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Passerida

Passerida is a monophyletic within the suborder Oscines of the order Passeriformes, comprising approximately 4,000 species that represent about 36% of all extant bird species worldwide (as of 2025). This group, primarily a radiation with a global distribution, is defined by genetic autapomorphies such as a one-codon insertion in the c-myc gene and encompasses a diverse array of songbirds adapted to varied habitats from forests to urban environments. Phylogenetic studies based on nuclear and mitochondrial DNA sequences have resolved Passerida into four major clades, with the deepest branches including the African rockfowl (Picathartes) and rockjumpers (Chaetops), followed by three principal superfamilies that account for the bulk of its diversity. Sylvioidea, the largest superfamily, includes families such as the babblers (Timaliidae), bulbuls (Pycnonotidae), swallows (Hirundinidae), and sylviine warblers (Sylviidae), many of which are insectivorous and arboreal. Muscicapoidea comprises thrushes (Turdidae), Old World flycatchers (Muscicapidae), starlings (Sturnidae), mockingbirds (Mimidae), dippers (Cinclidae), and waxwings (Bombycillidae), featuring species known for their melodious songs and migratory behaviors. Passeroidea, often called the "passerine finches," encompasses larks (Alaudidae), pipits (Motacillidae), weavers (Ploceidae), finches (Fringillidae), sparrows (Passeridae), tanagers (Thraupidae), and New World warblers (Parulidae), many of which are seed-eaters or nectarivores with vibrant plumage. The of Passerida originated from DNA-DNA hybridization studies by Sibley and Ahlquist in , which proposed the initial division into these superfamilies, and has been refined through subsequent molecular analyses confirming their . These birds exhibit complex vocalizations, advanced learning abilities, and ecological roles as pollinators, seed dispersers, and insect controllers, contributing significantly to across continents.

Overview

Definition and classification

Passerida constitutes a monophyletic within the oscine passerines of the suborder Passeri, order , representing the core group of songbirds while excluding basal oscine lineages such as lyrebirds (family Menuridae) and scrubbirds (family Atrichornithidae). The taxonomic concept of Passerida was introduced in 1988 by Charles G. Sibley, Jon E. Ahlquist, and Burt L. Monroe Jr. as part of a comprehensive derived from DNA-DNA hybridization analyses, where it was designated as a parvorder sister to the parvorder Corvida within Passeri. In contemporary phylogenetic frameworks, Passerida retains its monophyletic status and parvorder or infraorder rank, though the sister group Corvida has been resolved as paraphyletic through DNA sequence data. Within the order Passeriformes, Passerida occupies a derived position among the oscines, historically contrasted with nine-primaried oscines (such as wood-warblers in family Parulidae) in morphological classifications, but molecular phylogenies have clarified that these groups are nested within Passerida rather than forming a distinct sister . Encompassing approximately 4,000 (as of 2025), Passerida accounts for about 36% of all known bird worldwide. Traditional schemes further subdivide Passerida into three primary superfamilies: , Muscicapoidea, and Passeroidea.

Diversity and significance

Passerida represents one of the most diverse clades within the Passeriformes, encompassing over 4,000 across more than 50 families and accounting for more than a third of all extant bird . This vast diversity is particularly pronounced in temperate and tropical regions, where Passerida form a dominant component of local avifaunas. Ecologically, Passerida birds fulfill critical roles as pollinators, seed dispersers, and primary insectivores, thereby supporting and controlling populations across a range of habitats from forests and grasslands to urban environments. Their high adaptability enables them to thrive in diverse conditions, significantly contributing to overall maintenance and stability. In scientific research, Passerida serves as a premier model group for investigating processes, vocal learning mechanisms, and migratory behaviors, owing to the clade's extensive phylogenetic resolution and experimental tractability. Species within Passerida are overrepresented in avian genomics studies, with genomes like that of the providing foundational insights into bird evolution and gene function. From a conservation perspective, while many Passerida species demonstrate resilience through widespread distributions and adaptability, the includes numerous threatened taxa, particularly island endemics such as the , which face severe risks from habitat loss and invasive diseases. Human interactions with Passerida are extensive, with species like finches being highly sought after in the global pet trade due to their vibrant plumage and song capabilities. Additionally, Passerida birds hold cultural prominence, exemplified by the nightingale's enduring symbolism in as a muse for themes of love, loss, and renewal across various traditions.

