2018 in paleobotany: Difference between revisions

List of years in paleobotany
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In paleontology 2015 2016 2017 2018 2019 2020 2021
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This article records new taxa of plants that are scheduled to be described during the year 2018, as well as other significant discoveries and events related to paleobotany that are scheduled to occur in the year 2018.

Research

• A study attempting to establish a timescale of early land plant evolution is published by Morris et al. (2018).^[1]
• Assemblage of putative Ordovician (Hirnantian) land plants is described from the Zbrza locality in the southern Świętokrzyskie Mountains (Poland) by Salamon et al. (2018).^[2]
• A study on the phylogenetic relationships of the Cretaceous mosses Meantoinea alophosioides and Eopolytrichum antiquum within Polytrichaceae is published by Bippus, Escapa & Tomescu (2018).^[3]
• Meristems of rooting axes belonging to Asteroxylon mackiei are described from the Rhynie chert (United Kingdom) by Hetherington & Dolan (2018).^[4]
• A study re-examining the evidence on the speed of growth and life cycle of the tree-like lycophytes from the Carboniferous (Pennsylvanian) coal swamps, and in particular addressing an earlier study by Boyce & DiMichele (2016),^[5] is published by Thomas & Cleal (2018).^[6][7]
• A study on the impact of increased ultraviolet irradation (caused by volcanism-induced ozone shield deterioration) on plants during the Permian–Triassic extinction event is published by Benca, Duijnstee & Looy (2018).^[8]
• A study on the composition of the Late Triassic flora of the American Southwest, based on palynological data from the Chinle Formation, and indicative of a floral turnover occurring in the middle Norian, is published by Baranyi et al. (2018).^[9]
• A study on the Middle Jurassic flora from Yorkshire (United Kingdom) as indicated by pollen and spores, and on the possible dinosaur-plant interactions in the area is published by Slater et al. (2018).^[10]
• Occurrence of the characean genus Tolypella is reported from the Lower Cretaceous of the Garraf Massif (Catalonia, Spain) by Martín-Closas et al. (2018), representing the oldest known record of the genus reported so far.^[11]
• A study on the spore wall structure and development in Psilophyton dawsonii is published by Noetinger, Strayer & Tomescu (2018).^[12]
• Lycopsid megaspores preserved with fossil starch, probably used to attract and reward animals for megaspore dispersal, are described from the Permian of north China by Liu et al. (2018).^[13]
• A study on the phylogenetic relationships of extant and fossil members of Equisetales is published by Elgorriaga et al. (2018).^[14]
• A study on the anatomy of the Devonian fern-like plant Shougangia bella is published by Wang et al. (2018).^[15]
• A study on the phylogenetic relationships of a putative Triassic fern Pekinopteris, based on evaluation of specimens preserving fertile pinnae, is published by Axsmith, Skog & Pott (2018).^[16]
• A study on the anatomical structure of Coniopteris hymenophylloides (a fossil fern belonging to the family Dicksoniaceae) based on well-preserved materials from the Middle Jurassic Yaojie Formation (China), including sterile and fertile pinnae, sporangia and in situ spores, epidermal cuticles and stomatal complexes, is published by Xin et al. (2018).^[17]
• A study on the phylogenetic relationships of extant and fossil marattialean ferns is published by Rothwell, Millay & Stockey (2018).^[18]
• A study on the phylogenetic relationships of members of Dipteridaceae based on data from extant and fossil taxa is published by Choo & Escapa (2018).^[19]
• Fossil occurrences of members of the genus Christella are reported from the late Paleocene of Liuqu, southern Tibet and middle Miocene of the Jinggu Basin in western Yunnan (China) by Xu et al. (2018).^[20]
• A study on the phylogenetic relationships of early seed plants, aneurophytalean progymnosperms, Stenokoleales and several Devonian plants of uncertain affinities is published by Toledo, Bippus & Tomescu (2018).^[21]
• Plant fossils representing the genera Glossopteris, Vertebraria, Samaropsis, Paracalamites, Sphenophyllum and Dichotomopteris are described from the Permian strata in the Tabbowa Basin of Sri Lanka by Edirisooriya, Dharmagunawardhane & McLoughlin (2018), thus being the first representatives of the distinctive Permian Glossopteris flora reported from that country.^[22]
• A study on the diversity trends of Glossopteris flora from the Barakar, Raniganj, and Panchet formations of Tatapani–Ramkola Coalfield (India) will be published by Saxena et al. (2018).^[23]
• Fossils of member of the genus Glossopteris related to the species Glossopteris communis from India are described from the Permian deposits of southeastern Gobi (Mongolia) by Naugolnykh & Uranbileg (2018).^[24]
• A study on the fossils of Glossopteris from the Permian succession of eastern India, aiming to identify the molecular signatures of solvent-extractable and non-extractable organic matter, is published by Tewari et al. (2018).^[25]
• A study on the fossils of glossopterids from the Permian (Lopingian) Buckley Formation (Antarctica) will be published by DeWitt et al. (2018), who present evidence of glossopterids shedding their pollen organs during a different time of the season than Glossopteris leaves.^[26]
• Seed of the ginkgoalean Yimaia capituliformis with damage interpreted as likely oviposition lesions inflicted by a kalligrammatid lacewing will be described from the Middle Jurassic Jiulongshan Formation (China) by Meng et al. (2018).^[27]
• A study on the phylogeny of conifers, comparing the inferred phylogenetic relationships and estimated divergence ages with the paleobotanical record, will be published by Leslie et al. (2018).^[28]
• A study on the atmospheric carbon dioxide concentration levels in the Early Cretaceous based on data from specimens of the fossil conifer species Pseudofrenelopsis papillosa is published by Jing & Bainian (2018).^[29]
• A study on the phytogeographic history of ten conifer genera that are endemic to East Asia, based on fossil data from humid temperate forests in the Japanese Islands and Korean Peninsula, will be published by Yabe et al. (2018).^[30]
• A study on the phylogenetic relationships of members of Pinaceae based on data from extant and fossil taxa is published by Gernandt et al. (2018).^[31]
• A study on the epidermis of the leaves of the fossil pine Pinus mikii and on the phylogenetic relationships of the species is published by Yamada & Yamada (2018).^[32]
• A study on the anatomy and phylogenetic relationships of Austrohamia acanthobractea, based on data from leafy twigs with attached pollen cones and seed cones from the Middle Jurassic Daohugou Lagerstätte (China), is published by Dong et al. (2018).^[33]
• Five fossil foliage specimens of Calocedrus lantenoisi, representing one of the earliest records of the genus Calocedrus worldwide, are described from the Oligocene Shangcun Formation of the Maoming Basin (Guangdong Province, South China) by Wu et al. (2018).^[34]
• A study on the phylogenetic relationships of the vascular plants and the timescale of their evolution, attempting to establish when the flowering plants originated, is published by Barba-Montoya et al. (2018).^[35]
• A study on the phylogenetic relationships of extant and fossil members of Zingiberales is published by Smith et al. (2018).^[36]
• A study on the phylogenetic relationships of Cornales based on data from extant and fossil taxa is published by Atkinson (2018).^[37]
