A pseudoscorpion belonging to the family Chthoniidae, subfamily Chthoniinae and the tribe Tyrannochthoniini. Genus includes new species B. kachinae and B. muelleri.
A tick combining a body resembling that of a soft tick with a basis capitulum more like that of a hard tick, assigned to a new family Khimairidae as a possible transitional form between soft and hard ticks. Genus includes new species K. fossus.
Possibly a member of the family Palaemonidae. Announced in 2022; the correction including evidence of registration in ZooBank was published in 2023.[40]
A crab, probably a member of the family Orithopsidae. The type species is C. camilosantanai. Announced in 2022 in an online-only journal, and the publication did not include a ZooBank registration number; validated in 2023.[44]
Redescription of Oncopareia bredai and a revision of other species previously referred to the genus Oncopareia is published by Tshudy et al. (2022).[64]
A study on the evolution of carapace morphology of hermit crabs and changes of composition of their assemblages through time is published by Fraaije et al. (2022), who reinstate Probeebeidae as a distinct family, and name a new family Paguropsidae.[65]
A study on sexual dimorphism and intersex specimens in the population of hundreds of specimens of the Cretaceous crab Dakoticancer overanus Jones, Schweitzer & Feldmann (2022).[66]
Ossó et al. (2022) report the first known fossil material of Pleolobites from the Paleocene (Thanetian) of Togo, and reevaluate the phylogenetic affinities of this and other fossil portunoid crabs.[67]
A concretion containing an adult and a juvenile individual of Trichopeltarion greggi, representing the first association of an adult female and a juvenile crab of the same species in the fossil record reported to date, is described from the Miocene Greta Siltstone (New Zealand) by Feldmann & Schweitzer (2022), who interpret this finding as possible evidence of maternal care of juveniles.[68]
A new genus erected for Triassic ostracods formerly assigned to the genus Acanthoscapha, such as "Acanthoscapha" veghae Kozur (1970), "Acanthoscapha" mersinella Forel in Forel et al. (2017) and "Acanthoscapha" amphialata Kristan-Tollmann (1973). The generic name is preoccupied by the radiolarian genus Kozuria Zhang (1990).
A notostracan of uncertain affinities. The type species is "Triops cancriformis" permiensis Gand, Garric & Lapeyrie (1997), raised to the rank of the species Heidiops permiensis.
Collareta et al. (2022) describe borings on a sea turtle carapace from the Miocene (Tortonian) Pisco Formation (Peru), interpreted as probable attachment scars produced by turtle barnacles, and argue that sea turtles may have hosted barnacle symbionts as early as during the early Oligocene.[108]
New information on the anatomy of Stanleycaris hirpex, based on data from 268 specimens from the Cambrian Burgess Shale (British Columbia, Canada), is presented by Moysiuk & Caron (2022), who report exquisite preservation of the brain of this radiodont and unexpected presence of a large median eye.[110]
A member of the family Ellipsocephalidae belonging to the subfamily Ellipsocephalinae. The type species is "Ornamentaspis" usitata Geyer (1990); genus also includes new species C. bommeli and C. robusta, and possibly also Ornamentaspis? todraensis Geyer (1990).
A phacopid trilobite. Genus includes new species C. junggariensis. The genus Clarksonops was subsequently considered to be a junior synonym of the genus Omegops by Zong (2023), resulting in a new combination Omegops junggariensis.[122][123]
A member of the family Ellipsocephalidae belonging to the subfamily Protoleninae. The type species is "Proampyx" grandis Ahlberg & Bergström (1978); genus also includes "Cambrunicornia" agdziensis Geyer (1990).
A member of the family Ellipsocephalidae belonging to the subfamily Ellipsocephalinae. The type species is "Comluella" scanica Ahlberg & Bergström (1978).
A member of the family Phillipsinellidae. The type species is F. idoli; genus also includes new species F. adamanti, as well as "Agerina" laurentica Ingham & Tripp (1991) and "Agerina" norrisi Ludvigsen (1980).
