. 14
R. Steinberg, Radevormwald, Germany; Prof. F. G. Stiles, Bogotá, Colombia; R. Straneck, Cordoba, Argentina;
D. V. M. Sudharto, Indonesia; Dr W. Thiede, Köln, Germany; the late Prof. Dr K. H. Voous, Huizen, The
Netherlands; the late W. Weise, Clausnitz, Germany; Dr D. R. Wells, England. For technical help in digitalising
recordings, we thank D. Hagmann of Stuttgart Natural History Museum, Germany.
We particularly wish to give our most cordial thanks to Mrs Ingrid König, who was a patient and well-informed
assistant of Claus König both in the field in Africa, South America and Europe, and in the laboratory. In addition
Ingrid contributed important recordings during our field investigations. We also thank Mrs Christel Weick for her
great and indefatigable support at home and when visiting museums, institutes, etc. with her husband, and for her
warm hospitality to all visiting ornithological friends and colleagues from near and far.
We owe many thanks to our colleague Dr Jan-Hendrik Becking for his highly appreciated contributions to the
first edition of 1999, which have been incorporated into this new edition.
Last but not least we thank the late Christopher Helm, Nigel Redman and Jim Martin for their guidance and
patience throughout this project, Julie Dando for her expertise in the design and production of the book, and
David Christie, Ernest Garcia and Tim Harris for editorial support over the two editions.
16. 15
Layout of the book
The introductory chapters are fairly brief, but many line drawings are included to illustrate the points discussed.
The plates and species accounts comprise the greater part of the book. There is a strong emphasis on identification
and vocalisations in the species accounts but other aspects of biology and ecology are also covered where known.
INTRODUCTORY CHAPTERS
Owls: an overview
This chapter gives an overview of owl biology and behaviour and is subdivided into a number of sections covering
Morphology and Anatomy, Topography, Food, Hunting, Behaviour, Breeding, Vocalisations and Systematics and
Taxonomy.
Molecular evolution and systematics of the owls
An invited chapter by Michael Wink et al. gives an up-to-date assessment of owl systematics according to DNA
evidence. It also highlights that further changes in owl taxonomy are likely as more material becomes available
for analysis.
The introductory chapters conclude with some hints on studying owls and an overview of owl conservation.
PLATES
The 72 colour plates illustrate all known species of owls, showing their different colour morphs and often their
juvenile plumages. Many of the more distinct subspecies are also illustrated. All species on a plate are painted to
the same scale but the inserts (e.g. birds in flight) are of a reduced size. The plate captions give, for each species,
a brief summary of world range and the most important diagnostic features of each form or plumage illustrated.
Small versions of the maps from the species accounts are reproduced here in colour. Cross references to species on
different plates are given in the format (plate number: species number on plate).
SPECIES ACCOUNTS
Each genus begins with an introduction summarising key features and dealing with general structural differences
which will enable separation from sympatric owl genera. Each species account is subdivided as follows:
Names
English and scientific names are given for every species. Names are also given in French, German and Spanish
and, where relevant, in Portuguese.
First description
The name of the first description (oldest valid name) is given, together with author, source and type locality.
Identification
These sections give key features for field identification and should be used in conjunction with the plates. Similar
species: Confusable species are mentioned, with a summary of the principal criteria for separation. This section
is largely concerned with sympatric species. In some cases, no other species of owl occurs sympatrically with the
species concerned.
Vocalisations
Voice transcriptions are included where available. Most have been transcribed by the authors from tape record-
ings. Transcriptions of vocalisations emphasise the rhythm. Sequences written ‘how how...’ mean that the ‘barks’ are
uttered at intervals of more than one second, while a hyphenated ‘how-how-...’ denotes shorter intervals (about 0.5
seconds), and ‘howhowhow...’ indicates that the notes follow each other without noticeable breaks. Some vocalisa-
tions have a stress, huwuwúbubu. In this example, ú is short, whereas hooting notes are transcribed as oo; tones lying
between oo and ee are expressed as ew (equivalent to French ‘u’ in ‘tu’, or ‘ü’ in German ‘Hütte’).
Distribution
These sections commence with a brief summary of world range followed by a more detailed treatment. They
should be used in conjunction with the maps. For several regions information is very scanty. The distributions
given relate to the range of the species as a whole. In the cases of polytypic species, the ranges of individual
subspecies are given in ‘Geographical Variation’.
17. 16
Movements
Most owls are resident and sedentary but a few are migratory and others undertake local movements. This section
covers all movements, both local and long distance, including altitudinal movements and vagrancy.
Habitat
Most species are dependent on trees to some extent, although some inhabit grasslands or other open areas. Habitat
preferences are given, including favoured tree species if known. Altitudinal ranges are also noted where known.
Description
These sections contain detailed descriptions of plumage features. For ease of use, the section is subdivided into
Adult, Juvenile and Bare Parts. For most polytypic species the nominate race, or in some cases the most wide-
spread one, forms the subject of the description. Where a species exhibits two or more colour morphs, these are
usually described separately.
Measurements and Weight
Wherever possible, measurements from the largest samples have been used and refer to the race described in full
under ‘Description’; measurements for other races are detailed in ‘Geographical Variation’. Mensural data given
includes total length, wing length, tail length and weight. All measurements are in millimetres unless otherwise
stated (body length is always given in centimetres); weights are in grams.
Measurements were taken in the following ways. (1) Wing length The wing was closed and laid on to a special
ruler (without pressing it down) and pushed against the zero stop at one end. Then the distance from carpal joint
to wing-tip (minimum chord) was measured. Other authors often give measurements of flattened wings. (2) Tail
length The distance from the point where the shaft of a central feather emerges from the skin to its tip was meas-
ured with dividers. (3) Wing-tip The distance that the primaries extend beyond the tips of the secondaries on the
closed wing. (4) Total length The distance from the front edge of the crown to the tip of the tail, when the bird is
laid on its back. Some authors measure from the tip of bill but this is difficult in owls as these birds have the bill
in the middle of the ‘face’. Therefore it seems to be more sensible to measure from the crown.
Geographical Variation
We have attempted to describe briefly all recognised races, concentrating on the differences between them. Fu-
ture taxonomic revisions are likely to subdivide certain polytypic species (or even amalgamate other taxa), and
some potential ‘splits’ and ‘lumps’ have been noted in these sections. The range of each subspecies is briefly
given, with measurements if available. The authors of the type descriptions for every accepted taxon are given in
this section. Subspecies not recognised by us are listed as synonyms.
Habits
Typical behavioural traits are noted in this section, although little is known for many species. We hope that the lack
of information for some species may inspire others to undertake research into some of the lesser-known owls.
Food
Where recorded, prey items are listed for each species, although the diet of many species is still poorly known.
Many of the smaller owls are exclusively insectivorous but larger species take a range of vertebrate prey.
Breeding
The nesting habits of each species, where known, are included in this section. Information presented includes
breeding season, courtship, nest sites (most species build no nests or only rudimentary ones, or re-use the nests
of other birds), eggs and clutch size, incubation, brooding and fledging. As with ‘Habits’, the breeding biology of
many species is virtually unknown.
Status and conservation
Information on the status of each species is given where known, together with any conservation recommenda-
tions. For some better-known species, it has been possible to give details of conservation measures implemented,
but most species are not protected and many are under threat from habitat destruction.
Remarks
Taxonomic problems or differences of opinion regarding taxonomic treatment are indicated in this section.
Aspects of a species’ biology or behaviour requiring further research are also highlighted here.
References
References given in the text and at the end of the species accounts are listed in full in the Bibliography.
18. 17
MAPS
A map is included for each species. Black shading indicates the distribution of breeding areas. If the species is
migratory and winters far outside its breeding range, the wintering areas are indicated by hatching. Lesser move-
ments are described in the text (Distribution) and in the legends accompanying the maps. A cross indicates a
vagrant record or an area of irregular occurrence. A question mark indicates an area of uncertain occurrence. On
the maps accompanying the caption texts facing the plates, the breeding areas of more or less resident owls are
shown in green, with the breeding ranges of migratory species in ochre and wintering areas in blue.