• Fossil fruits of members of the genera Fragaria and Rubus are reported from the Pliocene otrcrops in the Heqing Basin (China) by Huang et al. (2018).^[38]
• A study on the phylogenetic relationships of the flowering plants and Gnetales, as indicated by morphological data from extant and fossil taxa, is published by Coiro, Chomicki & Doyle (2018).^[39]
• Revision of the taxonomy of the Cretaceous monocot genus Viracarpon is published by Matsunaga et al. (2018), who transfer the species Coahuilocarpon phytolaccoides known from the Campanian Cerro del Pueblo Formation (Mexico) to the genus Viracarpon, thus rejecting the hypothesis that Viracarpon was endemic to India.^[40]
• Microfossil remains of early grasses extracted from a specimen of the Early Cretaceous dinosaur species Equijubus normani from China will be described by Wu, You & Li (2018).^[41]
• Cantisolanum daturoides from the Eocene London Clay Formation, previously suggested to be a member of the family Solanaceae, is reinterpreted as more likely to be a commelinid monocot by Särkinen et al. (2018).^[42]
• A study on the lower threshold of extant palm temperature tolerance, as well as on the potential of using the presence of palm fossils to infer past climate, is published by Reichgelt, West & Greenwood (2018).^[43]
• A study on fossil pollen of members of the group Ericales from five Eocene localities in the United Kingdom, Austria, Germany and China, aiming to describe fossil pollen types and compare them with the most similar looking pollen of modern species, is published by Hofmann (2018).^[44]
• A new fossil Loranthaceae pollen type (the first representative of this family in the fossil record of Africa) is described from the earliest Miocene of Saldanha Bay (South Africa) by Grímsson et al. (2018).^[45]
• A study on the macroevolutionary dynamics of extinction and adaptation of palms with megafaunal fruits in the late Cenozoic is published by Onstein et al. (2018), who interpret their findings as indicating that progressive loss of megafaunal frugivores during the late Cenozoic likely resulted in increased extinction rates of palms with megafaunal fruits.^[46]
• A study on factors which influenced the diversification processes and diversity dynamics of Cenozoic woody flowering plants is published by Shiono et al. (2018).^[47]
• Description of plant remains and palynomorphs preserved in the coprolites produced by large dicynodonts from the Triassic Chañares Formation (Argentina), and a study on the affinities of the plants preserved in those coprolites, is published by Perez Loinaze et al. (2018).^[48]
• A study on the nutritional value of plants grown under elevated CO₂ levels, evaluating the hypothesis that constraints on sauropod diet quality were driven by Mesozoic CO₂ concentration, is published by Gill et al. (2018).^[49]
• A study on the diversity, frequency and representation of insect damage of fossil plant specimens from the Permian La Golondrina Formation (Argentina) is published by Cariglino (2018).^[50]
• A study on the insect herbivory on fossil ginkgoalean and bennettitalean leaves from the Middle Jurassic Daohugou Beds (China), and on defenses of these plants against insect herbivory, is published by Na et al. (2018).^[51]
• A study on the plant specimens (ferns, gymnosperms and angiosperms) from the Lower Cretaceous Araripe Basin (Brazil) preserving evidence of plant–insect interactions and potentially of paleoecological relationships between plants and insects will be published by Edilson Bezerra dos Santos Filho et al. (2018).^[52]
• Diverse gymnosperm and angiosperm fossils, displaying affinities with the flora of the Araripe Basin (Santana Formation) as well as those identified in deposits from the North America (Potomac Group), are described from the Lower Cretaceous Codó Formation (Brazil) by Lindoso et al. (2018).^[53]
• Insect and plant inclusions are reported from amber from the uppermost Campanian Kabaw Formation of Tilin (Myanmar) by Zheng et al. (2018).^[54]
• Organically preserved plant fossils, including leaves with cuticular preservation, are described from the Paleogene Ligorio Márquez Formation (Argentina) by Carpenter, Iglesias & Wilf (2018).^[55]
• A study on changes in Eocene plant diversity and floristic composition at Messel (Germany) will be published by Lenz & Wilde (2018).^[56]
• Su et al. (2018) use radiometrically dated plant fossil assemblages to quantify when southeastern Tibet achieved its present elevation, and what kind of floras existed there at that time.^[57]
• A study on the dynamics and evolution of the flora of Turgai ecological type in Western Siberia during the early Oligocene to earliest Miocene will be published by Popova et al. (2018).^[58]
• A study evaluating when the plants using the C₄ photosynthetic pathway initially expanded on the Australian continent, as indicated by carbon isotope ratios of plant waxes from scientific ocean drilling sediments off north‐western Australia, is published by Andrae et al. (2018).^[59]
• A study on changes of C₄ vegetation composition in southwestern Montana (United States) from the late Miocene through present will be published by Hyland et al. (2018).^[60]
• A study on the abundance of the C₃ and C₄ grasses in the central interior of southern Africa in the Early Pleistocene, as indicated by enamel stable carbon and oxygen isotope data, associated faunal abundance and phytolith evidence from the site of Wonderwerk Cave (South Africa), is published by Ecker et al. (2018).^[61]
• A study on the changes of vegetation in the temperate zone of Asia during an interval containing the Mid-Pleistocene Transition, ~1.2–0.7 million years ago, as indicated by pollen data from a drilling core from the North China Plain, as well as on their effect on the large mammal fauna is published by Xinying et al. (2018).^[62]
• A study on the use of plants by early modern humans during the Middle Stone Age as indicated by analyses of phytoliths from the Pinnacle Point locality (South Africa) is published by Esteban et al. (2018).^[63]
• A study on the distance of seed dispersal by extant and extinct mammalian frugivores and on the impact of the extinction of Pleistocene megafauna on seed dispersal is published by Pires et al. (2018).^[64]
• A study evaluating how mega‐herbivore animal species controlled plant community composition and nutrient cycling, relative to other factors during and after the Late Quaternary extinction event in Great Britain and Ireland, is published by Jeffers et al. (2018).^[65]
• A study on the seeds preserved in moa coprolites is published by Carpenter et al. (2018), who question the hypothesis that some of the largest-seeded plants of New Zealand were dispersed by moas.^[66]
• A study on the plant–insect interactions in the European forest plant communities in the Upper Pliocene Lagerstätte of Willershausen (Lower Saxony, Germany), the Upper Pliocene locality of Berga (Thuringia, Germany) and the Pleistocene locality of Bernasso (France) is published by Adroit et al. (2018).^[67]
• A study on the inner structure of cuticles and carbonaceous compressions of Early Jurassic plants from Argentinian Patagonia, using Focused Ion Beam Scanning Electron Microscopy, is published by Sender et al. (2018).^[68]
• Evidence of plant domestication and food production from the early and middle Holocene site of Teotonio (southwestern Amazonia, Brazil) is presented by Watling et al. (2018).^[69]

Flowering plants

Name	Novelty	Status	Authors	Age	Unit	Location	Notes	Images
Alloberberis axelrodii[70]	Sp. nov	Valid	Doweld	Miocene		United States ( Nevada)	A member of the family Berberidaceae; a replacement name for the previously invalidly published Mahonia sinuata Axelrod (1985), lacking holotype designation when published.
