Ferruginous Hawk by Tony Hisgett (CC BY 2.0)

The gape of a bird's beak might not be the first thing that comes to mind when thinking about our feathered friends, but it’s an incredibly important feature that plays a vital role in their survival. Let's delve into what the gape is, why it matters, and some fascinating examples from the bird world.

The gape is the opening of a bird’s mouth, including the width and the angle when the beak is open. It's not just about how wide a bird can open its beak, but also how it uses this ability. The gape is particularly crucial for feeding, both in terms of what a bird can eat and how it feeds its young. The size and shape of the gape can give us insights into a bird’s diet and its feeding behavior.

For many songbirds, especially those that feed their young in the nest, the gape is a bright, colorful target. Nestlings often have brightly colored gapes, which serve as a visual cue for parents to know where to place food. This ensures the food goes directly into the chick’s mouth and not somewhere else. The vibrant colors can range from yellow to red, and this is especially prominent in species where the nest is dark and hard to see.

American Robin chicks by Mark Turnauckas (CC BY 2.0)

The gape also plays a significant role in the feeding strategies of various bird species. For instance, flycatchers, with their wide gapes, are adept at catching insects on the wing. Their beaks may appear short and stubby, but when they open wide, they can catch a considerable number of flying insects. This adaptation is crucial for their survival, as their diet consists mainly of airborne insects.

Another interesting example is the Common Nighthawk, which has a very wide gape, allowing it to scoop up insects while flying with its mouth open. This behavior, known as "aerial feeding," is made possible by the bird's ability to open its beak exceptionally wide, creating a larger target area for catching prey.

Pelicans have one of the most impressive gapes in the bird world. Their beak can open wide enough to catch fish and even hold large quantities of water, which they then drain out before swallowing their catch. The gape of a pelican’s beak is not only wide but also flexible, allowing it to expand to accommodate large prey.

American White Pelican by Don DeBold (CC BY 2.0)

Gape size can also influence a bird's song. In many songbirds, the muscles controlling the gape are highly developed and allow for a wide range of vocalizations. This ability to produce varied and complex sounds is crucial for communication, especially during mating season when males are trying to attract females with their songs.

Hummingbirds, with their narrow, elongated beaks, might not seem like they have much of a gape, but they do. Their beaks can open wider than you might expect, allowing them to catch small insects, which are an important protein source in their diet. This capability shows that even birds with specialized beaks for feeding on nectar can have a significant gape when needed.

The gape of a bird’s beak is a fascinating and important aspect of avian biology. It influences feeding habits, parental care, communication, and survival strategies. Whether it’s the bright, colorful gapes of nestlings, the wide-mouthed aerial feeders, or the specialized adaptations of pelicans and hummingbirds, the gape is a key feature that helps birds thrive in their environments.

Vagrant Birdorable American Flamingo

What Vagrancy Means In Bird Terms

In the birding world, the term "vagrant" refers to a bird that has strayed far outside its usual range or migratory path. These wayward travelers often end up in unexpected places due to various factors such as weather events, navigational errors, or a mysterious sense of wanderlust. Observing a vagrant bird can be a thrilling experience for birdwatchers, as it provides a rare opportunity to see species that are typically not found in their region.

What Causes Vagrancy?

Vagrancy in birds occurs for several reasons. One common cause is weather. Strong winds, storms, or other extreme weather conditions can push birds off course during migration or at other times, leading them to unfamiliar territories. For instance, hurricanes have been known to carry seabirds far inland, where they are not usually seen. Similarly, strong tailwinds might allow birds to overshoot their intended destinations.

Another factor contributing to vagrancy is navigational error. Birds navigate using a combination of the Earth's magnetic field, the position of the sun and stars, and visual landmarks. Sometimes, particularly in young or inexperienced birds, these navigational tools can fail, causing the birds to veer off course. This can result in sightings of species thousands of miles away from their typical range.

Changes in habitat and climate also play a role in bird vagrancy. Habitat destruction, whether through deforestation, urbanization, or agricultural development, can force birds to seek new areas. Climate change is altering migration patterns and the availability of resources, prompting some birds to explore beyond their traditional boundaries in search of food or suitable breeding grounds.

Steller's Sea-Eagle in its natural range by Sascha Wenninger [CC BY-SA 2.0]

Examples of Vagrant Birds

In the wake of major Hurricane Idalia, which hit the Big Bend area of Florida as a cat 3 storm on August 31, 2023 and continued northeast along the eastern coast of the United States, American Flamingos started turning up in unlikely places. The striking pink birds were recorded in Florida, North Carolina, South Carolina, Kentucky, Indiana, Wisconsin, Missouri, and Kansas!