A selection of owls to illustrate relative differences in size between various genera.
tiny very small small small to medium-sized medium-sized
13-16cm 17-20cm 21-25cm 26-34cm 35-45cm
Xenoglaux Glaucidium Aegolius Tyto Tyto
Micrathene Otus Athene Phodilus Lophostrix
Glaucidium Megascops Taenioglaux Otus Jubula
Otus Mimizuku Bubo
Ptilopsis Ninox Pulsatrix
Megascops Uroglaux Strix
Asio Surnia
Strix Ninox
Megascops Asio
Nesasio
very large
64-72cm
Bubo
large
57-63cm
Bubo
Strix
Ninox
fairly large
46-56cm
Tyto
Bubo
Pulsatrix
Strix
Ninox
Asio
Domestic Pigeon
19. 18
Owls: an overview
Owls are a group of chiefly nocturnal birds which share many patterns in behaviour, morphology and anatomy.
All have a rather large, rounded head with eyes directed forward as in humans. Their plumage is soft, often rather
fluffy and mostly cryptically coloured. All have a curved bill with a pointed tip, similar to diurnal birds of prey,
and generally powerful talons with curved and sharp claws, as an adaptation for carnivory. Owls are ecologically
the nocturnal counterparts to diurnal birds of prey, without being related to them. This phenomenon in biology,
in which unrelated groups come to resemble each other through adaptation to similar lifestyles, is called conver-
gence. It is found in a considerable diversity of animal and plant groups. For example the Old World and New
World flycatchers, although superficially similar, are unrelated; the same is true of New and Old World vultures.
Anatomically and behaviourally there are large differences between such groups although they occupy similar
ecological niches.
The closest relatives of owls are, according to recent studies of DNA evidence, not the nightjars (Caprimulgi-
formes). Systematically the owls are actually best placed between the parrots (Psittaciformes) and the diurnal
raptors, excluding the falcons. Owls have caeca but no crop, while the reverse is the case in diurnal birds of prey.
When perched, owls show in general a very upright appearance. Many of them have ear-tufts, consisting of
elongated feathers on the sides of the forehead. These have nothing to do with hearing. They serve as adornments
which play a role in behaviour. The real ears are openings behind the rim of the facial disc and are situated at the
sides of the head.
We recognise two surviving owl families: the barn, grass and bay owls (Tytonidae) and the ‘true owls’ (Strigidae).
Most species belong to the latter family. Both families have distinctive morphological and anatomical features.
Morphology and anatomy
In owls the eyes are set frontally as in humans. They are placed in sclerotic tubes or rings (Fig. 2a). The visual field
of owls is similar to ours (Fig. 1a) but, unlike us, their eyeballs are fixed. They cannot roll their eyes or move them
in any way. Therefore they swivel their heads in order to see behind them. They can turn their heads through an
arc of about 270°, thereby seeing backwards with great ease (Fig. 1b).
The visual sense in owls is well developed. It would be wrong to think that owls see less well in daylight. At dusk or
in the very subdued light at night, owls are able to distinguish more details than the human eye, but even in bright
daylight they can see better than ourselves. Like us, they are blind in total darkness. The sclerotic sockets or tubes
give their eyeballs a more oval shape (Fig. 2a). The retina is very large and densely equipped with rod cells, but
with few or no uvular cells (Fig. 2b.). Therefore, although an owl’s eye is capable of maximising shape outlines at
the lowest light intensities, its ability to see colours is very much reduced or nearly lacking. More-diurnal owls (e.g.
Eurasian Pygmy Owl Glaucidium passerinum) are able to distinguish colours, but their night vision is reduced.
Being active at dusk and night, owls need a highly developed acoustic sense. The ear openings are located in
the auricular region at the side of the head which is often covered by the rim around the facial disc. The shape
of the aperture varies according to species; it is often placed asymmetrically with a valve (operculum) covering
the opening. The opening varies from a small, round aperture to a longitudinal slit with a large operculum. All
members of the Tytonidae have rounded openings with large opercula, while in Strigidae the shape of the outer
ear is more varied (Figs 3a,b).
Figure 1a. Visual field of an owl.
monocular
vision
monocular
vision
binocular
vision
Figure 1b. Short-eared Owl turning
its head 180° (max. 270°).
20. 19
Although an owl’s frequency range is not much different from that of the human ear, its hearing is much more
acute. This enables it to hear even the slightest rustle of an insect among dry leaves. The often asymmetrically-set
ear openings give it an incredible ability to pinpoint the source of sounds. This is particularly true of the strictly
nocturnal species such as the barn owls Tyto or Tengmalm’s Owl Aegolius funereus (Fig. 5). American Barn Owls
(Tyto furcata and related taxa) utter metallic clicking sounds in flight, which might suggest echolocation as used by
bats and Oilbirds for orientation. But the emissions of American Barn Owls are lower in pitch than those of bats
or Oilbirds and not in the frequency range of ultrasonic sounds. On the other hand we know that blind humans
with intact hearing may get hints for orientation from sounds produced by beating a stick against hard soil, stones,
iron, etc. Might the clicking notes of American Barn Owls and allies have a similar function?
Figure 2a. Tubular eye. Figure 2b. Cross-section of an Eagle Owl’s eye.
eye socket
(sclerotic ring)
pecten
optic nerve
retina
scleral bone
(sclerotic ring)
iris
cornea
lens
Figure 3a. Barn Owl showing large
operculum and ear aperture.
Figure 3b. Long-eared Owl showing ear
aperture with complicated structure.
Strictly nocturnal owl species have a very pronounced facial disc, which is used to assist hearing. Its shape can be
changed at will by special muscles and its function may be compared with the focusing apparatus of a searchlight.
Owls may receive sound waves with a dilated or a more contracted facial disc, according to the distance of the
detected sound. The more diurnal owls have in general a less well-developed facial disc.
Owls have powerful talons with sharp, curved claws. The Tytonidae have inner and central toes of about equal
length (Fig. 4a), while the Strigidae have an inner toe that is distinctly shorter than the central one (Fig. 4b).The
claw of the central toe in the Tytonidae is serrated on its underside (see detailed sketch of a claw in Fig. 4a).
The skeleton of an owl is typically avian (Fig. 7). The skulls of species with asymmetrical ears are, however,
different from others (Fig. 5). The Tytonidae and Strigidae may be separated by their breast-bones (Fig. 6). The
former have a rather broad carina, becoming narrower towards the abdomen, and the lower edge of the breast-bone
Figure 4a. Foot of Barn Owl (Tytonidae) and
detail of serrated claw of the middle toe.
Figure 4b. Foot of Eagle Owl (Strigidae).
21. 20
(sternum) has only a slight emargination on each side. In the Strigidae the carina is narrow at its upper part and
becomes broader towards the belly, while the lower edge of the sternum has two deep emarginations on each side.
Most owls fly noiselessly because of the structure of their feathers. The outermost flight feather (tenth primary;
and in some species also the ninth) has a ‘combed’ or serrated edge on its outer web (Fig. 8a). This suppresses
noise when cutting through the air. The surface of the flight feathers is covered with a velvety structure absorbing
sounds produced by moving the wings. The same applies to the loose, soft feathering of the body. More diurnal
owls have a somewhat noisier flight than nocturnal ones.
Figure 5. Skull of Tengmalm’s Owl, showing the
asymmetrical position of the ear-openings.
Figure 6. Different sterni in Tytonidae/Strigidae.
scleral bone
(eye socket)
cranium
upper jaw
(upper mandible)
lower jaw
(lower mandible)
scapula
humerus
ulna
radius
metacarpals
phalanges
furcula
coracoid
ribs
sternal ribs
carina
sternum
pelvis
pygostyle
pubis
femur
tibia
fibula
tarso-metatarsus
(tarsus)
Figure 7. Skeleton of a typical owl (Tawny Owl).
Frontal view
Dorsal view Sternum of Tyto Sternum of Asio
22. 21
The rim around the facial disc is like a ruff of rather stiff feathers (Fig. 8b), while around the auricular region
the feathers have filamentous barbs in order to reflect sounds (Fig. 8c). As an example, Fig. 8d shows a range of
Little Owl feathers.
Figure 8a. 10th primary of Barn
Owl, showing serrated outer web.
Figure 8b. Feather from the
ruff of Barn Owl, with thick
rachis and dense webbing.
Figure 8c. Feather from
auricular area of Barn Owl,
with filamentous barbs and
absence of barbules.
Not to scale.