Characteristics

Morphological features

Passerida, the largest within the oscine passerines, exhibit a typical size range of small to medium-bodied , measuring 8–52 cm in length and weighing 5–550 g, with compact bodies that facilitate agile flight and perching. This range encompasses species from tiny warblers around 5 g to larger oropendolas (Psarocolius spp.) approaching 550 g, reflecting adaptations for diverse ecological niches while maintaining a generally build for energy-efficient locomotion. Their feet are characteristically anisodactyl, featuring three forward-facing toes and an opposable hind toe (hallux), which enables strong gripping on perches and branches. Plumage in Passerida is diverse, often serving cryptic functions for or displaying vibrant colors, particularly in males where sexual dichromatism is common and linked to mating displays. Molting patterns typically involve a complete annual prebasic molt, replacing feathers to maintain aerodynamic efficiency for flight and , with some species undergoing partial prealternate molts to enhance plumage. is pronounced in certain groups, such as estrildid finches and some cardinals, where males exhibit brighter plumage due to carotenoid deposition influenced by testosterone. Skeletal adaptations include 9–10 primary on each wing, supporting sustained flight and maneuverability, alongside elongated hindlimbs that enhance perching stability through extended tarsometatarsi and robust flexor tendons. The , a bifurcated vocal organ with at least five pairs of intrinsic muscles in oscines, enables complex song production through independent control of medial and lateral labia, allowing for wide frequency ranges and spectral diversity. Sensory features comprise relatively large eyes relative to body size, providing high for detecting prey and navigating environments, often with tetrachromatic vision including sensitivity. Bill morphology varies widely to reflect dietary specializations, such as conical bills in seed-eating finches (e.g., Passer domesticus) for cracking husks or slender, curved bills in nectarivores like sunbirds for probing flowers.

Behavioral traits

Passerida, comprising the majority of oscine songbirds, exhibit vocal production learning, an innate ability to imitate and innovate complex songs based on auditory experience from tutors, typically during a sensitive juvenile period. This learning process enables the development of species-specific repertoires that serve functions in mate attraction and territory defense. Regional dialects, variations in song structure learned from local populations, are prominent in species like the (Zonotrichia leucophrys), where young males preferentially copy conspecific songs with introductory whistles, leading to population-specific syllable patterns that can influence and . The anatomy, with its dual sound sources and muscular control, underpins this vocal complexity unique to oscines. Social structures in Passerida are predominantly monogamous, with pairs forming seasonal or lifelong bonds that facilitate and resource sharing. Males commonly engage in territorial singing to establish and defend areas, often from elevated perches, signaling dominance and deterring rivals through repetitive, stereotyped phrases. During non-breeding periods, many shift to , forming mixed-species groups that enhance foraging efficiency and provide collective vigilance against predators, as seen in winter aggregations of sparrows and finches. Foraging behaviors among Passerida are diverse, reflecting adaptations to various niches; for instance, flycatchers in the superfamily Muscicapoidea specialize in aerial insect hawking, sallying from perches to capture flying prey mid-air with precise bill snaps. Thrushes, also in Muscicapoidea, employ ground gleaning, hopping to probe leaf litter and soil for using their probing bills. Nectar feeding is prevalent in sunbirds (Nectariniidae) within Passeroidea, where tubular tongues and curved bills allow efficient extraction from flowers, often while hovering. Tool use remains rare but is exemplified in , such as the woodpecker finch (Camarhynchus pallidus), which modifies twigs or cactus spines to extract arthropods from tree crevices, a acquired through individual and social learning. Migration patterns vary, but long-distance migration is common in many Passerida species, including warblers (Sylvioidea) that undertake transoceanic flights spanning thousands of kilometers between and wintering grounds. Navigation relies on a multimodal system, integrating a magnetic sensitive to Earth's geomagnetic field for directional orientation with celestial cues like polarized light patterns and star positions for calibration, enabling precise route following even under overcast conditions. Parental care in Passerida is typically biparental, occurring in approximately 81% of bird species overall and predominant among passerines, with both sexes contributing to nest , , and offspring provisioning to maximize fledging success. Feeding involves both parents delivering or to nestlings, often in coordinated bouts to reduce predation risk. Nest architectures vary widely, from simple open cups woven with grasses in sparrows to elaborate pendulous pouches suspended from branches in penduline tits (Remizidae), providing protection from ground predators.