Another fascinating case is a lost individual Steller's Sea-Eagle that has been visiting the northeastern United States on and off since 2021. The usual range for this majestic eagle is across far eastern Siberia and Asia!

Why Vagrant Birds Matter

Vagrant birds can provide valuable scientific insights. Studying these out-of-range birds helps ornithologists understand more about migration patterns, navigation, and the effects of environmental changes on bird populations. For instance, tracking the movements of vagrant birds can reveal how species respond to habitat loss or climate change, offering clues about their adaptability and resilience.

For birdwatchers, the appearance of a vagrant bird is a cause for celebration. The excitement of spotting a bird that is not normally found in their area adds an element of unpredictability and adventure to birding. Many birdwatchers keep detailed lists of the species they have seen, and a vagrant bird can be a prized addition to these lists.

The American Birding Association's Rare Bird Alert page highlights rarities spotted within the ABA area, showcasing a number of vagrants that can be found at any given time.

Vagrant birds are those that have strayed far from their usual range, often due to weather events, navigational errors, or changes in their environment. These birds provide thrilling opportunities for birdwatchers and valuable data for scientists. The next time you're out birdwatching, keep an eye out—you never know when a vagrant might make a surprise appearance!

Birdorable Rhinoceros hornbill

Rhinoceros hornbill

In the fascinating world of birds, some species have developed unique adaptations that set them apart from others. One such distinctive feature is the casque. The casque is an enlargement of bones found on the upper beaks and/or heads of certain bird species, typically serving various functions, from display and communication to protection and foraging. Let’s explore the role and significance of the casque in these remarkable birds.

Casques in Hornbills

The casque is most prominently seen in birds like most hornbills, all cassowaries, some species of curassows, the Horned Guan, and others. These structures can vary greatly in size, shape, and function depending on the species. For many birds, the casque is an integral part of their identity and survival strategy. Casques are typically made of bone, an extension of the upper beak or skull with a layer of keratin covering the protrusion. They are mostly hollow, given structure by bony filaments inside.

Hornbills are perhaps the most well-known group of birds with casques. These relatively large birds are found in Africa and Asia, and are easily recognized by their oversized bills topped with casques. These casques play a role in both individual identification and sexual selection; the size, shape, and coloration of casques in some species varies between males and females, and between young birds and adults. Larger and more colorful casques can be a sign of health and vitality, attracting potential mates. 

The casque in hornbills is also used in combat. During territorial disputes, hornbills may engage in head-butting contests, where the casque provides protection and acts as a battering ram. This behavior helps establish dominance without causing serious injury, thanks to the cushioning effect of the casque.

Birdorable Rufous Hornbill

Rufous Hornbill

Casques in Cassowaries

In contrast, the casque of the cassowary serves a different primary function. Cassowaries are large, flightless birds native to the tropical forests of New Guinea, nearby islands, and northern Australia. The casque of the Southern Cassowary, for example, is a tall, helmet-like structure made of keratin, the same material as human nails. The prevailing theory for purpose in cassowaries suggests that the casque helps the birds thermoregulate, allowing the bird dissipate heat in its warm, tropical habitat. Other theories that suggest cassowaries use their casques in protect their heads in dense forest habitat or as shovels while foraging are no longer considered credible.

Photo of a Southern Cassowary

Southern Cassowary

Casques in Curassows and other Animals

Curassows, a group of large, terrestrial birds found in Central and South America, also sport casques, although these are generally less pronounced than those of hornbills and cassowaries. In the curassows that have them, the casque is often more ornamental, serving as a display structure to attract mates. The size and shape of the casque can vary between species and even between individuals, often reflecting the bird’s health and genetic fitness.

Birds aren't the only animals with casques! Several species of chameleon and lizard sport casques. Just like in birds, casques are used for various reasons among reptiles; some are used to store fat, collect moisture, strengthen biting power, or as part of mating displays. 

Birdorable Birds with Casques

Casque Drawbacks

Casques, especially those used in combat, are subjected to breakage or other injuries. Some birds have been hunted for their casques, used as ivory for carvings in some cultures dating back more than 2000 years. The critically endangered Helmeted Hornbill is particularly sought after for their very dense casques.

Casques are Fascinating!