Figure 8d. Various feathers of
an owl, based on Little Owl.
scapular
secondary
greater
secondary-
covert
crown
ruff
chest
flank
primary
medium
secondary-
covert
nape
lower
primary-
covert
lower
tail-covert
alula
upper
tail-covert
outermost
tail feather
innermost
tail feather
outermost
primary-
covert
medium
primary-
covert
23. 22
Topography
Figure 9 shows sketches of typical owls:
(a) Whole body of an owl of the genus Athene (little owls). The foot consists of toes with claws and the tarsus or
tarso-metatarsus. We use the expression ‘foot’ only when no part of it is specified. Mostly we use the terms ‘tarsi’
or ‘toes’. Owls have four toes, three in front and one hind-toe. Of the front toes the outer one may be turned
backwards.
(b) Head of a Long-eared Owl Asio otus with typical ear-tufts and showing on one eye the nictitating membrane,
an opaque third eyelid, which may act as a protection to the eye in certain situations. This membrane keeps the
eye clean and moist. Owls also have upper and lower eyelids, which may be bare or finely feathered. The eye often
has a brightly coloured iris and a dark or pink bare rim.
(c) Lateral view of an owl’s head (type Athene) with the ‘false eyes’ or ‘occipital face’ on the nape. This pattern
is characteristic of Glaucidium and some Athene species and gives the impression of a face with dark eyes, whitish
eyebrows and a whitish band below. It is a feature of many semi-diurnal species and it may have the purpose of
deterring potential predators, as the owls are vulnerable when perched. The fleshy area surrounding the nostrils
is called the cere and may be distinguished from the smooth horn of the bill by its rough surface.
Figure 9a. Topography of a
typical owl, based on Athene.
eyebrow or supercilium
bill
chin
throat
breast
alula
belly
primary-coverts
flanks
tibia
tarsus
toe
abdomen
tail
primaries
secondaries
secondary-coverts
lesser coverts
scapulars
mantle
claw
undertail-coverts
back
collar
ear-tuft
rim
nictitating membrane
facial disc
bill
throat
eyebrow
eyelid
iris
bristles
chin Figure 9b. Front view of head,
based on Long-eared Owl.
24. 23
crown
occiput
false eyes
nuchal band
back
forehead
cere and nostril
upper mandible
lower mandible
chin
gape
throatFigure 9c. Lateral view of head.
Figure 9d. Wing and tail of an owl (upperside).
outer web
primary-coverts
alula
bend of wing
lesser coverts
secondary-coverts
scapulars
tertials
rump
uppertail-coverts shaft
tail-feathers or rectrices
secondaries
remiges
primaries
P10
P9 P8
P7
P6
P5
P4
P3
P2
P1
S1
S2
S3
S4
R6
R5
R4
R3
R2
R1
S5
S6
S7
S8
S9
S10
(d) Wing and tail of an owl from above. The primaries are numbered descendently i.e. counted from the mid-
dle of the wing towards the tip and the secondaries from that point towards the body. Wing length is measured
on the closed wing, from the carpal bend (wrist) to the tip of the longest primary feather. Tail length is measured
from the base of the central tail feathers to the tip. Tail feathers are counted from the centre outwards. Each
feather has a shaft and an outer and an inner web.
25. 24
Food
Owls are carnivorous. Their diet includes invertebrates such as insects, spiders, crabs, snails, earthworms and
scorpions, and vertebrates from fish, reptiles and amphibians to birds and mammals. Some species specialise on
certain prey. The food of Barn Owls consists mainly of mice, shrews and voles. If these are scarce, breeding suc-
cess is low. Bay Owls Phodilus are less dependent on small mammals. Scops and screech owls, Otus and Megascops,
feed mainly on insects, while the food of the Eurasian Pygmy Owl Glaucidium passerinum consists of small rodents,
shrews and birds. Little Owls have a varied diet which includes earthworms, insects and small mammals. Most
eagle owls Bubo take hedgehogs, hares or young foxes and birds up to the size of ducks and gamebirds. Asian
fish owls Bubo, subgenus Ketupa, specialise on fish, as do the African fishing owls Bubo, subgenus Scotopelia. Wood
owls Strix and Asian and Australian hawk owls Ninox have a very varied diet. Long-eared and Tengmalm’s Owls are
highly dependent in the breeding season on the supply of small mammals, especially voles. The Great Grey Owl
Strix nebulosa, Snowy Owl Bubo scandiacus (subgenus Nyctea) and Northern Hawk Owl Surnia ulula similarly depend
on an abundant supply of lemmings Lemmus or other northern voles for breeding success.
In Fig. 10 a–g some owls are shown carrying prey in their beaks. Prey is killed by crushing the skull and kneading
the body with the powerful talons. Many owls remain on the seized prey with half-spread wings, biting and knead-
ing it at the same time, before flying to a perch to feed. Large prey is partly plucked on a perch. Pieces of it are
torn off and swallowed. Smaller prey such as mice are often swallowed whole. When swallowing the eyes are closed.
A Patagonian Pygmy Owl Glaucidium nanum has been observed gulping down whole an unfledged Austral Thrush
Turdus falcklandii. Smaller owls dismember larger insects, tearing apart with their beaks the hard elytra or sturdy
legs of beetles, while holding the prey in the talons of one foot and feeding on it in a parrot-like manner.
If prey is abundant, owls will store the surplus food in caches, which may be in the nest or in a nearby tree-hole
or fork in a tree branch. Females incubate alone; their mates either bring food to the nest or deliver it nearby
after calling the females out. Towards the end of incubation or when the young have hatched, the female Eurasian
Pygmy Owl often flies to known food deposits for herself.
Hunting
Before catching prey, owls have to fly from their daytime roosts to their hunting areas, which may sometimes be
quite far off. Their flight is light with rowing wingbeats alternating with gliding on more or less extended wings
(Fig. 11a). Some larger owls, e.g. Eurasian Eagle Owl Bubo bubo and Short-eared Owl Asio flammeus, sometimes soar.
When owls leave the perch, the legs dangle for a moment before they are pulled up against the tail (Fig. 12).
Most species catch their prey from a perch (Fig. 18), swooping down with opened wings and talons stretched for-
ward (Figs 11b, 15). Some, notably those using visual rather than aural search methods, employ a rather longer
attack flight, e.g. eagle owls pursuing hares in open country, or pygmy owls dashing from cover to grasp their often
avian prey. These latter and some others will take prey larger than themselves – Northern Hawk Owls may even
take ptarmigans Lagopus. (Fig. 16) – while others take small prey such as bush-crickets plucked from leaves. In
winter some owls detect their prey (mice or voles) acoustically through a cover of snow. Great Grey Owls (Fig. 23)
specialise in hunting in this way. Some others, e.g. Long-eared Owls, also hunt in this manner when a deep layer
of snow is covering the ground. Smaller insectivorous owls, notably Otus and Megascops, may hawk insects in the
Figure 10. Owls and prey. a) Glaucidium with remains of bird; b) Otus with bush cricket; c) Athene with moth; d)
Strix with mouse; e) Strix with frog; f) Athene with viper; g) Ninox with centipede.
a) b) c) d)
e) f) g)
26. 25
Figure 11a. Common Barn Owl flying
(lateral view).
Figure 11b. Common
Barn Owl swooping
with talons stretched
forward.
Figure 12. Eurasian Eagle Owl
after take-off with legs hanging.
air. Barn Owls hawk bats on the wing and, along with Short-eared Owls and Snowy Owls, they often quarter the
ground in search of prey, dropping on small mammals in the grass, sometimes after a brief hover (see also Teng-
malm’s Owl in Fig. 20). Barn Owls, Long-eared Owls and Tawny Owls Strix aluco sometimes fly along hedgerows
at dusk in order to flush out roosting birds. Fish owls and fishing owls are perch-and-pounce species, snatching
prey as it rises near the water surface in the twilight (Figs 14, 15), although some species also wade in the shallows
after prey.
Figure 13. Great Horned Owl
with thrush. Figure 14. Blakiston’s Fish Owl
perched, watching for fish or crayfish.
Figure 15. Pel’s Fishing
Owl fishing in flight.
Figure 16. Northern Hawk
Owl hunting Willow Grouse.
Smaller prey is carried away in the bill (Fig. 13) or eaten at once (Fig. 19). Larger prey is transported in the
talons (Fig. 17). All owls eject indigestible remains of food as pellets. These are dark, oval objects, containing hair,
feathers, chitinous parts of insects and bones. They could be confused with fox droppings but those are more
elongated, never contain bones and have a more earthy quality. Foxes leave their droppings on stones, on mole-
27. 26
hills or tree stumps; owl pellets are normally found below perches. Unlike raptor pellets, owl pellets contain even
the smallest bones. Fresh barn owl pellets are always covered with a slightly glossy film of dried saliva. This film is
lacking in pellets of the Strigidae.