Alloberberis caeruleomontana[70]	Nom. nov	Valid	Doweld	Miocene		United States ( Oregon)	A member of the family Berberidaceae; a replacement name for Ilex sinuata Chaney & Axelrod (1959).
Anacolosidites eosenonicus[71]	Sp. nov	Valid	Arai & Dias-Brito	Late Cretaceous (Santonian)	São Carlos Formation	Brazil	A pollen taxon, possibly a member of the family Loranthaceae.
Araliaephyllum popovii[72]	Sp. nov	Valid	Golovneva	Early Cretaceous (Albian)		Russia	A member of Laurales described on the basis of fossil leaves.
Archeampelos betulifolia[73]	Sp. nov	Valid	Moiseeva, Kodrul & Herman	Paleocene	Zeya–Bureya Basin	Russia	A flowering plant described on the basis of fossil leaves, similar to leaves of members of the family Betulaceae.
Austrovideira[74]	Gen. et sp. nov	Valid	Rozefelds & Pace	Early Oligocene		Australia	A member of Vitaceae. Genus includes new species A. dettmannae.
Berberis miopannonica[70]	Nom. nov	Valid	Doweld	Miocene		Romania	A species of Berberis; a replacement name for Berberis lanceolata Givulescu (1985).
Berberis notata[70]	Nom. nov	Valid	Doweld	Miocene		Austria	A species of Berberis; a replacement name for Ilex ambigua Unger (1847) and Berberis ambigua Kovar-Eder & Kvaček (2004).
Berryoxylon[75]	Gen. et sp. nov	Valid	Awasthi, Mehrotra & Shukla	Late Miocene–early Pliocene	Cuddalore Sandstone Formation	India	A fossil wood showing affinities with members of the genus Berrya. Genus includes new species B. cuddalorensis.
Bignonioxylon[76]	Gen. et sp. nov	Valid	Moya & Brea	Late Pleistocene	Arroyo Feliciano Formation	Argentina	A member of Bignoniaceae described on the basis of fossil wood. Genus includes new species B. americanum.
Burretiodendron guangxiensis[77]	Sp. nov	In press	Dong & Sun in Dong et al.	Oligocene	Ningming Formation	China	A species of Burretiodendron.
Buxus pliosinica[78]	Sp. nov	Valid	Huang, Su & Zhou	Late Pliocene	Sanying Formation	China	A species of Buxus.
Calophyllum zhangpuensis[79]	Sp. nov	In press	Wang et al.	Miocene	Fotan Group	China	A species of Calophyllum.
Canarium guangxiensis[80]	Sp. nov	Valid	Han & Manchester in Han et al.	Late Oligocene to late Miocene	Erzitang Formation Foluo Formation Yongning Formation	China	A species of Canarium
Carlquistoxylon australe[81]	Sp. nov	In press	Pujana et al.	Early Cretaceous (late Albian)	Cerro Barcino Formation	Argentina	A flowering plant of uncertain phylogenetic placement, described on the basis of fossil wood.
Castanopsis guangxiensis[82]	Sp. nov	Valid	Huang et al.	Late Oligocene	Yongning Formation	China	A species of Castanopsis.
Castanopsis nanningensis[82]	Sp. nov	Valid	Huang et al.	Late Oligocene	Yongning Formation	China	A species of Castanopsis.
Cedrelospermum tibeticum[83]	Sp. nov	In press	Jia, Su & Zhou in Jia et al.	Late Oligocene	Dingqing Formation	China	A member of Ulmaceae.
Chisochetonoxylon vastanensis[84]	Sp. nov	Valid	Shukla & Mehrota	Early Eocene	Cambay Shale Formation	India	A member of the family Meliaceae described on the basis of fossil wood.
Cichoreacidites? igapoensis[85]	Sp. nov	In press	D'Apolito et al.	Pliocene–Pleistocene		Brazil	Fossil pollen of a member of the genus Pacourina or Vernonia.
Cladium transdnestrovicum[86]	Nom. nov	Valid	Doweld	Miocene (Serravallian)		Transnistria	A species of Cladium; a replacement name for Cladium crassum Negru (1972), preoccupied by extant C. crassum (Thwaites) Kükenthal.
Cobbania pharao[87]	Sp. nov	In press	Coiffard & Mohr	Late Cretaceous (Campanian)	Quseir Formation	Egypt	A member of the family Araceae belonging or related to the subfamily Aroideae.
Concavistylon[88]	Gen. et sp. nov	Valid	Manchester, Pigg & Devore	Middle Miocene	Little Butte Volcanic Series	United States ( Oregon)	A member of the family Trochodendraceae. Genus includes new species C. kvacekii.
Craspedodromophyllum boguchanicum[73]	Sp. nov	Valid	Moiseeva, Kodrul & Herman	Paleocene	Zeya–Bureya Basin	Russia	A member of the family Betulaceae.