The casque is a fascinating and diverse structure found in several bird (and other) species, each adapted to serve specific functions essential for survival and reproduction. Whether it’s amplifying calls in hornbills, navigating dense forests in cassowaries, or attracting mates in curassows, the casque is a remarkable example of nature’s ingenuity in adapting to different ecological niches. The next time you encounter a bird with a casque -- at a zoo, in a nature documentary, or in the wild -- take a moment to appreciate the unique role this structure plays in its life.

Cute Birdorable Gifts

Dickcissels by Andy Reago & Chrissy McClarren (CC BY 2.0 DEED)

The cloaca is an essential anatomical feature in birds (the organ also exists in reptiles, amphibians, and some fish). In birds, the cloaca is a single opening located at the base of the tail that serves multiple functions. It is the exit point for the digestive, urinary, and reproductive tracts. This means that the cloaca is used for the expulsion of fecal matter, the release of urine, and the transfer of sperm or the laying of eggs.

In summary, the cloaca is a multi-purpose organ that is vital for the biological functions of digestion, excretion, and reproduction in birds.

The multi-use design of the cloaca might seem strange, but it’s a remarkable example of evolutionary efficiency. By having just one opening, birds maintain a lighter body weight, which is crucial for flight. The cloaca’s interior is divided into three chambers to handle the different functionalities. Each chamber has a technical name: the coprodeum is like a rectum and is for receiving feces from the intestines; the urodeum is for both urine and genital products; and the proctodeum, which is involved in storing waste from the other chambers before it is expelled.

House Sparrows mating by Richard Smith (CC BY 2.0 Deed)

In birds, the cloaca plays a crucial role during mating. Most birds do not have external reproductive organs. Instead, in breeding season, the cloacal regions of both male and female birds swell, facilitating the transfer of sperm.

Mating occurs when a male and female bird press their cloacas together in a quick touch that typically lasts less than a second. This behavior is known as the cloacal kiss. The swift action allows the sperm to move from the male to the female to fertilize eggs. The efficiency of this process is vital, as birds often need to mate quickly to avoid predators and to not draw attention to themselves in vulnerable situations.

Despite the quick nature of their mating, birds often engage in complex and lengthy courtship rituals leading up to the cloacal kiss. These rituals can involve dances, songs, gift-giving (like offering food), and other behaviors that strengthen pair bonds and signal the fitness of the potential mate. For birdwatchers, observing these behaviors can be one of the most delightful aspects of monitoring avian life.

Black-headed Gulls mating by Alan Shearman (CC BY 2.0 Deed)

In terms of breeding success, the timing of the cloacal kiss is critical. Many bird species have very specific mating seasons, driven by environmental cues like temperature and day length, which ensure that the subsequent laying of eggs and rearing of chicks occur during times when survival rates will be highest.

Understanding terms like cloaca and cloacal kiss not only deepens our knowledge of bird anatomy and reproductive strategies but also enhances our appreciation for the intricacies of bird life.

Anting 🐜 is a behavior exhibited by some birds in which they allow ants 🐜 to crawl on their feathers and skin, or they actively apply ants, other insects, or substances ants secrete, to their feathers. They do this as part of their preening, or self-care, routine.

Anting is a curious behavior exhibited by a surprisingly wide range of birds – over 200 species across the globe are known to do it.

Anting is one of the most peculiar and fascinating behaviors observed in birds. Those that engage in anting display a curious interaction with ants and other insects. 🐜 This behavior has intrigued ornithologists and bird enthusiasts alike, offering a glimpse into the complex natural behaviors birds have developed to cope with their environments. 🐜

American Robin Anting by ptgbirdlover (CC BY 2.0 Deed)

🐜 Anting typically occurs in two forms: active and passive. In active anting, a bird will pick up ants in its beak and then rub them onto its feathers. In passive anting, a bird will sit directly on an insect nest or move its body around on the ground where the bugs are present, allowing the insects to crawl through its feathers. 🐜 The majority of anting observations involve formic acid-bearing ants, which are believed to play a crucial role in this behavior.

The reasons why birds engage in anting are still not entirely understood by ornithologists, but several theories have been proposed. 🐜 One of the most accepted explanations is that anting helps birds to get rid of parasites and other skin irritants. Ants produce formic acid, a chemical that could potentially help control feather mites and lice. 🐜 By rubbing ants over their bodies, birds might be using the formic acid as a kind of natural pesticide.

Another theory suggests that anting could be a way for birds to soothe irritated skin, particularly during molting when new feathers are growing and old ones are being shed. 🐜 The formic acid might provide a form of relief from the discomfort associated with this process.