A replacement name for Mexicaspis Lochman (1948).
Not valid because prior replacement: Caspimexis Özdikmen 2005
in: Paleontological Journal 39(5):563-564
The type species is "Toxotis" venustus Lazarenko (1968); genus also includes new species T. artus, T. kotuyensis, T. nelegensis, T. tuberculosus and T. ventosus.
A member of the family Calymenidae belonging to the subfamily Reedocalymeninae.
Trilobite research
A study on patterns of segment allocation and expression in the bodies of trilobites throughout their evolutionary history is published by Hopkins & To (2022), who argue that neither taxonomic turnover nor enrolment behaviour of trilobites can sufficiently explain the studied changes of segmentation patterns.[137]
A study on the early evolutionary history of trilobites is published by Holmes & Budd (2022), who argue that the first appearance datum of trilobites in the fossil record closely reflects their evolutionary origins, and that there is no compelling evidence to suggest an extended cryptic evolutionary history for this group.[138]
A study on the injured specimens of Redlichia takooensis and Redlichia rex from the Cambrian Emu Bay Shale (Australia) is published by Bicknell et al. (2022), who argue that R. rex was likely the chief producer of the injuries in the studied specimen and of large shelly coprolites in the Emu Bay Shale biota, and represents one of the earliest cannibalistic trilobites.[140]
Losso & Ortega-Hernández (2022) report evidence of the presence of significantly modified and reduced endopodites underneath the seventh thoracic and first pygidial tergites of Olenoides serratus and interpret these appendages as likely functional analogs to claspers.[141]
A study on the phylogenetic relationships of members of the olenid group Hypermecaspidinae is published by Monti, Tortello & Confalonieri (2022).[142]
Revision of Ordovician trilobite collections from Shan State (Myanmar) and Yunnan (China), first described by F.R.C. Reed, is published by Fortey, Wernette & Hughes (2022).[143]
A study on the growth and mortality of Triarthrus eatoni, reevaluating the data presented by Cisne (1973),[144] is published by Pauly & Holmes (2022).[145]
Edgecombe & Fortey (2022) describe a specimen of Asaphellus tataensis from the Fezouata Formation (Morocco) preserved with antennae bearing a series of round, dome-shaped organs of uncertain homology and function, larger than sensilla on the antennae of other arthropods.[146]
A study on the degree and structure of modularity in the heads of Calyptaulax annulata and Cloacaspis senilis is published by Vargas-Parra & Hopkins (2022), who consider the best modularity models to be those in which the eyes and anteriormost cranidium formed a single module, or belonged to two modules that highly covaried relative to other modules.[147]
Bicknell & Smith (2022) seven new abnormal specimens of Odontopleura (Sinespinaspis) markhami from the Silurian (Telychian) Cotton Formation (Australia), interpreting their abnormalities as teratological developments through genetic malfunctions, and evaluate likely causes of abnormalities in Silurian trilobite specimens in general.[148]
A study on the distribution patterns of Devonian trilobites from Morocco and northwestern Algeria through time and space is published by Bault, Crônier & Bignon (2022).[149]
A study on the morphological diversity and possible relationship between morphology and environmental and/or ecological factors in Devonian trilobites from North Africa is published by Bault, Crônier & Monnet (2022).[150]
A study on changes in global distribution of trilobites during the late Paleozoic is published by Brezinski (2022).[151]
A study on functional morphology, coaptation and palaeoecology of selected acastid trilobites was published by Van Viersen & Kloc (2022).[117]
A study on the morphological diversity of cephalic sclerites of asteropygine acastids throughout their evolutionary history is published by Martin et al. (2022).[152]
A bivalved arthropod. Genus includes new species V. montcalmi.