Cretaceoxylon[89]	Gen. et sp. nov	Valid	Pujana in Pujana et al.	Late Cretaceous (Campanian)	Santa Marta Formation	Antarctica (James Ross Island)	An eudicot of uncertain phylogenetic placement, described on the basis of fossil wood. Genus includes new species C. heteropunctatum.
Cryptocaryoxylon lemnium[90]	Sp. nov	Valid	Mantzouka	Early Miocene		Greece	A member of the family Lauraceae.
Cryptocaryoxylon lesbium[90]	Sp. nov	Valid	Mantzouka	Early Miocene		Greece	A member of the family Lauraceae.
Cussoniophyllum[91]	Nom. nov	Valid	Doweld	Late Cretaceous (Cenomanian)		Czech Republic	A flowering plant described on the basis of fossil leaves; a replacement name for the invalidly published Cussoniphyllum Velenovský (1889). Genus includes "Cussonia" partita Velenovský (1882).
Cyperus maii[86]	Nom. nov	Valid	Doweld	Miocene		Germany	A species of Cyperus; a replacement name for Dichostylis macrocarpa Mai (1987).
Cyperus waltheri[86]	Nom. nov	Valid	Doweld	Miocene		Germany	A species of Cyperus; a replacement name for Dichostylis minor Mai in Mai & Walther (1991).
Dakotanthus[92]	Gen. et comb. nov	Valid	Manchester et al.	Cretaceous (late Albian to Cenomanian)	Dakota Formation Woodbine Formation	United States ( Kansas  Nebraska  Texas)	An early eudicot; a new genus for "Carpites" cordiformis Lesquereux (1892).
Dalbergioxylon biseriatensis[93]	Sp. nov	In press	Cheng et al.	Pliocene	Yuanmou Basin	China	A member of the family Fabaceae described on the basis of fossil wood.
Dioscorites palauensis[94]	Sp. nov	Valid	Guzmán-Vázquez, Calvillo-Canadell & Sánchez-Beristain	Late Cretaceous	Olmos Formation	Mexico	A member of the family Dioscoreaceae.
Diplosophyllum[91]	Nom. nov	Valid	Doweld	Late Cretaceous (Cenomanian)		Czech Republic  Germany	A flowering plant described on the basis of fossil leaves; a replacement name for the preoccupied Diplophyllum Velenovský & Viniklář (1929). Genus includes "Inga" cottae Ettingshausen (1867), "Diplophyllum" cretaceum Velenovský & Viniklář (1929), "Hymenaea" elongata Velenovský (1884), "Hymenaea" inaequalis Velenovský (1884) and "Hymenaea" primigenia de Saporta in Velenovský (1884).
Dipterocarpuspollenites cretacea[95]	Sp. nov	Valid	Prasad et al.	Late Cretaceous (Maastrichtian)		India	A pollen taxon belonging to the family Dipterocarpaceae.
Donlesia cheyennensis[96]	Sp. nov	Valid	Wang & Dilcher	Early Cretaceous (Albian)	Cheyenne Sandstone	United States ( Kansas)	A member of the family Ceratophyllaceae.
Ebenoxylon cuddalorensis[75]	Sp. nov	Valid	Awasthi, Mehrotra & Shukla	Late Miocene–early Pliocene	Cuddalore Sandstone Formation	India	A fossil wood showing affinities with members of the family Ebenaceae.
Edencarpa[97]	Gen. et sp. nov	Valid	Atkinson, Stockey & Rothwell	Late Cretaceous (early Coniacian)		Canada ( British Columbia)	A member of Cornales. Genus includes new species E. grandis.
Elioxylon[98]	Gen. nov	In press	Srivastava, Miller & Baas	Late Cretaceous (Maastrichtian)–Paleocene (Danian)	Deccan Intertrappean Beds	India	A fossil wood sharing features with extant genera of Achariaceae and Salicaceae.
Endobeuthos[99]	Gen. et sp. nov	Valid	Poinar & Chambers	Late Cretaceous (Cenomanian)	Burmese amber	Myanmar	A flowering plant of uncertain phylogenetic placement, possibly a relative of members of the family Dilleniaceae. Genus includes new species E. paleosum.
Eucalyptoxylon cuddalorensis[75]	Sp. nov	Valid	Awasthi, Mehrotra & Shukla	Late Miocene–early Pliocene	Cuddalore Sandstone Formation	India	A fossil wood showing affinities with members of the genus Eucalyptus.
Eydeia vancouverensis[97]	Sp. nov	Valid	Atkinson, Stockey & Rothwell	Late Cretaceous (early Coniacian)		Canada ( British Columbia)	A member of Cornales.
Ficus microtrivia[100]	Sp. nov	Valid	Huang & Zhou in Huang et al.	Miocene	Wenshan Basin	China	A species of Ficus.
Garcinia zhangpuensis[101]	Sp. nov	In press	Wang et al.	Middle Miocene	Fotan Group	China	A species of Garcinia.
Gardenia eocenicus[102]	Sp. nov	In press	Shukla, Mehrotra & Nawaz Ali	Early Eocene	Palana Formation	India	A species of Gardenia.
Gastonispermum[103]	Gen. et sp. nov	Valid	Friis, Crane & Pedersen	Early Cretaceous		Portugal	A flowering plant with affinities to Austrobaileyales or Nymphaeales. Genus includes new species G. portugallicum.
Gleditsioxylon jiangsuensis[104]	Sp. nov	Valid	Cheng et al.	Early Miocene		China	A member of Leguminosae described on the basis of fossil wood.
Gouania miocenica[105]	Sp. nov	Valid	Hernandez-Hernández & Castañeda-Posadas	Early Miocene	Mexican amber	Mexico	A species of Gouania.
Hederago[91]	Nom. nov	Valid	Doweld	Late Cretaceous (Cenomanian)		Czech Republic	A flowering plant described on the basis of fossil leaves; a replacement name for the invalidly published Hederophyllum Velenovský (1889). Genus includes "Hedera" credneriifolia Velenovský (1882) and "Hedera" primordialis de Saporta (1879).
Hemitrapa alpina[106]	Sp. nov	Valid	Su & Zhou in Su et al.	Early Oligocene		China	A member of the family Lythraceae.
Holigarna palaeograhamii[102]	Sp. nov	In press	Shukla, Mehrotra & Nawaz Ali	Early Eocene	Palana Formation	India	A species of Holigarna.
Hopenium tertiarum[75]	Sp. nov	Valid	Awasthi, Mehrotra & Shukla	Late Miocene–early Pliocene	Cuddalore Sandstone Formation	India	A fossil wood showing affinities with members of the genus Hopea.