Anting may help to regulate a bird's preen oil production. 🐜 Preen oil, secreted from a gland near the base of the tail, keeps feathers waterproof and flexible.  🐜 The formic acid from the ants could stimulate the preen gland or even supplement the oil itself.

Crows anting by Betsy Howell for U.F Forest Service- Pacific Northwest Region (Public Domain)

There’s also a thought that anting may play a role in the maintenance of a bird's plumage. 🐜 By allowing ants to crawl through their feathers, the ants might be helping to clean the birds, removing debris and possibly even adding a layer of protective substances via the ants' secretions. 🐜

Behaviorally, anting is quite a spectacle. 🐜 Some bird species appear to enter a trance-like state while anting, remaining still and allowing ants to work their way through their feathers for several minutes. The bird may be laying prone on the ground with feathers spread as if it is sunning, as shown in the above photos in this post. The below image of a Black Woodpecker shows the bird standing normally with ants crawling over the feathers. 🐜 Whatever the method, such behavior can be quite entertaining to watch, as birds seem to be completely absorbed in the process.

Black Woodpecker anting in Hungary by Fracesco Veronesi (Public Domain)

Interestingly, not all birds use ants for anting; some have been observed using other materials like cigarette butts, presumably for the chemicals they contain, or even snails and millipedes. 🐜🐜 This substitution suggests that the primary motivation behind anting might be related more broadly to chemical acquisition from various sources, not just ants. 🐜

Some Bird Species Known to Engage in Anting Behavior

Anting behavior varies widely among bird species and is most commonly seen in passerines, or perching birds. Among the well-documented anters 🐜 are species like the Blue Jay, European Starling, and American Crow. 🐜🐜 However, reports indicate that many other species across different families also engage in this behavior, highlighting its widespread nature but variable practice among avians.

Despite its oddity, anting is a significant aspect of avian behavior, pointing to the intricate ways birds interact with their environment to meet their physiological needs. 🐜 It serves as a reminder of the adaptive and sometimes unexpected nature of wildlife, sparking curiosity and wonder among those lucky enough to observe it. 🐜🐜🐜

Swallow Week 2024: Glossary

Swallow Family Glossary: Terms to Help Understanding Swallows

As our week-long celebration of Swallows continues here on the Birdorable blog, we're sharing a glossary of terms related to the family Hirundinidae. Understanding these related terms will help with your understanding of the unique birds in this fascinating cosmopolitan family of insect-feeding birds.

Birdorable Chimney Siwft aerial insectivore

Chimney Swifts are aerial insectivores, catching insects in flight.

Aerial Insectivores

Birds that catch insects in flight, a category that prominently includes swallows.

Apus

A genus of birds in the swift family, often confused with swallows due to their similar appearance and flight patterns. Swifts and swallows are, however, different in their wing structure and nesting habits.

Brood Parasitism

A behavior where a bird lays its eggs in the nests of other birds, relying on them to raise their young. Brood parasitism does not only involve mixed species; in their communal nesting colonies, Cliff Swallows have been observed laying eggs in other Cliff Swallow nests.

Diurnal Migration

The pattern of migrating during the day. Swallows, being diurnal, migrate during the day, utilizing the daylight hours for feeding on insects as they move.

Gape

The wide opening of a bird's mouth, often significantly large in aerial insectivores to facilitate easy feeding.

Hawking

A feeding strategy where birds catch insects in mid-air. Swallows are expert hawkers, gracefully capturing prey during flight with precision.

Hirundinidae

The scientific family name for swallows, from Latin, which encompasses various species of swallows, saw-wings, and martins.

Rictal Bristles

Stiff feather structures around the base of the beak, thought to aid in sensing and catching insects mid-flight. Rictal bristles are present in several aerial insectivorous species, including the swallows, saw-wings, and martins. Rictal bristles are also notable in nighthawks, swifts, and flycatchers -- all specialist aerial insectivores.

Barn Swallow with rictal bristles

Rictal bristles are stiff feathers around the base of the beak to aid in sensing and catching insects mid-flight.

Roost

A place where birds gather to rest or sleep. Swallows can form large roosts during migration periods. Unlike many birds that might roost solitarily or in small family groups, swallows gather in large numbers at roosting sites. 

Trans-Saharan Migrants

Refers to birds, including some swallows, that migrate across the Sahara Desert to reach their breeding or wintering grounds.

Zugunruhe

A German term used in ornithology to describe the increased restlessness in migratory birds, including swallows, as the migration season approaches.