Redescription of Chuandianella ovata, based on data from new specimens from the Yu’anshan Member of the Chiungchussu Formation (Cambrian Stage 3; Yunnan, China) preserving unprecedented details of their soft anatomy, is published by Zhai et al. (2022).[173]
A study on the ventral aspect of head organization of Jianfengia multisegmentalis, and on its evolutionary significance, is published by Zhang et al. (2022).[174]
Redescription of Triopus draboviensis is published by Van Roy, Rak & Fatka (2022), who also provide a revised diagnosis for Cheloniellida, and exclude Parioscorpio venator from this clade.[175]
Redescription of the ventral morphology of Retifacies abnormalis and a study on the implications of this taxon for the knowledge of the relationships and evolution of Cambrian artiopods is published by Zhang et al. (2022).[176]
A study on the appendicular organization in Pygmaclypeatus daziensis and on its ecological and evolutionary implications is published by Schmidt et al. (2022).[177]
Description of the organization of the central nervous system of a specimen of Mollisonia symmetrica from the Burgess Pass (Burgess Shale; British Columbia, Canada) is published by Ortega-Hernández et al. (2022).[178]
A study on the evolutionary stability in the history of fossil and living xiphosurids is published by Bicknell et al. (2022).[179]
Revision of Australian xiphosurids Austrolimulus fletcheri, Dubbolimulus peetae, Tasmaniolimulus patersoni and Victalimulus mcqueeni, and a study on the temporal range of these taxa is published by Bicknell et al. (2022), who reinterpret T. patersoni as living in the Triassic rather than Permian.[180]
New specimen of Vaderlimulus tricki, providing new information on the anatomy of this xiphosuran and representing the first record of muscles in an austrolimulid reported to date, is described from the OlenekianThaynes Group (Idaho, United States) by Lerner & Lucas (2022).[181]
A study on the ontogenetic stages, allometry and ecology of Paleolimulus kunguricus is published by Naugolnykh & Bicknell (2022).[182]
A study on the anatomy of the chelicerae of Slimonia acuminata, based on data from a new specimen, is published by Lamsdell (2022).[183]
Braddy & Gass (2022) redescribe tracks from the Ordovician Martinsburg Formation (New York, United States) assigned to the ichnotaxon Palmichnium gallowayi, attribute these tracks to a medium-sized stylonurid eurypterid, and interpret them as the earliest trace fossil evidence for mass migrations of eurypterids into nearshore environments to molt and mate.[184]
Biomechanical study of the chelicerae of pterygotid eurypterids is published by Bicknell et al. (2022), who argue that pterygotid chelicerae were functionally analogous to scorpion chelae, and that Erettopterus bilobus and Pterygotus anglicus had a generalised diet and were apex predators of their ecosystems, while Acutiramus bohemicus was adapted to piercing and slicing the cuticle of other eurypterids, and Jaekelopterus rhenaniae was adapted to capturing large, highly mobile, armoured prey.[185]
New fossil material of Tuzoia with exceptionally preserved soft tissues is described from the Cambrian Burgess Shale (Canada) by Izquierdo-López & Caron (2022), who interpret this arthropod as adapted to predation or scavenging while swimming along the seafloor, and interpret it as an early member of Hymenocarina.[186]
A study on the functional morphology of Ercaicunia multinodosa, aiming to determine the posture used by this arthropod to overcome resistance and to obtain most lift while sliding in the water column, is published by Li et al. (2022).[187]
General research
Review of the paleontological, phylogenomic and molecular clock evidence pertaining to the possibly Cambrian terrestrialization of the arthropods is published Tihelka et al. (2022).[188]
^ abcdDe Francesco Magnussen, I.; Müller, S. P.; Hammel, J. U.; Kotthoff, U.; Harms, D. (2022). "Diversity of schizomids (Arachnida: Schizomida) revealed by new fossil genera and species from mid-Cretaceous Burmese amber with implications for a Gondwanan origin of the Burma Terrane". Zoological Journal of the Linnean Society. 196 (2): 792–844. doi:10.1093/zoolinnean/zlac034.