Ipomoea meghalayensis[107]	Sp. nov	Valid	Srivastava, Mehrotra & Dilcher	Paleocene (Thanetian)		India	A species of Ipomoea.
Kirchheimeria[108]	Gen. et comb. nov	Valid	Kowalski in Kowalski & Worobiec	Oligocene to Pliocene		Denmark  Germany  Poland  Russia ( Kaliningrad Oblast)	A member of Ericaceae of uncertain phylogenetic placement. Genus includes "Elaeocarpus" globulus Menzel (1906).
Koelreuteria lunpolaensis[109]	Sp. nov	In press	Jiang et al.	Late Oligocene	Lunpola Basin	China	A species of Koelreuteria.
Kvacekispermum[110]	Gen. et sp. nov	Valid	Friis, Crane & Pedersen	Early Cretaceous	Figueira da Foz Formation	Portugal	A member of the family Chloranthaceae. Genus includes new species K. rugosum.
Lacinipetalum[111]	Gen. et sp. nov	Valid	Jud et al.	Paleocene (early Danian)	Upper Salamanca Formation	Argentina	A member of Cunoniaceae. Genus includes new species L. spectabilum.
Ladakhipollenites? densicolumellatus[85]	Sp. nov	In press	D'Apolito et al.	Pliocene–Pleistocene		Brazil	Fossil pollen of a flowering plant.
Ladakhipollenites? lolongatus[85]	Sp. nov	In press	D'Apolito et al.	Pliocene–Pleistocene		Brazil	Fossil pollen of Symmeria paniculata.
Ladakhipollenites? porolenticularis[85]	Sp. nov	In press	D'Apolito et al.	Pliocene–Pleistocene		Brazil	Fossil pollen of a flowering plant (possibly a member of the family Marcgraviaceae).
Laurinoxylon rennerae[112]	Sp. nov	Valid	Estrada-Ruiz et al.	Late Cretaceous (late Campanian)	McRae Formation	United States ( New Mexico)	A member of Lauraceae described on the basis of fossil wood.
Laurophyllum alseodaphnoides[113]	Sp. nov	In press	Wang & Sun in Wang et al.	Miocene (Langhian)	Fotan Group	China	A member of Lauraceae described on the basis of fossil leaves.
Laurophyllum fotanensis[113]	Sp. nov	In press	Wang & Sun in Wang et al.	Miocene (Langhian)	Fotan Group	China	A member of Lauraceae described on the basis of fossil leaves.
Laurophyllum lindaiensis[113]	Sp. nov	In press	Wang & Sun in Wang et al.	Miocene (Langhian)	Fotan Group	China	A member of Lauraceae described on the basis of fossil leaves.
Laurophyllum triangulatum[113]	Sp. nov	In press	Wang & Sun in Wang et al.	Miocene (Langhian)	Fotan Group	China	A member of Lauraceae described on the basis of fossil leaves.
Laurophyllum zhangpuensis[113]	Sp. nov	In press	Wang & Sun in Wang et al.	Miocene (Langhian)	Fotan Group	China	A member of Lauraceae described on the basis of fossil leaves.
Lefipania[114]	Gen. et sp. nov	Valid	Martínez, Gandolfo & Cúneo	Late Cretaceous (Maastrichtian)	Lefipán Formation	Argentina	A flowering plant of uncertain phylogenetic placement, described on the basis of fossil leaves. Genus includes new species L. padillae.
Leguminocarpum oguruiensis[115]	Sp. nov	Valid	Yabe & Nakagawa	Miocene	Shimo Formation	Japan	A fossil legume fruit.
Limnobiophyllum stockeyana[87]	Sp. nov	In press	Coiffard & Mohr	Late Cretaceous (Campanian)	Quseir Formation	Egypt	A member of the family Araceae belonging to the subfamily Lemnoideae.
Liquidambar fujianensis[116]	Sp. nov	Valid	Dong et al.	Middle Miocene	Fotan Group	China	A species of Liquidambar.
Lithocarpoxylon microporosum[93]	Sp. nov	In press	Cheng et al.	Pliocene	Yuanmou Basin	China	A member of the family Fagaceae described on the basis of fossil wood.
Lithocarpoxylon nanningensis[82]	Sp. nov	Valid	Huang et al.	Late Oligocene	Yongning Formation	China	A member of Fagaceae described on the basis of fossil wood.
Litseoxylon[117]	Gen. et sp. nov	In press	Huang et al.	Late Oligocene	Yongning Formation	China	A member of the family Lauraceae. Genus includes new species L. nanningensis.
Luckowcarpa[118]	Gen. et sp. nov	Valid	Martínez	Late Eocene	Esmeraldas Formation	Colombia	A member of Fabaceae belonging to the group Dalbergieae. Genus includes new species L. gunnii.
Lusitanispermum[103]	Gen. et sp. nov	Valid	Friis, Crane & Pedersen	Early Cretaceous		Portugal	A flowering plant with affinities to Austrobaileyales or Nymphaeales. Genus includes new species L. choffatii.
Maytenoxylon[119]	Gen. et sp. nov	Valid	Franco	Late Cenozoic	Ituzaingó Formation	Argentina	A member of Celastraceae described on the basis of fossil wood. Genus includes new species M. perforatum.
Mcraeoxylon[112]	Gen. et sp. nov	Valid	Estrada-Ruiz et al.	Late Cretaceous (late Campanian)	McRae Formation	United States ( New Mexico)	A flowering plant described on the basis of fossil wood, with a suite of features seen in several families of Malpighiales, Myrtales and Oxalidales. Genus includes new species M. waddellii.
Menispermites calderensis[120]	Sp. nov	Valid	Jud et al.	Eocene (Ypresian)	Huitrera Formation	Argentina	A member of the family Menispermaceae described on the basis of fossil leaves.
Menispermites olmosensis[94]	Sp. nov	Valid	Guzmán-Vázquez, Calvillo-Canadell & Sánchez-Beristain	Late Cretaceous	Olmos Formation	Mexico	A member of the family Menispermaceae.
Nelumbo jiayinensis[121]	Sp. nov	Valid	Liang et al.	Late Cretaceous (Santonian)	Yong'ancun Formation	China	A species of Nelumbo.
Neofructus[122]	Gen. et sp. nov	Valid	Liu & Wang	Early Cretaceous (Barremian–Aptian)	Yixian Formation	China	An early flowering plant. Genus includes new species N. lingyuanensis.