Valentine's Day Bird Term: Billing

Love Is in the Air: Understanding Billing in Birds for Valentine's Day

Birdorable Atlantic Puffins on a cliff in Iceland

In ornithology, the term 'billing' refers to a courtship behavior displayed by certain bird species where two individuals touch, tap, or clasp each other's beaks. It is also known as beak-tapping or bill-tapping. It's called nebbing in British English.

This behavior is often seen in birds that form strong pair bonds and in some ways can be likened to kissing in humans. As today is Valentine's Day (it's always on February 14th), let's look at this interesting bonding behavior, and learn why birds engage in this activity.

Strengthening Pair Bonds
Billing is a sign of affection and helps to strengthen the bond between a mating pair. It is commonly observed in species that mate for life or have long-term partnerships Common Ravens hold each other's bills and feet as part of pair bonding. Atlantic Puffins tap bills quickly as part of their pair bonding behavior, as shown in the video below.

Mutual Grooming
In some cases, billing is part of mutual grooming (allopreening), where birds clean each other's feathers. Rock Pigeons engage in allopreening which includes mutual beak-touching.

Courtship Ritual
Billing is an essential part of the courtship ritual in many species. It is a display of trust and partnership, which can be critical in the mate-selection process. Courting Cedar Waxwings rub their beaks together and pass food to one another. Many albatross species engage in beak-tapping as part of their courtship, like the Waved Albatrosses in the below video.

Territorial and Social Signaling
In some instances, billing can also be a way of demonstrating a pair's territorial bond to other birds, signaling that they are a united and established couple.

Billing is a fascinating aspect of avian behavior that highlights the complex social interactions and emotional connections between birds.

Cute Valentine's Day Gift Ideas from Birdorable

Bird Term: Cosmopolitan

Exploring the Meaning of "Cosmopolitan" in the Avian World

Birdorable Ospreys in locations around the world

Ospreys around the world

Imagine a bird, not confined by national boundaries or familiar landscapes, but a feathered citizen of the world. This is the essence of a cosmopolitan bird species – one that transcends geographic limitations and thrives in a vast tapestry of habitats across the globe. But what exactly does this term mean, and how do birds achieve such remarkable adaptability?

The word cosmopolitan, derived from the Greek kosmopolites, means "citizen of the world."

The core of cosmopolitanism for birds lies in their distribution. Unlike species confined to specific regions or ecological niches, cosmopolitan birds boast expansive ranges that span continents and oceans. The Rock Pigeon, for example, is a ubiquitous urban resident, dotting rooftops from New York to Shanghai. The Arctic Tern, on the other hand, embarks on epic annual migrations, traversing the entire globe from Arctic breeding grounds to Antarctic feeding grounds.

Birdorable Mallards in locations around the world

Mallards around the world

Adaptability plays a crucial role in cosmopolitan bird species. Consider the Cattle Egret, a clever opportunist, following herds of large herbivores like cattle and buffalo, gleaning insects disturbed by their grazing. This nomadic strategy allows it to thrive in a variety of agricultural landscapes worldwide.

Cosmopolitanism isn't a static concept. It's a dynamic interplay between distribution and adaptation, influenced by factors like climate change, habitat availability, and human activities. The House Sparrow, another cosmopolitan champion, has adapted to human settlements so effectively that its range has expanded alongside our own, even in isolated islands and remote mountain villages.

Yet, cosmopolitanism doesn't imply homogeneity. While sharing a global presence, these birds often exhibit regional variations in their populations, behavior, and even appearance.

Ultimately, the meaning of "cosmopolitan" in the avian world is a tapestry woven from vast distributions, remarkable adaptability, and an inherent defiance of boundaries. These birds remind us that the world is not a collection of isolated maps, but a connected web of life, where feathered ambassadors navigate continents and ecosystems with impressive resilience.

European Starling in New York City

Here are some examples of cosmopolitan bird species:

  1. Peregrine Falcon: Found all over the world, this bird of prey is renowned for its impressive speed and hunting prowess. They nest on cliffs in natural areas and on buildings in urban areas.

  2. Barn Owl: With a distribution across every continent except Antarctica, the barn owl is one of the most widely distributed bird species.

  3. Osprey: This fish-eating bird of prey is found near coastlines worldwide, except for polar regions.

  4. Mallard: Native to most of the Northern Hemisphere, it has been introduced to other areas and is commonly found in parks and urban ponds.