Behaviour
A few owl species are partly active in the daytime; most are active at dusk or dawn; several are virtually inactive
in the dead of night. In general, activity begins around dusk. Some species (e.g. some pygmy owls) hunt during
daytime. Other taxa living in the most northerly or southerly regions of the earth also inevitably hunt by day in
summer when there may be 24 hours of daylight. Examples are Northern Hawk Owl and Snowy Owl in the north
and Magellan Horned Owl in the south. At dusk the owl, having spent most of the day motionless at its daytime
roost, begins to stretch its wings and legs and to preen its plumage (Fig. 24 a–c) or to comb its head by scratch-
ing it with its claws (Fig. 25). Often the whole plumage is ruffled up and shaken or claws and toes are cleaned by
nibbling with the bill. Then the owl silently leaves its roost, sometimes calling or singing, particularly during the
reproductive cycle.
Owls in general roost singly or in pairs. In the latter case allopreening may be observed at the daytime roost
(Fig. 26). This behaviour is one of the inherited measures for maintaining the pair-bond between mates. Although
owls are territorial, some species may form flocks outside the breeding season especially during migration. Thus
groups of Short-eared Owls may be found roosting on the ground in meadows and on cultivated land such as
Figure 17. Eurasian Pygmy
Owl carrying prey in feet.
Figure 18. Little Owl starting
to pounce from fence.
Figure 19. Burrowing
Owl with beetle.
Figure 20. Tengmalm’s
Owl hunting a mouse.
Figure 21. Short-eared
Owl with vole.
Figure 22. Western Screech
Owl swallowing prey whole.
Figure 23. Great Grey Owl, with slightly spread
wings, after a deep snow plunge hunting vole.
28. 27
potato-fields. In daytime during winter Long-eared Owls may congregate in dozens in trees for roosting, even in
urban parks, gardens and tree-lined avenues. Many pellets may be found on the ground below such roosts, provid-
ing an insight into their diet.
Owls bathe frequently. As with most birds they wade into shallow water and splash it around by pecking and
shaking their heads, ruffling their body feathers and flapping their wings. They also bathe in rain (Fig. 27).
Observation will reveal that owls are often expressive in their posture and behaviour. A relaxed owl carries its
plumage rather loosely. Thus while the ear-tufts of Long-eared Owls are erected when the bird is on its guard, they
are almost invisible when it is at its ease (Fig. 28). If frightened, or in order to camouflage itself at its daytime roost,
Figure 24b. Common Barn Owl
juvenile preening tail feathers.
Figure 24a. Common Barn Owl simultaneously
stretching leg and wing.
Figure 25. Tawny Owl under-
taking feather maintenance
of head with toes and claws.
Figure 24c. Great Grey Owl,
wing-stretching over the back
before starting to fly.
Figure 26. Rufous Owl
male preening the
female on nape.
Figure 27. Little Owl
rain-bathing.
Figure 28. Long-eared Owl:
above, invisible ear-tufts;
below, erected ear-tufts.
Figure 29. Common
Scops Owl screening.
29. 28
it becomes very slim, its feathers pressed closely to its body, making it very upright; it closes its eyes to a narrow slit
and erects its ear-tufts straight up. Common Scops Owls Otus scops (Fig. 29) behave in the same way. Owls without
ear-tufts also display similar behaviour (Fig. 30), ‘freezing’ when frightened. Some other genera, e.g. Aegolius and
Glaucidium, compress the feathers of the head so tightly to the head that the feathers around their facial discs
suggest small ear-tufts. Glaucidium owls cock the tail when excited or alarmed and flick it from side to side (Fig.
31). Little Owls bob their bodies up and down when alert. Like many other owls they turn their heads from side
to side in a curious way, probably to focus on an approaching object (Fig. 32). Similar behaviour may be observed
in many species. If a potential enemy approaches its daytime roost, the owl either flies off immediately or assumes
a threat posture before leaving. The body feathers are ruffled, the body bowed forward and the wings spread out,
either hanging down or partly lifted above the body (Figs 33, 34). Just before or after fledging, young owls assume
similar threatening postures (Fig. 34), accompanied by bill-snapping and hissing sounds. If touched, they defend
themselves from a supine position by striking with their talons and biting with the bill. Owls may be very aggres-
sive near the nest or fledged young. Tawny Owls and Ural Owls Strix uralensis are even known to attack humans
fiercely, hitting them with their sharp claws in diving flights. Small owls can also be aggressive: the tiny female
Eurasian Pygmy Owl will attack a human climbing a tree near the nest hole. The male sometimes dive-bombs a
person imitating or playing-back its song.
Figure 30. Northern Hawk
Owl: left, sleeked upright
posture; right, normal
posture on perch.
Figure 32. Little Owl
head-turning.
Figure 31. Eurasian Pygmy Owl
tail-flicking.
In the wild, owls have been recorded reaching ages of 6–20 years, the larger species living longer. In captivity they
may survive longer still.
Most owls are more or less resident. Some avoid the hard northern winters by moving southward, reaching
areas where they are not normally found. In good reproductive years, in autumn northern owls invade the south.
Northern Hawk Owls may then be observed for instance in central or western Europe. Some resident owls near
their northern limits of distribution suffer greatly in severe winters. Many die and local populations may go extinct
from starvation. But after a severe winter, repopulation of the vacant territories quickly takes place.
Figure 33. Itombwe Owl stretching wing upwards.
Figure 34. Common Barn Owl juvenile threat display.
30. 29
breeding
When owls begin to sing and call the reproductive cycle has begun. The males claim their territories and potential
nesting sites. In temperate climates this normally occurs in late winter or early spring; in the tropics at almost any
time, but most often near the end of the dry season. Song is delivered from different perches in the territory, often
but not always from near the future nesting site, sometimes even from outside the territory.
Figure 35a. Eurasian Eagle Owl singing.
Females also sing; normally their song is higher in pitch and less clear. Often male and female may be heard
duetting. After pairing, the female normally stops singing and uses other calls in its vocabulary to contact its mate
and later its young. Unpaired owls, males as well as females, may sing persistently until they have found a mate.
The song of both male and female has the purpose especially of claiming a territory and attracting a mate. After
pairing the singing activity of males decreases considerably. After the female has accepted the future nesting site,
the male Tengmalm’s Owl utters only a few phrases of song when bringing food to her inside the nesting hole.
Later it only utters low notes. Voice is discussed more fully under ‘Vocalisations’ below, and special vocal features
of individual species are treated in the species accounts. Unlike most songbirds, owls do not open their bill visibly
when singing. Instead, they inflate their throat into a small ball, which often shines as a white spot easily seen at
dusk (Fig. 35). However, when giving other calls or cries, the bill is wide open (Fig. 36).
Some owls pair for life or at least for more than one breeding season; others seek a new mate each year. Males
are in general more faithful to their breeding territory; females tend to wander, sometimes occupying their own
feeding territories, which may occasionally be united with those of males. The male will only occupy a territory if
it meets his breeding demands and contains suitable nesting sites. In hole-nesting species he searches and inspects
tree holes before embarking on courtship, scratching a shallow depression in the bottom of a selected hole and
doing a little superficial preparation. He advertises potential nesting sites to the female, guiding her around his
territory. He utters a song or some other vocalisation at the nest site and may deposit prey as a courtship gift. The
female then chooses one of the offered nest sites. After pairing, courtship display occurs near the nesting site.
The birds often copulate on branches or nearby rocks; some Tyto and other species mate on the nest itself, the
female carrying the male’s gift in her bill (Fig. 37).
Figure 35b. American Great Horned Owl
aggressive singing.
Figure 36. Little Owl calling.
Figure 37. Common Barn Owl copulation; male has handed over prey.