Nitaspermum[123]	Gen. et 5 sp. nov	Valid	Friis, Crane & Pedersen	Early Cretaceous (Albian)	Potomac Group	United States ( Maryland  Virginia)	A fossil seed with affinities to Austrobaileyales and Nymphaeales. Genus includes new species N. taylorii, N. hopewellense, N. crassum, N. virginiense and N. marylandense.
Obamacarpa[97]	Gen. et sp. nov	Valid	Atkinson, Stockey & Rothwell	Late Cretaceous (early Coniacian)		Canada ( British Columbia)	A member of Cornales. Genus includes new species O. edenensis.
Paisia[124]	Gen. et sp. nov	Valid	Friis, Mendes & Pedersen	Early Cretaceous (late Barremian–early Albian)	Almargem Formation	Portugal	An early eudicot. Genus includes new species P. pantoporata.
Paleoallium[125]	Gen. et sp. nov	Valid	Pigg, Bryan & DeVore	Early Eocene	Klondike Mountain Formation	United States ( Washington)	A monocot similar to members of Amaryllidaceae. Genus includes new species P. billgenseli.
Paliurus pubescencea[126]	Sp. nov	In press	Dong et al.	Middle Miocene		China	A species of Paliurus.
Palmoxylon araneus[127]	Sp. nov	Valid	Nour-El-Deen, El-Saadawi & Thomas	Oligocene (Rupelian)	Jebel Qatrani Formation	Egypt
Palmoxylon elsaadawii[127]	Sp. nov	Valid	Nour-El-Deen & Thomas in Nour-El-Deen, Thomas & El-Saadawi	Oligocene (Rupelian)	Jebel Qatrani Formation	Egypt
Palmoxylon qatraniense[127]	Sp. nov	Valid	Nour-El-Deen, El-Saadawi & Thomas	Oligocene (Rupelian)	Jebel Qatrani Formation	Egypt
Paraalbizioxylon sinica[93]	Sp. nov	In press	Cheng et al.	Pliocene	Yuanmou Basin	China	A member of the family Fabaceae described on the basis of fossil wood.
Paraalbizioxylon yunnanensis[93]	Sp. nov	In press	Cheng et al.	Pliocene	Yuanmou Basin	China	A member of the family Fabaceae described on the basis of fossil wood.
Parahancornioxylon[128]	Gen. et comb. nov	Valid	Moya, Brea & Lutz	Pliocene	Andalhualá Formation	Argentina	A member of Apocynaceae described on the basis of fossil wood; a new genus for "Menendoxylon" piptadiensis Lutz (1987).
Paraphyllanthoxylon antarcticum[89]	Sp. nov	Valid	Pujana in Pujana et al.	Late Cretaceous (Campanian)	Santa Marta Formation	Antarctica (James Ross Island)	A flowering plant of uncertain phylogenetic placement, described on the basis of fossil wood.
Pazlia[103]	Gen. et sp. nov	Valid	Friis, Crane & Pedersen	Early Cretaceous		Portugal	A flowering plant with affinities to Austrobaileyales or Nymphaeales. Genus includes new species P. hilaris.
Pazliopsis[103]	Gen. et sp. nov	Valid	Friis, Crane & Pedersen	Early Cretaceous	Almargem Formation	Portugal	A flowering plant with affinities to Austrobaileyales or Nymphaeales. Genus includes new species P. reyi.
Pistacioxylon ufuki[129]	Sp. nov	Valid	Akkemik & Poole in Akkemik et al.	Early Miocene	Haymana Basin	Turkey	A Pistacia-like plant described on the basis of fossil wood.
Polyalthioxylon arunachalensis[130]	Sp. nov	Valid	Srivastava, Mehrotra & Srikarni	Late Pliocene–Early Pleistocene	Kimin Formation	India	A member of the family Annonaceae described on the basis of fossil wood.
Priscophyllum[91]	Nom. nov	Valid	Doweld	Late Cretaceous (Cenomanian)		Czech Republic	A flowering plant described on the basis of fossil leaves; a replacement name for the invalidly published Grevilleophyllum Velenovský (1889). Genus includes "Grevillea" constans Velenovský (1883).
Prunus hirsutipetala[131]	Sp. nov	In press	Sokoloff, Remizowa & Nuraliev in Sokoloff et al.	Eocene	Rovno amber	Ukraine	A species of Prunus.
Pseudoanacardium[132]	Gen. et comb. nov	Valid	Manchester & Balmaki	Early Oligocene		Peru	A fossil fruit of uncertain phylogenetic placement; a new genus for "Anacardium" peruvianum Berry (1924).
Pseudolimnobiophyllum[87]	Gen. et sp. nov	In press	Coiffard & Mohr	Late Cretaceous (Campanian)	Quseir Formation	Egypt	A member of the family Araceae belonging to the subfamily Lemnoideae. Genus includes new species P. simile.
Pseudowinterapollis agatdalensis[133]	Sp. nov	Valid	Grímsson & Zetter in Grímsson et al.	Paleocene (Danian)	Agatdal Formation	Greenland	A pollen taxon, a member of the family Winteraceae.
Psilastephanocolporites brevissimus[85]	Sp. nov	In press	D'Apolito et al.	Pliocene–Pleistocene		Brazil	Fossil pollen of a flowering plant, possibly a member of the genus Myrsine.
Psilatriporites aspidatus[85]	Sp. nov	In press	D'Apolito et al.	Pliocene–Pleistocene		Brazil	Fossil pollen of a member of the genus Faramea.
Pterocaryoxylon huxii[93]	Sp. nov	In press	Cheng et al.	Pliocene	Yuanmou Basin	China	A member of the family Juglandaceae described on the basis of fossil wood.
Pterygota eocenica[102]	Sp. nov	In press	Shukla, Mehrotra & Nawaz Ali	Early Eocene	Palana Formation	India	A species of Pterygota.
Quercus shangcunensis[134]	Sp. nov	In press	Liu et al.	Early Oligocene	Shangcun Formation	China	An oak
Retiacolpites pigafettaensis[95]	Sp. nov	Valid	Prasad et al.	Late Cretaceous (Maastrichtian)		India	A pollen taxon.
Reyispermum[103]	Gen. et sp. nov	Valid	Friis, Crane & Pedersen	Early Cretaceous	Figueira da Foz Formation	Portugal	A flowering plant with affinities to Austrobaileyales or Nymphaeales. Genus includes new species R. parvum.