^Kolesnikov, V. B.; Turbanov, I. S.; Eskov, K. Yu.; Propistsova, E. A.; Bashkuev, A. S. (2022). "First non-amber Mesozoic pseudoscorpion from Upper Triassic deposits of eastern Europe, with a description of two new fossil subfamilies (Arachnida, Pseudoscorpiones, Feaellidae)". Papers in Palaeontology. 8 (5): e1466. doi:10.1002/spp2.1466. S2CID253137909.
^Johnson, J.; Loria, S. F.; Kotthoff, U.; Hammel, J. U.; Joseph, M. M.; Harms, D. (2022). "First record of the pseudoscorpion tribe Tyrannochthoniini Chamberlin, 1962 from mid-Cretaceous Burmese amber (Pseudoscorpiones: Chthoniidae: Chthoniinae) of northern Myanmar". Cretaceous Research. 105459. doi:10.1016/j.cretres.2022.105459. S2CID255297832.
^Lourenço, W. R.; Velten, J. (2022). "The remarkable variability of the genus Chaerilobuthus Lourenço & Beigel, 2011 ( Scorpiones: Chaerilobuthidae) and description of a new species from Early Cretaceous Burmite". Faunitaxys. 10 (10): 1–6.
^Lourenço, W. R.; Velten, J. (2022). "Further insights on Cretaceous Burmite scorpions with the descriptions of a new genus and species (Scorpiones: Buthoidea: Buthidae)". Faunitaxys. 10 (35): 1–5. doi:10.57800/faunitaxys-10(35).
^Lourenço, W. R.; Velten, J. (2022). "A second new species for the genus Cretaceoushormiops Lourenço, 2018 from Cretaceous Burmite (Scorpiones: Protoischnuridae)". Faunitaxys. 10 (43): 1–5. doi:10.57800/faunitaxys-10(43).
^Botero-Trujillo, R.; Davis, S. R.; Michalik, P.; Prendini, L. (2022). "Hirsutisoma grimaldii sp. nov., a ca. 99-million-year-old ricinuleid (Primoricinulei, Hirsutisomidae) from Cretaceous Burmese amber with a corticolous, scansorial lifestyle". Palaeoentomology. 5 (5): 493–504. doi:10.11646/palaeoentomology.5.5.11. S2CID252492618.
^García-Villafuerte, M. Á.; Carbot-Chanona, G.; Rivera-Velázquez, G.; Pineda-Diez de Bonilla, E.; Matamoros, W. A. (2022). "The first fossil record of the genus Phycosoma (Araneae, Theridiidae) from the lower Miocene Mexican amber, with the description of a new species". Journal of Paleontology. 96 (6): 1346–1353. Bibcode:2022JPal...96.1346G. doi:10.1017/jpa.2022.44. S2CID249349413.
^Martine, A. M.; Vianna Mesquita, M.; Carvalho, I.; Beloto, B.; Ricardi-Branco, F.; Garcia, M. J. (2022). "Taubaracna maculosa: First fossil spider from Paleogene in South America". Journal of South American Earth Sciences. 121. 104147. doi:10.1016/j.jsames.2022.104147. S2CID254300676.
^Ojeda, M.; Vega, F. J.; Rivas, G. (2022). "Ceratozetidae (Acari: Oribatida) from lower Miocene Mexican amber, including a new species of Trichoribates Berlese, 1910". Journal of South American Earth Sciences. 104165. doi:10.1016/j.jsames.2022.104165. S2CID254846432.
^Carvalho, M. G. P.; Maisey, J. G.; Mendes, I. D.; Carvalho, I. S. (2022). "Micro-tomographic analysis of a scorpion fossil from the Aptian Crato Formation of North-Eastern Brazil". Cretaceous Research. 147. 105454. doi:10.1016/j.cretres.2022.105454. S2CID254948977.