31. 30
The nest sites of owls vary even within species. No owl constructs a real nest. Many scratch a shallow depression at
the base of the nesting site; others mince pellets or remains of food with their bill in order to make a pad for the
eggs. Grass owls Tyto trample a platform on the ground. Marsh Owls Asio capensis and Short-eared Owls collect dry
leaves, grass stems, etc., from around the nest to make an incomplete layer for the clutch. Sometimes tall grass or
other vegetation at the nesting site is drawn together to make a shelter above the nest (Fig. 38). Common Barn
Owls Tyto alba use corners in dusky attics of larger buildings (church towers, barns, etc.), holes in walls or rocks or
hollow trees with large holes for nesting. They may accept artificial nestboxes placed behind the outside wall of
the attics of larger buildings; optimal structures possess a quadrangular opening (20 x 15cm) about 15cm above
the bottom of the box (Fig. 39). Many owls nest on cliff ledges, in holes or crevices of rocks or on bare ground
(Fig. 40, 41). Eagle owls and some other larger species nest on ledges and in cavities in cliffs, abandoned nests
of other birds (often Ural Owls) or shallow cavities in tree stumps (Figs 42, 43). The Great Grey Owl never uses
hollow trees, always nesting in rather open sites. Owls living in deserts, such as Hume’s Owl Strix butleri, mostly
nest in rock cavities (Fig. 44). Most small to medium-sized owls nest in cavities. The tiny Elf Owl Micrathene whit-
neyi nests in holes made by woodpeckers in giant cacti or trees (Fig. 45). Glaucidium owls use similar holes. The
Figure 39. Common Barn Owl in nesting box.
Figure 38. Short-eared Owl ground-nesting.
Figure 41. Snowy Owl ground-nesting.Figure 40. Eurasian Eagle Owl rock-nesting.
Figure 42. Great Grey Owl nesting on stump
of broken tree. Figure 43. Ural Owl in an old raptor’s nest.
32. 31
�Little Owl prefers holes in orchard trees, walls, cliffs, riverbanks or sand-pits; sometimes it nests under the eaves
of buildings and in barns. Erecting special nestboxes in orchards can dramatically increase the Little Owl popula-
tion (Fig. 46).
The related Burrowing Owl nests in burrows in the
ground (Fig. 47) which may have been dug by prairie
dogs or rabbits but are quite often excavated by the owls
themselves. The tunnels may be several metres long,
ending in a nest chamber. Tengmalm’s and Northern
Hawk Owls, and many other species, nest in tree-holes.
Tengmalm’s Owl usually uses the abandoned hole of
a large woodpecker such as the Black Woodpecker
Dryocopus martius, but locally very frequently nests in
artificial nestboxes (Fig. 48). The Northern Hawk Owl
breeds in larger, rather open cavities in rotten tree
stumps (Fig. 49 a). Tawny Owls mostly breed in natural
holes: when leaving the nest they dive from the open-
ing (Fig. 49b).
All owls lay pure white eggs; oval in the Tytonidae,
roughly spherical in the Strigidae. They are laid gener-
ally at intervals of a few days (normally two days). Incubation often starts after the first egg is laid. Some (e.g. Glau-
cidium) begin incubating only after the last or penultimate egg is laid. Only the female, fed by her mate, incubates.
Prey is delivered either at the nest or near it, when the male summons the female to emerge. The male may cover
the clutch in the brief absence of the female but real incubation by males has not been proven. Males never have
a brood-patch. When incubation starts from the first egg, the young hatch in laying sequence. When incubation
starts after the clutch is almost complete, the young hatch within one or two days of each other. They are born
with closed eyes and covered with a whitish natal down. This is gradually succeeded by a second coat, the so-called
‘mesoptile’, a fluffy, almost downy plumage. The mesoptile covers the body and head, while flight and tail-feath-
ers resemble those of the adults. Many species of owl have no typical mesoptile but resemble their parents, their
body-feathering being only slightly fluffier and less distinctly marked. Sometimes they differ in coloration. The
hatched chicks are normally first brooded and fed by the female alone; later on in many species they are cared
for by both parents. After fledging, the young move about calling for food. In some species (e.g. Tawny Owl) the
fledglings are not yet able to fly and will climb up trees by fluttering with their wings and using the bill and claws
Figure 44. Hume’s Owl nesting in rock cavity.
Figure 45. Elf Owl in hole of Gila Woodpecker in
Saguaro cactus.
Figure 46. Little Owl beside nesting box.
Figure 47. Burrowing Owl in nest burrow.
33. 32
(Fig. 49 c). They are accompanied for some weeks, sometimes even months, by their parents. In Eurasian Pygmy
Owls the young, after having left the nest hole for more than 8–10 days, are fed and guided by the male alone.
The female keeps apart from the family and moults her plumage. In some species at this time the residue of the
mesoptile is still perceptible. Owls normally breed once per year but, when food is especially abundant, there are
records of two and occasionally three clutches in species such as Common Barn Owl.
Vocalisations
Owl vocalisations are poorly treated in bird books. Some calls are described but the transcriptions are generally
not very helpful as an aid to identification. Ornithologists belong to a diurnal species and tend therefore to look
first for plumage patterns in order to separate one owl from another. However, the vocal patterns of nocturnal or
crepuscular species are in general much more important than coloration or plumage as an aid to identification.
Owls have at their disposal a variably extended vocabulary depending on species. In all owls vocalisations are
inherited and therefore of great taxonomic importance. Owls show little geographical dialect variation. In general
there is also little variation in vocalisation between individuals; nor are vocal parameters different between races of
the same species. Where competition for food or nest sites is low, some species may develop individual variations.
A typical example is Tengmalm’s Owl, in which individual males may be recognised by their territorial songs, but
despite this all show typical, specific patterns. If we compare the songs of that species from the Alps, Scandinavia
and North America, we find some variation but no essential differences between the three populations. In areas
where species of the same size occur sympatrically, the individual variation is much less developed (e.g. American
Megascops or Glaucidium). Some books state that populations of the same species have different voices in different
areas of their distribution. We have studied the evidence and found that either different notes of the vocabulary
have been compared or that the birds belonged to separate species. Such studies have involved the American
pygmy owls (Glaucidium) or South American screech owls (Megascops).
Figure 48. Tengmalm’s Owl
in nesting box.
Figure 49a. Northern Hawk Owl
in hole of dead tree.
Figure 49b. Tawny Owl
leaving nest hole
Figure 49c. Young Tawny
Owl climbing on a tree.
34. 33
In order to build up a picture of the comparative vocalisations of different species, good recordings of their
vocabularies are essential. First, we must know the territorial song. To establish this, studies in the field or of birds
kept in aviaries will be necessary. Every vocalisation in an owl’s vocabulary has a precise meaning. The song marks
the territory and attracts the mate. Songs are uttered by all males and most females. Some taxa have two songs for
different situations. In American screech owls (Megascops) both sexes utter a territorial song, the primary or A-
song. They also have a secondary or B-song, which is used in courtship. The two sonograms (Figs 50a, b) illustrate
the A- and B-songs of the Tropical Screech Owl Megascops choliba. The courtship song often has a more aggressive
character than the territorial song. Courtship behaviour is a form of ritualised aggression, hence the B-song is
often used as an aggressive vocalisation against an intruder into the occupied territory when the latter is uttering
the A-song.
Figure 51a. Common Scops Owl: female and
male duetting during courtship. Figure 51b. Common Scops Owl: aggressive call
of male.
Figure 50b. Tropical Screech Owl: B-song of male.Figure 50a. Tropical Screech Owl: A-song of male.
Old World Otus, like most owls, have only the A-song, which is used in aggressive situations as well as in courtship
when duetting with the female. Common Scops Owls duet, the male’s song being more pronounced and lower
in pitch than the female’s (Fig. 51a). Unpaired males may sing without noticeably stopping from dusk to dawn.
Aggressive, single, piercing cries different from the song are uttered at irregular intervals (Fig. 51b). Unpaired
females give a song similar to the males’, with only faint cadences but more drawn out. This type of song is seldom
heard and may be a claim to a food territory. When a male approaches, this song changes into the higher-pitched,
more lilting song uttered when duetting (Fig. 51c).
Typical vocalisations include territorial or courtship songs: aggressive calls, contact notes, begging calls, cries of
distress and alarm calls. Apart from vocal sounds, bill-snapping or wing-clapping sounds may be made. Studying
the songs is usually sufficient to identify species, but allospecies may have similar songs as normally they never
meet. There may, however, be differences in vocabulary. As an example, the calls advertising potential nesting
holes of two allopatric pygmy owls are shown here (Fig. 52). In both cases the male flies to a potential hole in a
tree (usually made by a woodpecker), slips into it and utters advertising calls. Those of the Ferruginous Pygmy Owl
Glaucidium brasilianum, a resident of tropical and subtropical South America east of the Andes, are very different
from those of the allopatric Austral Pygmy Owl G. nanum. The first gives high-pitched, rather piercing, cricket-like
notes in irregular sequences, while the latter utters much lower, softly purring calls with a wavy character (Figs
52a, b). The differences are easily discernible although the songs are similar, showing only slight differences in
frequency of notes and tonal quality (Figs 52c, d).