Distribution and habitats

Global distribution

Passerida, the largest within the oscines (songbirds), exhibit a near-cosmopolitan geographic range, occurring on all continents except and absent from polar extremes as well as certain remote oceanic islands such as those in the far southern . This distribution encompasses over 3,500 , representing approximately 36% of all bird species, with the highest diversity concentrated in the and of the . Eurasia and Africa serve as primary centers of origin and diversification for Passerida, where basal lineages emerged following early Miocene dispersals across into , leading to subsequent radiations. From these continental cores, Passerida lineages invaded the , likely via the during periods of connectivity, with examples including the ancestors of New World warblers (Parulidae) and (Thraupidae). Similarly, incursions into occurred through island-hopping from , though diversity remains lower there compared to the . High levels of endemism characterize island radiations within Passerida, particularly in isolated archipelagos where adaptive diversification has produced unique assemblages. In , the honeycreepers (subfamily Drepanidinae within Fringillidae) represent a classic example, evolving from a single finch-like into over 50 with diverse bill morphologies adapted to local resources, though as of 2025, only 17 remain, many extinct or due to habitat loss and . In the , (genus Orthotomus within Cisticolidae, ) exhibit significant endemism, with such as the Visayan tailorbird (O. castaneiceps) restricted to specific islands like and , contributing to the region's hotspot status. Human-mediated introductions have further expanded Passerida distributions, often with negative ecological consequences for native avifauna. The European starling (Sturnus vulgaris, Sturnidae within Muscicapoidea), introduced to in 1890, has proliferated across the continent, competing aggressively for nesting cavities and displacing species like bluebirds and woodpeckers. Similarly, the house sparrow's global spread via shipping and colonization has led to nest usurpation and predation on native songbirds in the and . These invasions underscore Passerida's adaptability but highlight ongoing threats. Passerida dominate several biogeographic realms, particularly the Palearctic, , and , where they account for the majority of passerine diversity through ancient biotic exchanges between Africa and Asia. In the Palearctic, temperate and boreal forests host numerous migrants and residents; the features high endemicity in savannas and rainforests; and the Indomalayan realm, including Southeast Asian hotspots, supports dense assemblages in montane and lowland habitats. Contributions from superfamilies like enhance regional patterns, with alone comprising over 1,300 species across these areas.

Preferred habitats

Passerida species exhibit a broad habitat spectrum, encompassing forests as primary environments for many warblers, such as the which favors mature deciduous forests for breeding. Grasslands serve as key habitats for larks, including the that prefers sparsely vegetated open areas with short grasses and bare ground. Wetlands are essential for reed warblers, like the Eurasian reed warbler, which inhabits dense reed beds in riverine and marshy areas. Urban environments support species such as the , which readily occupies human-altered spaces around buildings and farms. Adaptations to these niches vary widely among Passerida; for instance, tree creepers are arboreal specialists that climb tree trunks in woodland habitats to forage for . Ground-dwelling pipits, such as the American pipit, thrive in open, sparsely vegetated terrains where they walk and run to capture prey. occupy aquatic margins along swift, clear streams, diving underwater to feed on in rocky substrates. The spans a wide altitudinal range, from to high elevations, with the inhabiting montane zones up to 5,000 m in rocky alpine meadows. Passerida demonstrates broad climate tolerance, including temperate migrants that breed in seasonal northern latitudes and overwinter in warmer regions, tropical residents adapted to year-round equatorial conditions, and desert specialists like the desert wheatear that exploit arid rocky terrains. Many Passerida species have successfully colonized human-modified habitats, such as agricultural fields and cities, facilitating range expansions; for example, the has proliferated in urban and rural developed areas globally.