^Xuan, Q.; Cai, C.; Huang, D. (2022). "Immature chaerilid scorpions from mid-Cretaceous amber of northern Myanmar (Arachnida: Scorpiones: Chaeriloidea)". Cretaceous Research. 144. 105461. doi:10.1016/j.cretres.2022.105461. S2CID255359495.
^ abcdefghijklmnC. Beschin; A. Busulini; G. Tessier (2022). Decapodi associati a coralli dell'Eocene inferiore della Valle dell'Agno (Vicenza – Italia nordorientale) nelle collezioni del Museo "G. Zannato" di Montecchio Maggiore (Vicenza). pp. 1–102.
^ abSmith, C. P. A.; Charbonnier, S.; Jenks, J. F.; Bylund, K. G.; Escarguel, G.; Olivier, N.; Fara, E.; Brayard, A. (2022). "The Paris Biota decapod (Arthropoda) fauna and the diversity of Triassic decapods". Journal of Paleontology. 96 (6): 1235–1263. Bibcode:2022JPal...96.1235S. doi:10.1017/jpa.2022.34. S2CID249448157.
^Ferratges, F. A.; Zamora, S.; Aurell, M. (2022). "Systematics and paleoecology of a new species of Varunidae H. Milne Edwards, 1853 (Decapoda: Brachyura) from the lower Eocene of Spain". Journal of Crustacean Biology. 42 (2): ruac013. doi:10.1093/jcbiol/ruac013.
^Vega, F. J.; Bruce, N. L.; de Lourdes Serrano-Sánchez, M.; Coutiño, M. A. (2022). "A new genus and species of sphaeromatid (Crustacea: Isopoda) from the Lower Cretaceous (Aptian) Sierra Madre Formation, Chiapas, Mexico". Journal of South American Earth Sciences. 114: Article 103720. Bibcode:2022JSAES.11403720V. doi:10.1016/j.jsames.2022.103720. S2CID246455464.
^Santana, W.; Tavares, M.; Martins, C. A. M.; Melo, J. P. P.; Pinheiro, A. P. (2022). "A new genus and species of brachyuran crab (Crustacea, Decapoda) from the Aptian-Albian (Cretaceous) of the Araripe Sedimentary Basin, Brazil". Journal of South American Earth Sciences. 116: Article 103848. Bibcode:2022JSAES.11603848S. doi:10.1016/j.jsames.2022.103848. S2CID249005503.
^ abFraaije, R. H. B.; Klompmaker, A. A.; Jagt, J. W. M.; Krobicki, M.; van Bakel, B. W. M. (2022). "A new, highly diverse paguroid assemblage from the Oxfordian (Upper Jurassic) of southern Poland and its environmental distribution". Neues Jahrbuch für Geologie und Paläontologie - Abhandlungen. 304 (1): 1–12. doi:10.1127/njgpa/2022/1054. S2CID248600120.
^ abcGarassino, A.; Pasini, G.; Pizzolato, F. (2022). "A review of some leucosiid crabs from the lower Pleistocene beds of Poggi Gialli (Tuscany, central Italy)". Neues Jahrbuch für Geologie und Paläontologie - Abhandlungen. 304 (3): 263–273. doi:10.1127/njgpa/2022/1070. S2CID250010128.
^ abDe Angeli, A.; Bellin, B. (2022). "Nuovi crostacei brachiuri dell'Eocene di cava "Main" di Arzignano (Vicenza, Italia nordorientale)". Lavori – Società Veneziana di Scienze Naturali. 47: 93–101.
^Khosravi, E.; Sari, A.; Mirziee-Ataabadi, M.; Gholamalian, H.; Hyžný, M.; Naderloo, R. (2022). "A new species of Galene de Haan, 1833 (Galenidae: Brachyura) from the middle Miocene of Zagros Mountains, Iran". Zootaxa. 5124 (2): 139–154. doi:10.11646/zootaxa.5124.2.2. PMID35391131. S2CID247918640.