Figure 51c. Common Scops Owl: song of an unpaired female.
35. 34
Systematics and taxonomy
Vocalisations are very important in owl taxonomy. However, there are also morphological differences between the
two families and between the different species within them. Several species of owl have been lumped together
as variants or races of the same species. The North American Eastern Screech Owl Megascops asio and its Asian
counterparts in the Otus bakkamoena superspecies (consisting of at least four valid species) have been included by
some authors in the single species Otus asio. Similarly, many South-East Asian Otus have been lumped as races of O.
scops, even O. insularis from Mahé in the Seychelles. We now know that all these forms have different vocalisations,
particularly songs, but we are also aware of strikingly different colour morphs in several owl species which do not
represent separate species or races. These morphs often are wrongly described as phases; strictly-speaking a phase
is something temporary. In owls the colour morphs last a lifetime and reappear after each moult. A red-morph
Tawny Owl will always be red.
Owl systematics have frequently been discussed and recent studies on DNA give clues to probable relation-
ships. However, we must regard DNA evidence as only one parameter, doubtless an important one, in the ‘mosaic’
of Taxonomy. For clear results most or all parameters should correspond well. The division of living owls into two
families, Tytonidae and Strigidae, may be accepted without argument. The first may be separated into two genera,
Tyto with 25 species and Phodilus with two species, as we separate the taxon assimilis endemic to Sri Lanka and SW
Ghats (Kerala) from Phodilus badius as a full species because of vocal and morphological features. On the other
hand we include the Itombwe Owl, hitherto called Phodilus prigoginei, in Tyto as it shows typical barn owl features:
Tyto prigoginei. All Tyto owls have well developed heart-shaped facial discs, rather small, dark eyes and relatively
long legs with central and inner toes equal in length to the central toe. Phodilus has similar toe patterns and a ser-
rated inner edge to the claw of the central toe, but the facial disc is very distinctly shaped, the eyes are relatively
large and the legs are short with feathered tarsi.
The Strigidae comprises about 223 species in 25 genera, making a total of 250 species in the whole order
Strigiformes. We include the genus Ketupa in Bubo, giving it the rank of subgenus. Asian fishing owls are obviously
related to eagle owls and represent fishing Bubo species. On vocal patterns they appear to be more closely related
to ‘true’ Asian Bubo than are Bubo leucostictus or Bubo poensis of Africa. For similar reasons we also include the gen-
era Scotopelia and Nyctea as subgenera in Bubo, as DNA evidence clearly proves this relationship. The genus Ciccaba
we include in Strix. We regard the Cuban Bare-legged Owl as a monotypic genus, Gymnoglaux, as this bird seems
to be more related to Athene than to Megascops. We also maintain the isolated Palau Owl Pyrroglaux podarginus in a
genus of its own.
Figure 52a. Ferruginous Pygmy Owl: high
chirping notes when advertising nest-hole.
Figure 52b. Austral Pygmy Owl: cooing
calls advertising potential nest-hole.
Figure 52c. Ferruginous Pygmy Owl: song of male. Figure 52d. Austral Pygmy Owl: song of male.
36. 35
We treat the American screech owls as members of the genus Megascops, as they differ from Old World scops
owls in having two songs (A- and B-songs). However, on the basis of bioacoustical studies and DNA evidence, the
American Flammulated Owl is neither related to the Old World scops owls nor to the American screech owls.
Therefore, in accordance with the rules of nomenclature, we give it the oldest known name Psiloscops flammeolus.
The Burrowing Owl we treat as a close relative of the Little Owl.
The large genus Glaucidium we split into true Glaucidium, having an ‘occipital face’ consisting of two dark spots
on the nape surrounded by a whitish zone on the hindneck, and Taenioglaux with streaked heads and napes.
Following Ernst Mayr, we have applied the Biological Species Concept (BSC) to owls. So we regard as full
species the members of a reproductive community which have evolved different distinguishing features from
members of another reproductive community. These are often most easily perceptible among their vocalisations.
Owls have not evolved distinct regional dialects and all vocalisations are inherited; therefore bioacoustics is the
most important taxonomic criterion used to separate difficult species groups (e.g. Glaucidium, Megascops and
Otus). These studies have led to the recognition of several new species. Specific status can be substantiated by DNA
evidence and field studies. We know that in owl taxonomy the nucleotide substitutions in DNA-sequencing are
variable at subspecific level from about zero to 1%. Greater differences in nucleotide substitutions suggest species
status. In Passeriformes, the nucleotide substitutions may be much greater and clinal vocal differences may be very
striking.
For owls the taxonomic evidence may be summarised as follows. (1) Clearly distinguishable vocal patterns,
such as distinct songs, suggest different species, especially for sympatric taxa. (2) In allopatric, non-migratory
species (allospecies) many vocal patterns may be similar or even identical but this may not be evidence of closer
relationship and perhaps only indicates common ancestry. Allospecies are normally separated by large distances
and are unlikely to come into contact with each other; thus, isolating mechanisms between them may not be
necessary. This holds true for morphological as well as vocal characteristics. Convergence may explain any simi-
larities. (3) In parapatric species (paraspecies), whose range may sometimes overlap, specific vocal parameters
may be recognised in all studied cases. These may be barely distinguishable to the human ear, but are obviously
different to the owls. Hybridisation may occasionally occur but, in general, natural selection does not favour
hybrids and populations of such birds are unlikely to become established.
Following these principles we have revised the owl taxa, especially those that present difficult problems. In this
revised edition we recognise at least 250 species within the order Strigiformes, many of which have been recently
described or have been separated from existing species through bioacoustical, ecological and molecular research.
Biometric criteria, such as the tail/wing index (length of tail:length of wing) or the hand/wing index (length
of wing-tip projection on closed wing x 100, divided by wing-length), have also been utilised. Birds with long,
pointed wings have a large index; birds with rounded wings have a small index.
In several species plumage may vary and colour morphs exist. Nevertheless some species may be separated
by their plumage. For example, three species of Athene may be distinguished by the different markings on their
heads: Little Owl A. noctua and Spotted Owlet A. brama have relatively well developed occipital faces which are
absent or reduced to a narrow collar in Forest Owlet A. blewitti. The latter has a rather dark, virtually unspotted
crown, while in Little Owl the crown is boldly streaked and in Spotted Owlet it is spotted with rounded dots (Fig.
53). Eye (iris) colour may also be diagnostic, but in some species, e.g. in the genus Megascops several species may
be found whose eye colour varies between brown, orange and yellow. Sometimes this may be caused by ageing.
Bill coloration seems to be less variable. The aspect of the face may often be specifically diagnostic: several heads
of adult and young (mesoptile) owls are shown here (Fig. 54).
Most owls’ feet are distinctive: they vary in size and shape and in the extent of feathering of the tarsus and toes;
bare in some, sparsely bristled in others. Figure 55 demonstrates these differences. Most relate to adaptation for
hunting or to climatic conditions.
We now know much more on the systematics and taxonomy of owls than even a few years ago. Nevertheless,
much remains to be elucidated for several taxa: the last word on owl taxonomy is yet to be spoken!
Figure 53a. Little Owl, white
longitudinal spots above white
nuchal band.
Figure 53b. Spotted Owlet, white double-
spots above white nuchal band.
Figure 53c. Forest Owlet, only a few
small white spots above the sparse
white nuchal band.
37. 36
Tyto alba
Megascops kennikottii
Bubo bubo
Strix aluco
Pulsatrix perspicillata
Athene noctua
Otus scops
Bubo scandiacus
Bubo peli
Strix nebulosa
Surnia ulula
Aegolius funereus
Figure 54. Head plumages of adult and natal owls.
38. 37
Figure 54 (cont.). Head plumages of adult and natal owls.
Tyto soumagnei Phodilus badius Otus sunia
Megascops asio Megascops nudipes Gymnoglaux lawrencii
Bubo virginianus Bubo zeylonensis
Ptilopsis granti Mimizuku gurneyi
Glaucidium passerinum
Asio otus
Ninox boobook
Asio flammeus
Figure 55. Differences in the feet of a selection of owls (not to scale). Continued on p. 38.
Psiloscops flammeolus
Bubo scandiacus
39. 38
Figure 55 (cont.). Differences in the feet of a selection of owls (not to scale).