Evolutionary history

Origins and divergence

The Passerida, comprising the majority of oscine passerines, originated through divergence from basal oscines during the late Eocene to early , approximately 30–40 million years ago (Ma), following the broader post-Cretaceous radiation of Passeriformes that began in the early . This temporal origin aligns with analyses indicating a crown age for oscines around 38–47 Ma in the to Late Eocene, with Passerida emerging as a distinct amid the diversification of songbirds in the Australo-Pacific region. The initial radiation of passerines is traced to Gondwanan fragments, particularly , where ancestral populations adapted to fragmented landscapes after the breakup of . Key divergence events mark the separation of Passerida from more basal oscine lineages, including a split from Menurae (lyrebirds and allies) estimated at around 44–50 Ma during the Eocene, reflecting early oscine branching prior to the full emergence of advanced groups. Subsequent into the major superfamilies of Passerida occurred rapidly around 25–30 Ma in the , coinciding with the expansion of ecological niches in and as ancestral Australasian stocks dispersed northward. Ancestral traits of Passerida likely included enhanced vocal learning capabilities and small body sizes suited to forested understories, building on the song-producing inherited from earlier oscines. Phylogenetic reconstructions, such as those based on multi-locus datasets, illustrate these basal splits as foundational to the clade's explosive diversification. Adaptive drivers for Passerida's origins and early divergence were profoundly influenced by global climate cooling and the expansion of temperate forests during the Eocene-Oligocene transition, which fragmented tropical biomes and promoted through habitat isolation. This environmental shift, marked by declining temperatures and CO2 levels around 34 Ma, created diverse woodland mosaics that favored the of complex songs in Passerida for mate attraction and territorial signaling amid increasingly noisy, vegetated environments. Molecular clock estimates, derived from (mtDNA) and nuclear genes using Bayesian relaxed-clock methods calibrated with priors, consistently support this rapid diversification, with net rates accelerating in response to these biotic and abiotic changes.

Fossil evidence

The fossil record of Passerida, the largest within the oscine songbirds (Passeriformes), is notably sparse, reflecting the challenges posed by the small size and fragile skeletal structure of these birds, which often results in poor preservation. The earliest definitive s attributable to passerines, including potential basal Passerida members, date to the early (approximately 30–34 million years ago) in , providing the initial for the group's radiation in the . These records confirm an Old World origin for Passerida, with subsequent diversification evident in deposits, though the pre-Miocene scarcity leaves significant chronological gaps that are partially bridged by molecular phylogenetic estimates aligning with late Eocene to early Oligocene divergence timelines. Key early specimens include a well-preserved from the Frauenweiler locality in , representing the oldest European and exhibiting morphological traits consistent with early oscine affinities, such as a robust deltoidal . In , a nearly complete articulated leg from the early (ca. 29 million years ago) provides the earliest full record of a , featuring a short, indicative of perching adaptations typical of Passerida. Additional finds from the same period in include a partial assigned to the earliest known Tyrannida (a suboscine group, but relevant for basal context), dated to around 30 million years ago, with ambiguous fragments from other sites showing mosaic features that preclude precise assignment to Passerida but suggest sympatric coexistence of suboscine and oscine lineages. By the (ca. 23–5 million years ago), Passerida fossils become more diverse and geographically widespread, particularly in , where sylvioid-like forms (e.g., potential early relatives of warblers and allies in ) appear in deposits from and . For instance, isolated sterna and partial skeletons from the middle of (ca. 12 million years ago) exhibit oscine characteristics, including a bifurcated sternal rostral margin, supporting the expansion of Passerida across temperate . In , passeroid forms emerge in the early , such as a scansorial certhioid bird (related to treecreepers in Passerida) from eastern , dated to around 16 million years ago, with elongated phalanges adapted for climbing that highlight ecological diversification in forested habitats. The limitations of the fossil record stem primarily from the anatomical fragility of Passerida bones, which are thin-walled and prone to fragmentation, leading to underrepresentation in sedimentary deposits before the Miocene. Ambiguous pre-Miocene fragments, such as isolated pedal elements from late Oligocene sites in Germany, further underscore these challenges, as they often display a mix of primitive and derived traits without clear Passerida attribution. No significant Passerida fossils have been reported from amber inclusions in the Miocene Dominican Republic or elsewhere in the 2020s, though such deposits have preserved smaller invertebrates and occasionally avian soft tissues, suggesting potential for future tropical discoveries that could illuminate persistence in Neotropical regions. Overall, while fossils affirm an Old World cradle for Passerida evolution, the record's gaps emphasize reliance on integrated paleontological and molecular approaches to reconstruct deeper history.