^ abDe Angeli, A.; Caporiondo, F. (2022). "Gli Hexapodidae (Crustacea, Decapoda) dell'Eocene del Veneto (Italia nordorientale), con la descrizione di un nuovo genere e due nuove specie". Lavori – Società Veneziana di Scienze Naturali. 47: 107–115.
^ abSchweitzer, C. E.; Feldmann, R. M.; Casadío, S. (2022). "Revision of Decapoda (Glypheidea, Axiidea) from the Upper Jurassic-Lower Cretaceous of Argentina". Annals of Carnegie Museum. 87 (4): 291–307. doi:10.2992/007.087.0402. S2CID255547049.
^Pasini, G.; Garassino, A.; Stockar, R.; Magnani, F. (2022). "Penaeidean and caridean shrimps (Crustacea, Decapoda) from the Upper Meride Limestone (Middle Triassic) of Monte San Giorgio (TI, Switzerland)". Neues Jahrbuch für Geologie und Paläontologie - Abhandlungen. 303 (3): 339–353. doi:10.1127/njgpa/2022/1053. S2CID248042413.
^Pasini, G.; Garassino, A.; Pizzolato, F. (2022). "Report of a palicid crab (Brachyura, Palicidae) from the lower Pleistocene beds of Poggi Gialli (Tuscany, central Italy)". Neues Jahrbuch für Geologie und Paläontologie - Abhandlungen. 304 (3): 239–243. doi:10.1127/njgpa/2022/1067. S2CID249999218.
^S. Charbonnier; A. Garassino, eds. (2022). Fossil Decapod Crustacea in the historical collections. Mémoires du Muséum National d'Histoire Naturelle. Vol. 216. pp. 1–292. ISBN978-2-85653-974-3.
^Vega, F. J.; Garassino, A. (2022). "A new genus of crab (Crustacea: Brachyura: Cyclodorippidae) from the lower Maastrichtian of NE Mexico". Neues Jahrbuch für Geologie und Paläontologie - Abhandlungen. 305 (2): 131–143. doi:10.1127/njgpa/2022/1081. S2CID252131551.
^Beschin, C.; De Angeli, A. (2022). "Stimdromia conternoi n. sp., (Decapoda, Brachyura, Dromiidae) dell'Eocene di Nanto (Monti Berici, Vicenza, Italia nordorientale)". Studi e Ricerche - Associazione Amici del Museo - Museo Civico "G. Zannato" Montecchio Maggiore (Vicenza). 29: 5–8.
^Audo, D.; Charbonnier, S. (2022). "Teruzzicheles popeyei, an early Sinemurian polychelid lobster from the Osteno Lagerstätte (Italy)". Neues Jahrbuch für Geologie und Paläontologie - Abhandlungen. 306 (3): 187–194. doi:10.1127/njgpa/2022/1103. S2CID254820598.
^Garassino, A.; Pasini, G.; Nazarkin, M. V. (2022). "A new caridean shrimp (Crustacea, Decapoda) from the middle–late Miocene of Sakhalin Island, Russia". Neues Jahrbuch für Geologie und Paläontologie - Abhandlungen. 303 (1): 1–9. doi:10.1127/njgpa/2022/1031. S2CID246449498.
^Jones, A. R.; Schweitzer, C. E.; Feldmann, R. M. (2022). "Sexual dimorphism and rare intersex individuals in Cretaceous (Maastrichtian) Dakoticancer Rathbun, 1917 (Decapoda: Brachyura: Dakoticancroida)". Journal of Crustacean Biology. 42 (1): ruac010. doi:10.1093/jcbiol/ruac010.
^Feldmann, R. M.; Schweitzer, C. E. (2022). "Unique occurrence of the Miocene Trichopeltarion greggi Dell, 1969 (Decapoda: Brachyura: Trichopeltariidae): potential documentation of maternal care". Journal of Crustacean Biology. 42 (1): ruab080. doi:10.1093/jcbiol/ruab080.