Strix varia
Strix nebulosa
Glaucidium passerinum Xenoglaux loweryi
Micrathene whitneyi Athene cunicularia Athene noctua
Aegolius acadicus Ninox superciliaris Uroglaux dimorpha
Sceloglaux albifacies
Surnia ulula
Nesasio solomonensis Asio clamator
Bubo ussheri Pulsatrix perspicillata
Lophostrix cristata
Taenioglaux cuculoides
40. 39
How to study owls
Although some owls are partly diurnal, most are rather difficult to find in daytime. If we want to study the life of
owls, we must be prepared to be active at dusk or at night when our ears will be more important than our eyes.
Owls are easiest to find on clear, moonlit nights without wind. The temperature is not so important. Windy or
stormy nights are useless for owl studies. Wind affects the birds’ soft, often fluffy plumage and the noise of the
wind passing through the trees makes hearing more difficult, even for owls. Some owls are sensitive to falling
atmospheric pressure. Unpaired Tengmalm’s Owls are virtually silent if the atmospheric pressure falls during a
calm, clear night, giving way to rain next morning. Conversely, owls may call during nights with a slight drizzle if
an increase in atmospheric pressure heralds a clear morning.
Owls are most vocally active at the beginning of the reproductive period, which in temperate zones is in spring-
time and in tropical areas falls towards the end of the dry season. Owl studies are therefore best timed to coincide
with these periods. Males sing on different perches in their territory, sometimes close to the future nesting site,
sometimes quite far away from it. The singing male must be followed from perch to perch in order to fix the
boundaries of the territory. The presence of a female may often be deduced from the behaviour of the male. If
one is nearby he will advertise nest sites to the potential mate. Numerous droppings, remains of prey and pellets
under certain perches indicate the vicinity of an occupied nesting site. The male often roosts nearby in a sheltered
place. During the daytime nothing much happens but at dusk activity increases: some vocalisations may be heard,
and often the female leaves the nest for a short while, or the male brings food to the nest. However, little will be
heard from a distance; often vocalisations are so quiet that they may be perceived only at very close range.
Although many owls are confiding, they should not be disturbed. Observers need to move slowly or sit still
(not too close), watching with good binoculars or recording calls on tape. All observations should be routinely
recorded for later evaluation, noting date, time and weather conditions. The territories and nest sites should be
mapped.
Several species of owl will breed in nestboxes, which makes it easier to inspect the nest and ring the young and
their mother. Many studies of birds nesting in artificial nestboxes have been made of some northern species such
as Tengmalm’s, Pygmy, Ural and Tawny Owls, particularly in Scandinavia.
In the tropics, particularly in rainforests or cloudforests, owl studies are much more difficult than in temper-
ate regions, although there are more species living in the same habitat. Our knowledge of the voices of tropical
owls is incomplete. Walking around a tropical forest at night is not easy and finding nests is difficult. There are
so many confusing night voices coming from different animals such as nightjars, frogs, crickets, cicadas and some
mammals. Recordings should be thoroughly studied before making an expedition. In the forest the playback of
recordings (or whistled imitations) may attract some owls. As already mentioned, some species become quite
silent after courtship, but in general males react to the playback of their song, sometimes singing aggressively but
often by flying unobtrusively to perch near the source of the ‘intrusion’.
Dietary studies are very important. Collecting pellets below daytime-roosts or at nests will provide vital clues.
Watching the nest may also reveal the prey species.
An international project, the Global Owl Project (GLOW) is dealing with most of these aspects of owl biology
with a view to illuminating the still often dark world of these enigmatic birds.
Many owls will respond strongly to playback of their vocalisations, both vocally and by approaching
the sound source. Playback is a valuable survey technique but irresponsible use of sound-lures
may cause serious disturbance to the birds. Therefore we advise against using playback except as
part of a serious study.
Conservation
The greatest threat to owls is the increasing destruction of their natural habitats. The devastation of some tropical
rainforests by logging is well documented but illegal deforestation occurs in the developed world as well. Threats
are also connected with the loss of habitat on small, isolated islands.The use of pesticides also endangers owls as
well as other wildlife. In some regions owls are still persecuted as birds of ill-omen. Trade in many species is pro-
hibited under the Washington Convention (CITES) but nevertheless a black market persists.
Some practical measures can be undertaken locally to aid owl conservation. The loss of nesting sites by tree
felling may be partly compensated for by constructing nestboxes and mounting them in trees. Nestboxes are
available for many owl species, but in the case of Tawny Owls artificial nest sites are really not necessary. Tawny
41. 40
Owls will nest practically anywhere, even on the ground. Tengmalm’s Owls on the other hand really do need help.
Boxes should be hung in trees near forest clearings about 4–5m above ground (sometimes even higher). For Little
Owls, nesting tubes are available which resemble hollow branches; the tube has to be mounted on a vertical tree
branch in a suitable orchard. Common Barn Owls may be helped by mounting wooden boxes with an aperture of
15 x 20cm inside a barn or other large building such as a church tower. As owls do not build nests, the bottom of
all nestboxes should be covered with a layer of vegetable mould or peat dust. Putting pellets in the nest box may
sometimes make a Common Barn Owl feel at home.
Smaller tree-hole nesting owls suffer from mammalian predators such as martens Martes or raccoons Procyon.
Nests in abandoned woodpecker holes may be protected against predation by fixing cuffs of sheet iron around the
tree trunk, about 1m below and 1m above the aperture, so that no mammal can maintain its grip. This technique
has worked well for Tengmalm’s Owls in south-west Germany. Nestboxes on tree trunks may be protected in the
same way but martens have learned to jump from above onto the roof of the box. To avoid this the box should
be protected by a downhanging sheet, fixed to the trunk above the box, so that the marauder will slip off and
fall down. In Common and American Barn Owls nestboxes mounted at adequate sites in barns, church towers or
other large buildings have proved to be a great help to maintain or even to enlarge their populations.
Some locally extinct species have been successfully reintroduced, given the right ecological circumstances. The
Eurasian Eagle Owl has been reintroduced successfully in Central Europe. Eurasian Pygmy Owls have been
re-�established in the Black Forest, where the species became extinct after the Second World War owing to defor-
estation and an increasing Tawny Owl population. After re-afforestation, which helped reduce numbers of Tawny
Owls, captive-bred Pygmy Owls were released in the late 1960s. A regular census has shown an increasing popula-
tion (over 250 pairs) throughout the Black Forest. The population includes immigrants from other forested areas,
where Pygmy Owls have also increased due to the effects of ‘forest disease’, which favour these owls (more insects,
more small birds, more woodpecker holes in dead trees). The genetic diversity of Pygmy Owls in the Black Forest
is now satisfactory. However, a new threat to this population, and indeed to the health of the Black Forest as a
whole, has arisen from the harmful effects of severe storms.
Hard winters with long-lasting snow cover are harmful to many owls, especially to Common Barn and Long-
eared Owls. Because they often congregate in daytime roosts in winter, Long-eared Owls can be helped by provid-
ing laboratory mice and day-old chicks. An open plastic vat is placed within sight of the roost, the bottom covered
with straw or dry leaves. Before dusk several live laboratory (white) mice, together with some dead day-old chicks,
are put in the vat. The mice crawling about in the straw produce a rustling noise which attracts owls as they dis-
perse at dusk. When the owls’ confidence has been won after catching a few mice, they will also take the dead
chicks. After this, live mice are no longer necessary. In this way several populations of Long-eared Owls have been
helped to survive severe winters. Similar methods may be used to feed Common Barn Owls at places where they
have their daytime roosts.
Collar et al. (1994) listed 26 species of owls as globally threatened (Table 1) and a further 15 species as near-
threatened (Table 2). In the light of taxonomic revisions since this publication, the description of several new
species, and continuing habitat destruction in some parts of the world, it is likely that the number of threatened
species is now even higher. We have enlarged the lists in Collar et al. (1994) according to our current knowledge.
Table 1. List of globally threatened species (after Collar et al. 1994, modified by us).
Key: CR = critical, EN = endangered, VU = vulnerable.