Rhoipites? basicus[85]	Sp. nov	In press	D'Apolito et al.	Pliocene–Pleistocene		Brazil	Fossil pollen of a flowering plant.
Rhoipites manausensis[85]	Sp. nov	In press	D'Apolito et al.	Pliocene–Pleistocene		Brazil	Fossil pollen of a member of the genus Schefflera.
Rhoipites minuticirculus[85]	Sp. nov	In press	D'Apolito et al.	Pliocene–Pleistocene		Brazil	Fossil pollen of a flowering plant.
Rhoipites negroensis[85]	Sp. nov	In press	D'Apolito et al.	Pliocene–Pleistocene		Brazil	Fossil pollen of a flowering plant.
Rightcania[110]	Gen. et sp. nov	Valid	Friis, Crane & Pedersen	Early Cretaceous (Albian)	Potomac Group	United States ( Virginia)	A member of the family Chloranthaceae. Genus includes new species R. kvacekii.
Ripogonum palaeozeylandiae[135]	Sp. nov	Valid	Conran, Kennedy & Bannister	Early Eocene		New Zealand	A species of Ripogonum.
Ruprechtioxylon breae[119]	Sp. nov	Valid	Franco	Late Cenozoic	Ituzaingó Formation	Argentina	A member of Polygonaceae described on the basis of fossil wood.
Salacia lombardii[136]	Sp. nov	Valid	Hernández-Damián, Gómez-Acevedo & Cevallos-Ferriz	Miocene		Mexico	A species of Salacia.
Schoenoplectiella isolepioides[86]	Sp. nov	Valid	Doweld	Pliocene		Germany	A member of the family Cyperaceae; a replacement name for the invalidly named Scirpus (Schoenoplectus) isolepioides Mai & Walther (1988).
Scirpus novorossicus[86]	Nom. nov	Valid	Doweld	Miocene (Tortonian)		Ukraine	A species of Scirpus; a replacement name for Scirpus leptocarpus Negru (1986), preoccupied by extant Scirpus leptocarpus Mueller (1855).
Silutanispermum[103]	Gen. et sp. nov	Valid	Friis, Crane & Pedersen	Early Cretaceous		Portugal	A flowering plant with affinities to Austrobaileyales or Nymphaeales. Genus includes new species S. kvacekiorum.
Sloanea siwalika[137]	Sp. nov	Valid	More et al.	Pliocene	Geabdat Sandstone Formation	India	A species of Sloanea.
Soepadmoa[138]	Gen. et sp. nov	Valid	Nixon, Crepet, Gandolfo & Grimaldi	Late Cretaceous (Turonian)	Raritan Formation (New Jersey amber)	United States ( New Jersey)	A member of Fagales of uncertain phylogenetic placement. Genus includes new species S. cupulata.
Staphylea spinosa[139]	Sp. nov	Valid	Huang & Momohara in Huang, Momohara & Wang	Pleistocene	Shobudani Formation	Japan	A species of Staphylea.
Stafylioxylon[74]	Gen. et comb. nov	Valid	Rozefelds & Pace	Eocene	London Clay	United Kingdom	A member of Vitaceae; a new genus for "Vitaceoxylon" ramunculiformis Poole & Wilkinson (2000).
Stellatia[71]	Gen. et comb. nov	Valid	Arai & Dias-Brito	Late Cretaceous (Santonian)	São Carlos Formation	Brazil	A phytoclast, possibly a member of Nymphaeaceae. Genus includes S. furcata (Duarte & Arai, 2010).
Stephania jacquesii[140]	Sp. nov	Valid	Han & Manchester in Han et al.	Late Eocene to late Oligocene	Clarno Formation Yongning Formation	China  United States ( Oregon)	A species of Stephania.
Stephania psittaca[120]	Sp. nov	Valid	Jud & Gandolfo in Jud et al.	Paleocene (Danian)	Salamanca Formation	Argentina	A species of Stephania.
Stephania wilfii[140]	Sp. nov	Valid	Han & Manchester in Han et al.	Paleocene to Eocene	Green River Formation	United States ( Wyoming)	A species of Stephania.
Syzygium gurhaensis[102]	Sp. nov	In press	Shukla, Mehrotra & Nawaz Ali	Early Eocene	Palana Formation	India	A species of Syzygium.
Tanispermum[141]	Gen. et 4 sp. nov	Valid	Friis, Crane & Pedersen	Early Cretaceous (early Aptian to early to middle Albian)	Potomac Group	United States ( Maryland  Virginia)	A flowering plant with affinities to Austrobaileyales or Nymphaeales. Genus includes new species T. hopewellense, T. marylandense, T. drewriense and T. antiquum.
Teuschestanthes[142]	Gen. et sp. nov	Valid	Crepet, Nixon & Weeks	Late Cretaceous (Turonian)	Lower Magothy Formation	United States ( New Jersey)	A member of Ericales of uncertain phylogenetic placement. Genus includes new species T. squamata.
Trichomites[71]	Gen. et 3 sp. nov	Valid	Arai & Dias-Brito	Late Cretaceous (Santonian)	São Carlos Formation	Brazil	A phytoclast. Genus includes new species T. brevifurcatus (probably a member of Campanulaceae), T. duplihelicoidus (affinity unknown) and T. simplex (a dicotyledon of uncertain affinity).
Tricolpites joelcastroi[71]	Sp. nov	Valid	Arai & Dias-Brito	Late Cretaceous (Santonian)	São Carlos Formation	Brazil	A pollen taxon, an indeterminate dicotyledon.
Trochodendron postnastae[88]	Sp. nov	Valid	Manchester, Pigg & Devore	Middle Miocene	Little Butte Volcanic Series	United States ( Oregon)	A species of Trochodendron.
Trochodendron rosayi[88]	Sp. nov	Valid	Manchester, Pigg & Devore	Middle Miocene	Little Butte Volcanic Series	United States ( Idaho  Oregon)	A species of Trochodendron.
Turneroxylon[112]	Gen. et sp. nov	Valid	Estrada-Ruiz et al.	Late Cretaceous (late Campanian)	McRae Formation	United States ( New Mexico)	An eudicot with similarities to members of Dilleniaceae, described on the basis of fossil wood. Genus includes new species T. newmexicoense.
Ulmus priamurica[143]	Sp. nov	Valid	Blokhina & Bondarenko	Miocene	Sazanka Formation	Russia ( Amur Oblast)	An elm.