Systematics and phylogeny

Phylogenetic position

Passerida constitutes a major monophyletic within the suborder Passeri (oscines) of the Passeriformes, encompassing approximately 4,000 of advanced songbirds and forming the bulk of passerine diversity. It belongs to the parvorder Euoscines (also known as Passerides), where it serves as the to Corvides, the other principal Euoscine radiation that includes crows, shrikes, and allies. This positioning excludes the suboscine and the more basal oscine lineages such as Acanthisitti () and Menurae (lyrebirds and scrubbirds). The clade's overall placement as a crown-group oscine radiation was established through early molecular phylogenies in the , which utilized nuclear DNA sequences to reconstruct the deep structure of Passeriformes. The of Passerida received strong confirmation from multi-locus analyses, including genes like RAG-1, RAG-2, and , yielding bootstrap support values greater than 95% for the defining node. These studies resolved earlier suggestions of , which stemmed from morphological assessments and limited mitochondrial datasets, by demonstrating consistent signal for Passerida as a unified group originating from an Australasian ancestor dispersing to . High cladistic support has persisted across datasets, with no significant conflicts in comprehensive phylogenies sampling hundreds of taxa. Genomic-scale investigations have further refined Passerida's basal relationships within Passeriformes, upholding its position to Corvides with posterior probabilities approaching 1.0 in coalescent-based trees derived from thousands of loci. A 2024 analysis of family-level genomes across birds, incorporating over 63,000 intergenic sites, provided near-complete statistical support (98.1% of nodes at full ) for this while clarifying short internodes at deep oscine divergences. Similarly, a 2019 supertree integrating mitogenomic and nuclear data across all families reinforced these findings, with over 95% of deep nodes exhibiting bootstrap values above 70% and higher for the Passerida-Corvides split. A 2025 supertree integrating data from nearly 300 studies confirmed this framework as the consensus, with Passerida's superfamilies (, Muscicapoidea, Passeroidea) as its key subclades.