^ abcdefPuckett, T. M.; Hunt, G. (2022). "New Taxa of Marine Ostracods (Anticytherideinae, n. subfam.) from the Upper Cretaceous (Campanian and Maastrichtian) of Mississippi, Alabama and Tennessee, U. S. Gulf Coastal Plain". Micropaleontology. 68 (5): 433–504. Bibcode:2022MiPal..68..433P. doi:10.47894/mpal.68.5.01. S2CID252058741.
^Song, J.; Guo, W.; Sun, Y.; Ma, J.; Huang, J.; Zhang, Y.; Qie, W. (2022). "First record of the latest Devonian ostracods from the Xainza region, Tibet, China: implications on palaeoenvironment and palaeobiogeography". Palaeoworld. in press. doi:10.1016/j.palwor.2022.01.002. S2CID245994353.
^ abcdefMcDonald, A. P.; Warne, M. T. (2022). "Latest Miocene ostracods from the Bookpurnong Formation in the Murray Basin of southeastern Australia: shallow marine migrants into an epicontinental sea". Alcheringa: An Australasian Journal of Palaeontology. 46 (3–4): 301–339. Bibcode:2022Alch...46..301M. doi:10.1080/03115518.2022.2133169. S2CID253934707.
^ abcSousa, F. S. D. E.; Ramos, M. I. F. (2022). "Taxonomic study of the genus Cyprideis JONES, 1857 from the Pebas Formation (Miocene), Iquitos (Peru), with description of three new species". Journal of South American Earth Sciences. 123. 104126. doi:10.1016/j.jsames.2022.104126. S2CID254090098.
^ abPiovesan, E. K.; Melo, G. D.; Cabral, M. C.; Guzmán, J. (2022). "New Early Cretaceous species of Zonocypris G. W. Müller, 1898 (Crustacea: Ostracoda) from the Crato Formation, Brazil". Zootaxa. 5141 (6): 581–591. doi:10.11646/zootaxa.5141.6.4. PMID36095772. S2CID249221037.
^Karasawa, H.; Amano, K. (2022). "New records for pedunculate barnacles (Cirripedia: Thoracica) from the Miocene Higashibessho Formation in Toyama Prefecture, central Japan". Bulletin of the Mizunami Fossil Museum. 49: 123–127. doi:10.50897/bmfm.49.0_123.
^Van Houte, E.; Hegna, T. A.; Butler, A. D. (2022). "A new genus and species of ?parthenogenic anostracan (Pancrustacea, Branchiopoda, ?Thamnocephalidae) from the Lower Cretaceous Koonwarra Fossil Bed in Australia". Alcheringa: An Australasian Journal of Palaeontology. 46 (2): 180–187. Bibcode:2022Alch...46..180V. doi:10.1080/03115518.2022.2048267. S2CID247807263.
^Teng, X.; Li, G.; Zhang, Y.-Z. (2022). "Linglongtaestheria (Spinicaudata) from the Upper Jurassic of Qinglong, Hebei Province, northeastern China". Palaeoworld. doi:10.1016/j.palwor.2022.11.008. S2CID254449513.
^Mychko, E. V.; Alekseev, A. S.; Zaytseva, E. L.; Schweitzer, C. E.; Feldmann, R. M. (2022). "New finding of Cyclida (Crustacea) from Mississippian and not‑cyclidan from Permian of Russia". Neues Jahrbuch für Geologie und Paläontologie - Abhandlungen. 305 (1): 75–85. doi:10.1127/njgpa/2022/1077. S2CID250706723.
^Perreault, R. T.; Collareta, A.; Buckeridge, J. S. (2022). "A new species of the archaic "turtle barnacle" genus Protochelonibia (Coronuloidea, Chelonibiidae) from the upper Rupelian Chickasawhay Formation of Mississippi (U.S.A.)". Neues Jahrbuch für Geologie und Paläontologie - Abhandlungen. 305 (3): 225–235. doi:10.1127/njgpa/2022/1087. S2CID252744143.
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