Curaçao Barn Owl Tyto bargei (VU)
Madagascar Red Owl Tyto soumagnei (EN)
Golden Masked Owl Tyto aurantia (VU)
Taliabu Masked Owl Tyto nigrobrunnea (VU)
Minahassa Masked Owl Tyto inexspectata (EN)
Lesser Masked Owl Tyto sororcula (EN)
Manus Masked Owl Tyto manusi (VU)
Itombwe Owl Tyto prigoginei (VU)
White-fronted Scops Owl Otus sagittatus ((VU)
Serendib Scops Owl Otus thilohoffmanni (EN)
Sokoke Scops Owl Otus ireneae (VU)
Sresemann’s Mountain Scops Owl Otus stresemanni (VU)
Javan Scops Owl Otus angelinae (VU)
Mindanao Scops Owl Otus mirus (VU)
Luzon Scops Owl Otus longicornis (VU)
42. 41
Mindoro Scops Owl Otus mindorensis (VU)
Grand Comoro Scops Owl Otus pauliani (CR)
Anjouan Scops Owl Otus capnodes (CR)
Seychelles Scops Owl Otus insularis (CR)
Palawan Scops Owl Otus fuliginosus (VU)
Giant Scops Owl Mimizuku gurneyi (EN)
Usambara Eagle Owl Bubo vosseleri (VU)
Shelley‘s Eagle Owl Bubo shelleyi (EN)
Philippine Eagle Owl Bubo philippensis (EN)
Blakiston’s Fish Owl Bubo blakistoni (EN)
Rufous Fishing Owl Bubo ussheri (EN)
Sichuan Wood Owl Strix davidi (VU)
Albertine Owlet Taenioglaux albertina (VU)
Forest Owlet Athene blewitti (CR)
Powerful Owl Ninox strenua (VU)
Sumba Boobook Ninox rudolfi (VU)
Mindoro Hawk Owl Ninox mindorensis (EN)
Cinnabar Hawk Owl Ninox ios (VU)
Christmas Island Hawk Owl Ninox natalis (EN)
Fearful Owl Nesasio solomonensis (VU)
Table 2. List of near-threatened species (Collar et al.1994, modified by us).
Lesser Sooty Owl Tyto multipunctata
Oriental Bay Owl Phodilus badius (locally)
Sri Lanka Bay Owl Phodilus assimilis
Flores Scops Owl Otus alfredi
Mohéli Scops Owl Otus moheliensis
São Tomé Scops Owl Otus hartlaubi
Andaman Scops Owl Otus balli
Pemba Scops Owl Otus pembaensis
Wallace’s Scops Owl Otus silvicola
Bearded Screech Owl Megascops barbarus
Colombian Screech Owl Megascops colombianus
Forest Eagle Owl Bubo nipalensis
Tawny Fish Owl Bubo flavipes
Hume’s Owl Strix butleri
Spotted Owl Strix occidentalis
Pernambuco Pygmy Owl Glaucidium minutissimum
Chestnut-backed Owlet Taenioglaux castanea
Long-whiskered Owlet Xenoglaux loweryi
Unspotted Saw-whet Owl Aegolius ridgwayi
Buff-fronted Owl Aegolius harrisii
Andaman Hawk Owl Ninox affinis
Togian Hawk Owl Ninox burhani
Table 3. List of other significantly declining species.
Common Barn Owl Tyto alba (locally)
American Barn Owl Tyto furcata pratincola
Buffy Fish Owl Bubo ketupu
Pel’s Fishing Owl Bubo peli
Little Sumba Hawk Owl Ninox sumbaensis
43. 42
Molecular Phylogeny and Systematics
of Owls (Strigiformes)
Michael Wink, Petra Heidrich, Hedi Sauer-Gürth,
Abdel-Aziz Elsayed and Javier Gonzalez
Institute of Pharmacy and Molecular Biotechnology, University of Heidelberg,
INF 364, D-69120 Heidelberg, Germany
1. Introduction
‘The time will come I believe, though I shall not live to see it,
when we shall have fairly true genealogical trees of each kingdom of nature...’
Charles Darwin wrote this comment to his friend T. H. Huxley in 1857. Now, more than 150 years later, we have
indeed reached a stage when fairly true ‘genealogical’ (we prefer the term ‘phylogenetic’ today) trees can be
established for nearly every group of organisms.
The study of phylogeny and systematics of birds and other organisms is traditionally based on morphological and
anatomical characters. Sometimes ecological, behavioural, acoustical or geographical data are included in the analy-
ses. Since the main criterion is similarity, convergence due to adaptive traits can sometimes obscure the picture.
A real breakthrough for phylogenetic studies came with the advent of molecular and biochemical methods,
such as protein electrophoresis, DNA-DNA-hybridisation, DNA restriction analyses (RFLP), or the amplification of
marker genes by polymerase chain reaction (PCR) followed by DNA sequencing (overviews in Avise 1994, Beebe &
Rowe 2004, Frankham et al. 2002, Hall 2001, Hillis et al. 1996, Hillis & Moritz 1990, Hoelzel 1992; Karp et al. 1998,
Mindell 1997, Sibley & Ahlquist, 1990; Storch et al. 2007). In particular, the analysis of nucleotide sequences by pow-
erful computer programs, such as PAUP (Swofford 2002), PHYLIP (Felsenstein 1993) and MEGA (Tamura et al.
2007), has facilitated the reconstruction of phylogenies in all kingdoms of life. The molecular approach does not
make the traditional analysis obsolete; on the contrary, it is rather complementary and the right evolutionary ques-
tions can only be asked if we have a solid framework based on morphology, geography, behaviour and �acoustics.
The analysis of mitochondrial DNA (mtDNA) is central today to most molecular studies on birds (Mindell 1997),
since mtDNA evolves much faster than nuclear DNA (ncDNA). Among mitochondrial genes, many studies use the
cytochrome b gene, which has the advantage that deletions, insertions or inversions are usually absent, so that the
sequence alignment does not provide a problem (as compared with ribosomal genes, which are also often used as
markers). Cytochrome b (but also the other protein coding genes, such as ND2, COI) is usually a good marker at
the species and genus level, but it loses resolution on divergence events which are more than 20 million years in the
past. This is mainly due to multiple nucleotide substitutions at the same position, which can lead to homoplasy. For
deeper nodes’ sequences of more slowly evolving nuclear genes are very helpful. RAG1 (recombination activating
protein) is a single-copy nuclear gene that has been employed in several studies of vertebrate phylogeny.
Trees, which are based on sequence data, are not necessarily unequivocal and correct. Problems can arise if
the data set is incomplete and does not contain all related taxa for a comparison (undersampling). The alignment
can be critical for data sets containing gaps, insertion or deletions (as in rRNA genes). Nuclear copies of mito-
chondrial genes (so-called paralogous genes) can bias a phylogeny (Quinn 1997). Also algorithms (i.e. character
state, distance or maximum likelihood methods) and the evolutionary window to be analysed (i.e. problems of
homoplasy) are of importance in obtaining the correct tree. For mitochondrial genes it should be remembered
that we can only trace maternal lineages (gene trees) and that trees can be distorted by inbreeding and introgres-
sion. Therefore, analyses based on nuclear genes are essential. Some of these limitations have to be kept in mind
when interpreting the phylogenetic trees presented here.
Nucleotide sequences of the mitochondrial cytochrome b gene have already been employed to study the sys-
tematics and evolution of diurnal raptors and owls (Heidrich & Wink 1994, 1998; Wink 1995, 1998, 2000; Wink et
al. 1996, 1998a, b; Griffiths 1997, Seibold & Helbig 1995a, b, 1996; Heidrich et al. 1995a, b; Mindell 1997; Matsuda
et al. 1998, Wink & Heidrich 1999, 2000; Haring et al. 1999, 2001; Wink & Sauer-Gürth 2000, 2004; Groombridge
et al. 2002, Olsen et al. 2002; Riesing et al. 2003, Hendrickson et al. 2003, Godoy et al. 2004, Griffiths et al. 2004,
Kruckenhauser et al. 2004, Pearlstine 2004, Roques et al. 2004, Roulin & Wink 2004, Nittinger et al. 2005, Helbig
et al. 2005, Gamauf et al. 2005 and Proudfoot et al. 2006, 2007)
We have chosen the mitochondrial cytochrome b gene to study the finer details of speciation and phylogeny of owls
(Wink & Heidrich 1999, 2000; Wink et al. 2004). We have enlarged our cytochrome b database and have �additionally
sequenced nuclear markers (especially RAG-1; LDHb intron) for all groups that were critical. Basically, the ncDNA data
support the results obtained from mtDNA (Wink & Heidrich 1999; Wink et al. 2004). Our present dataset has a good