Superfamily Sylvioidea

The superfamily represents the basal lineage within the parvorder Passerida, encompassing a diverse radiation of oscine passerines that diverged early in the evolutionary history of this group. It includes approximately 1,300 distributed across more than 30 families, accounting for a significant portion of Passerida diversity. Prominent examples include the and (Hirundinidae), (Pycnonotidae), and (Zosteropidae), alongside other groups such as larks, warblers, and reedlings. This superfamily is characterized by its , as confirmed by molecular analyses using mitochondrial 12S sequences, which resolve Sylvioidea as a well-supported sister to the remaining Passerida superfamilies. Phylogenetic studies indicate that originated as the earliest branching superfamily within Passerida, with basal divergences involving families like Alaudidae (larks) and Hirundinidae (), followed by successive radiations into more derived lineages. The 2015 analysis in Avian Research utilized extensive sampling to affirm this monophyletic structure, highlighting early splits that gave rise to ground-dwelling forms like larks and aerial insectivores like before the diversification of arboreal and shrub-dwelling groups. Key families within include Alaudidae, with around 100 species of cosmopolitan but predominantly larks adapted to open habitats; Hirundinidae, comprising about 90 species of agile, aerial-feeding and martins; , featuring roughly 32 species of small, secretive warblers in the ; and , with over 150 species of colorful, vocal primarily in and . These families exemplify the superfamily's morphological and ecological breadth, from terrestrial to volant specialists. Shared traits among taxa include predominantly insectivorous diets, with many species foraging by or aerial hawking, supplemented seasonally by fruits or seeds in some groups like . Long-distance is prevalent, particularly in Palearctic warblers and that undertake transcontinental journeys between breeding grounds in and and wintering sites in or . The superfamily is predominantly Old World-centric, with the majority of species and families concentrated in , , and , and limited representation in the except for a few wrens and gnatcatchers. Sylvioidea exhibits its highest diversity in and , where tropical and subtropical habitats support dense assemblages of , , and babbler-like forms, contributing to over 70% of the superfamily's in these regions. Recent taxonomic revisions have further highlighted this dynamism, such as the elevation of parrotbills to their own family, Paradoxornithidae, based on molecular evidence resolving them as a distinct within , separate from traditional warbler groupings. This split, supported by multilocus phylogenies, underscores ongoing refinements in understanding the superfamily's internal boundaries.

Superfamily Muscicapoidea

The superfamily Muscicapoidea constitutes a major mid-level within the parvorder Passerida, comprising approximately 700 species across 15 families, including prominent groups such as thrushes (Turdidae), flycatchers and (Muscicapidae), (Cinclidae), and (Troglodytidae). This diverse assemblage represents a key branch in the oscine radiation, bridging basal Passerida lineages with more derived ones. Phylogenetically, Muscicapoidea occupies an intermediate position in Passerida as the sister taxon to Passeroidea, forming the Muscicapida; its has been robustly confirmed through whole-genome analyses in 2024 genomic studies utilizing thousands of intergenic loci across hundreds of bird species. Early evolutionary splits within the superfamily separated the muscicapids—encompassing flycatchers, , and —from the turdoids, which include thrushes and their allies, with these divergences estimated around 20–25 million years ago based on time-calibrated molecular phylogenies. Following the as the successive in Passerida, Muscicapoidea exhibits deeper internal branching compared to the more uniform radiation. Among the key families, Turdidae (thrushes and allies) includes about 170 known for their terrestrial foraging and complex vocalizations, while Muscicapidae ( flycatchers, robins, and ) encompasses roughly 320 adapted to aerial capture. Cinclidae () is a small family of 5 specialized for streamside habitats, and Troglodytidae () features around 90 of diminutive, secretive birds prevalent in environments. Members of Muscicapoidea share behavioral traits such as perch-and-glean , where scan from elevated perches before capturing prey, and melodious, complex songs often used in territorial defense and mate attraction. Notable adaptations include the aquatic diving capabilities of , which enable , and cavity-nesting habits in various thrushes and flycatchers that enhance nest . The superfamily's diversity spans global distributions, from temperate and to tropical , with a pronounced emphasis in the New World exemplified by the extensive radiations of (Troglodytidae) and (Mimidae) across diverse habitats like forests, shrublands, and mountains. These adaptive expansions, particularly in the , highlight Muscicapoidea's role in filling ecological niches vacated by other groups during Miocene diversification events.