  5. European Starling: Originally from Europe, Asia, and North Africa, this bird has been introduced to Australia, New Zealand, South Africa, and North America; it seems to thrive everywhere.

  6. Barn Swallow: These acrobatic aerialists connect continents with their breathtaking migrations. Nesting in farms and buildings across the globe, they spend most of their lives on the wing, catching insects mid-air with stunning precision.

  7. Rock Pigeon: This cosmopolitan species has adapted to urban environments around the world.

  8. House Sparrow: Native to Europe and Asia, these birds have been introduced to and thrived in many parts of the world.

  9. Eurasian Collared-Dove: Originally from Asia and Europe, this species has seen a significant expansion in its range across North America.

  10. Black-crowned Night Heron: Found on every continent except Australia and Antarctica, it is a common species in both freshwater and coastal habitats.

Cute cosmopolitan Birdorable gifts

Imagine a scene straight out of a wildlife documentary, or an AI-rendered, unreal-looking image: flocks of birds, normally seen only in remote northern forests, suddenly descend upon your backyard, filling the air with their calls and vibrant plumage. 

A dramatic, seasonal shift in bird populations is known as an irruption. Let's explore the meaning of this interesting bird term!

What causes irruption?

Bird irruptions are often triggered by fluctuations in food availability. When their usual food sources, like berries, insects, or lemmings, become scarce in their northern habitats, the birds embark on mass southward migrations in search of sustenance. This can happen due to factors like:

Mast years: When certain tree species produce a large, synchronized crop of seeds, it attracts irruptive species like crossbills and grosbeaks.

Insect outbreaks: A boom in insect populations in the north can lead to a subsequent decline as predators flourish, forcing birds to move south for alternative food sources.
Harsh winters: When winter weather arrives early, birds may be forced south to escape the harsh conditions and find food.

What species are affected?

While irruptions can occur with many different bird species, some are more prone to this behavior. Common irruptive birds include:

Finches: Common Redpolls, Pine Siskins, and Evening Grosbeaks are just a few of the species known for their dramatic southward surges in search of seeds and berries. Each year the Finch Research Network reveals a "Winter Finch Forecast" to discuss possible irruptive behavior of native finches and other species.

Owls: Snowy Owls, Northern Hawk Owls, and Great Gray Owls may irrupt southward when their prey populations decline in the north.

Nuthatches: Red-breasted Nuthatches are known for their irruptive movements, often exploring new territories in search of food.

The ecological impact

Bird irruptions can have significant ecological consequences. The influx of birds can disrupt local food webs, benefiting some species and putting pressure on others. Additionally, the introduction of new diseases or parasites from the irrupting birds can pose challenges for resident bird populations.

Flock of Pine Siskins feeding on seed [photo copyright "fishhawk" CC BY 2.0 Deed]

Despite the potential ecological impacts, bird irruptions offer a unique opportunity to observe birds outside their usual ranges. Many birdwatchers are delighted when seldom-seen species can be spotted regularly during the season.

Birdorable Gifts Featuring Irruptive Birds

Bird Term: Lek

Read About Lekking: What It Means And Which Birds Do It

Greater Prairie-Chicken Lek in Nebraska by Gregory "Slobirdr" Smith (CC BY-SA 2.0 Deed)

A lek is a group of male animals, most commonly birds or insects, that gathers as part of a breeding strategy. The males perform displays in an arena-like setting in order to lure observing females into mating.

Lekking in most bird species is like a big mating party where males perform dances, sing songs, and display strange body art to entice females. Females gather around the lek to watch the performances, comparing the potential partners and then eventually accepting the invitation of a male bird to mate. But then the party is over -- males are completely uninvolved in nesting activities like incubation and brooding.

Lesser Prairie-Chicken Lek in New Mexico by Larry Lamsa (CC BY 2.0 Deed)

Although this type of mate selection might seem to indicate a lack of partner fidelity, in many bird species females only come to lekking sites when their (previous) male partner is present.

Some bird species that display lekking behavior include the Long-wattled Umbrellabird, Black Grouse, Sage Grouse, Capercaillie, Kori Bustard, Sharp-tailed Grouse, birds-of-paradise, the Kakapo, and the Greater Prairie-Chicken and Lesser Prairie-Chicken.

Other species that engage in lekking include some types of paper wasps, fruit bats, bullfrogs, and moths.

Sage Grouse Lek in Oregon by Nick Myatt, Oregon Department of Fish and Wildlife (CC BY-SA 2.0 Deed)

Birdorable Gifts Featuring Birds that Lek