Superfamily Passeroidea

The superfamily Passeroidea constitutes a major derived within group of Passerida, characterized by its granivorous core and encompassing approximately 1,400 extant across more than 20 families, including representatives such as finches, sparrows, and weavers. This superfamily represents one of the most -rich radiations among songbirds, contributing significantly to the overall diversity of Passeriformes, which exceeds 6,000 globally. Phylogenetically, Passeroidea is monophyletic and positioned as the to Muscicapoidea, with the combined being sister to in the Passerida parvorder; this topology has been robustly supported by molecular data from nuclear and mitochondrial genes. A 2025 supertree integrating genomic data from nearly 300 studies has further refined internal relationships within Passeroidea, particularly clarifying the positions and divergences among emberizid buntings and sparrows, enhancing understanding of their evolutionary dynamics. The core Passeridae family anchors this monophyly, with broader inclusions like sunbirds and fairy-bluebirds receiving consistent support in earlier studies. Prominent families in Passeroidea include Passeridae (Old World sparrows and snowfinches), Fringillidae (true finches), Estrildidae (waxbills and allied finches), and (weavers and buffalo-weavers), which collectively highlight the superfamily's emphasis on seed-dependent lineages. These groups share morphological and behavioral adaptations suited to granivory, such as stout conical bills for seed processing, often paired with colonial nesting strategies that facilitate resource exploitation in open habitats. Passeroidea displays a , achieving dominance in temperate regions of the Palearctic and Nearctic realms through families like Fringillidae and Passeridae, while tropical diversity is bolstered by African radiations, notably in , where over 140 species have evolved in savannas and grasslands. Certain species exhibit high invasiveness, exemplified by the (Haemorhous mexicanus) in Fringillidae, which has rapidly expanded across following introductions in the early , impacting local ecosystems through and transmission.

Basal lineages within Passerida

Passerida includes several small, resolved basal clades that branch before the three main superfamilies, encompassing roughly 100 primarily in Australasian, , and Pacific distributions. These groups represent early divergences in the Passerida radiation and are now well-placed through molecular phylogenies, though some exhibit rapid diversification leading to short branches. Examples include the of rockfowl (Picathartidae, 2 ) and rockjumpers (Chaetopidae, 2 ), which form the deepest branch; the encompassing the rail-babbler (Eupetidae, 1 ) and Australasian (Petroicidae, ~45 ); and the kinglets (Regulidae, ~10 ), which are sister to the main superfamilies. Other taxa previously considered uncertain, such as (Drepanidinae, ~17 extant ), are now nested within Passeroidea as a tribe of , demonstrating from a cardueline ancestor. Sugarbirds (Promeropidae, 2 endemic to ) are placed as a basal lineage to Passeroidea. Oxpeckers (Buphagidae, 2 ) are allied to Sturnidae within Muscicapoidea. Phylogenetic analyses, including 2024 genomic studies, reveal short internal branches and rapid diversification around 22–26 million years ago, but full resolution is supported by expanded sequencing. Traits like convergent nectarivory in honeycreepers and sugarbirds illustrate driven by similar ecological niches.

Taxa outside Passerida

Taxa outside Passerida encompass oscine and other lineages that fall basal to the core clade within the order Passeriformes, representing early divergences in passerine evolution. These groups include the Menurae, which comprises the families Menuridae (lyrebirds) and Atrichornithidae (scrubbirds), positioned as sister to all remaining oscines, and the Acanthisittidae (), which form the to all other . Historically, these taxa were often erroneously grouped within broader oscine assemblages based on morphological similarities, such as shared Australasian distributions and certain skeletal traits, leading to pre-DNA classifications that included them alongside groups now recognized as Passerida members. Molecular phylogenetic analyses, particularly the 2004 study using RAG-1 and RAG-2 genes across 144 passerine species, resolved these errors by demonstrating their basal positions and excluding them from Passerida. Distinguishing traits include a simpler syrinx structure compared to the highly complex, four-syllable vocal organ typical of Passerida oscines; for instance, Menurae possess a syrinx intermediate between suboscine and advanced oscine forms, while Acanthisittidae exhibit a suboscine-like simplicity. Biogeographically, these taxa are restricted to Australasian endemics, with lyrebirds and scrubbirds in eastern and New Zealand wrens confined to , reflecting ancient Gondwanan isolations rather than the global radiation seen in Passerida. As of 2025, comprehensive genomic phylogenies continue to affirm these exclusions, with no evidence of re-inclusion into Passerida; for example, analyses incorporating thousands of loci across maintain the Menurae as the earliest oscine divergence and Acanthisittidae as the most basal lineage. This reinforces Passerida by excluding these basal groups.