Ventilago fujianensis[126]	Sp. nov	In press	Dong et al.	Middle Miocene		China	A species of Ventilago.
Weinmannioxylon trichospermoides[89]	Sp. nov	Valid	Pujana in Pujana et al.	Late Cretaceous (Campanian)	Santa Marta Formation	Antarctica (James Ross Island)	A member of Cunoniaceae described on the basis of fossil wood.
Wilkinsoniphyllum[120]	Gen. et sp. nov	Valid	Jud et al.	Paleocene (Danian)	Salamanca Formation	Argentina	A member of the family Menispermaceae described on the basis of fossil leaves. Genus includes new species W. menispermoides.
Zelkovoxylon yesimae[129]	Sp. nov	Valid	Akkemik & Poole in Akkemik et al.	Early Miocene	Haymana Basin	Turkey	A Zelkova-like plant described on the basis of fossil wood.
Zygogynum poratus[144]	Sp. nov	Valid	Liang & Zhou in Liang et al.	Middle Miocene		China	A species of Zygogynum.

Pinales

Name	Novelty	Status	Authors	Age	Unit	Location	Notes	Images
Agathis immortalis[145]	Sp. nov	Valid	Escapa et al.	Paleocene (Danian)		Argentina	A species of Agathis.
Agathoxylon crasseradiatum[146]	Sp. nov	Valid	Lignier ex Philippe et al.	Early Cretaceous (late Aptian-Albian)		France	A member of Araucariaceae described on the basis of fossil wood.
Agathoxylon santacruzense[147]	Sp. nov	Valid	Kloster & Gnaedinger	Middle Jurassic	La Matilde Formation	Argentina
Araucaria fildesensis[148]	Sp. nov	In press	Shi et al.	Eocene	Fossil Hill Formation	Antarctica (King George Island)	A species of Araucaria.
Araucaria lefipanensis[149]	Sp. nov	Valid	Andruchow‐Colombo et al.	Late Cretaceous	Lefipán Formation	Argentina	A species of Araucaria.
Atlanticoxylon ibiratinum[150]	Sp. nov	Valid	Faria et al.	Permian (Artinskian)	Irati Formation	Brazil	A conifer described on the basis of fossil wood.
Chimaerostrobus[151]	Gen. et sp. nov	Valid	Atkinson et al.	Early Jurassic		Antarctica	A conifer pollen cone. Genus includes new species C. minutus.
Cryptomeria yunnanensis[152]	Sp. nov	Valid	Ding & Zhou in Ding et al.	Oligocene (Rupelian)	Lühe Basin	China	A member of Cupressaceae, a species of Cryptomeria.
Cunninghamia shangcunica[153]	Sp. nov	In press	Kodrul et al.	Early Oligocene	Shangcun Formation	China	A species of Cunninghamia.
Cyclusphaera annularis[154]	Sp. nov	Valid	Perez Loinaze & Llorens	Early Cretaceous (Aptian)	Anfiteatro de Ticó Formation	Argentina	A pollen taxon with affinities with the family Araucariaceae.
Cyclusphaera punnulosa[154]	Sp. nov	Valid	Perez Loinaze & Llorens	Early Cretaceous (Aptian)	Anfiteatro de Ticó Formation	Argentina	A pollen taxon with affinities with the family Araucariaceae.
Elatides laiyangensis[155]	Sp. nov	Valid	Jin & Sun in Jin et al.	Early Cretaceous	Laiyang Formation	China	A conifer.
Hirandubia[156]	Gen. et sp. nov	In press	Ghosh et al.	Early Cretaceous	Rajmahal Basin	India	A member of Cupressaceae. Genus includes new species H. cupressoides.
Morinostrobus[157]	Gen. et sp. nov	Valid	Stockey et al.	Early Cretaceous (Valanginian)		Canada ( British Columbia)	A member of Cupressaceae described on the basis of pollen cones. Genus includes new species M. holbergensis.
Pinus daflaensis[158]	Nom. nov	Valid	Khan & Bera	Miocene	Dafla Formation	India	A pine; a replacement name for Pinus arunachalensis Khan & Bera (2017) (preoccupied by Pinus arunachalensis Srivastava, 2017).
Pinus leiophylloides[159]	Nom. nov	Valid	Doweld	Oligocene (Chattian)		France	A pine; a replacement name for Pinus pseudotaeda Saporta (1865).
Pinus microstrobus[159]	Nom. nov	Valid	Doweld	Oligocene (Chattian)		France	A pine; a replacement name for Pinus microcarpa Saporta (1865).
Pinus notata[159]	Nom. nov	Valid	Doweld	Oligocene (Chattian)		France	A pine; a replacement name for Pinus divaricata Saporta (1865).
Pinus pentaphylloides[159]	Nom. nov	Valid	Doweld	Late Cretaceous (Santonian)		Japan	A pine; a replacement name for Pinus hokkaidoensis Stockey & Ueda (1986).
Pinus plioarmandii[160]	Sp. nov	In press	An et al.	Pliocene		China	A pine.
Pinus tetraphylloides[159]	Nom. nov	Valid	Doweld	Oligocene (Chattian)		France	A pine; a replacement name for Pinus deflexa Saporta (1865).
Platycladus preorientalis[161]	Sp. nov	In press	He et al.	Early Miocene		China	A species of Platycladus.
Podocarpospermum podocarpoides[156]	Sp. nov	In press	Ghosh et al.	Early Cretaceous	Rajmahal Basin	India	A member of Podocarpaceae.
Protodammara reimatamoriori[162]	Sp. nov	In press	Mays & Cantrill	Late Cretaceous (Cenomanian)	Tupuangi Formation	New Zealand	A member of Cupressaceae.
Pseudofrenelopsis salesii[163]	Sp. nov	Valid	Batista et al.	Early Cretaceous (Albian)	Romualdo Member	Brazil	A member of Cheirolepidiaceae.
Rabagostrobus[164]	Gen. et sp. nov	In press	Kvaček et al.	Early Cretaceous (Albian)		Spain	An araucarian pollen cone. Genus includes new species R. hispanicus.
Sequoioxylon carneyvillense[165]	Sp. nov	Valid	Li, Jin & Manchester	Paleocene	Fort Union Formation	United States ( Wyoming)	Fossil wood resembling Sequoia.
Sequoioxylon zhangii[166]	Sp. nov	Valid	Tian et al.	Late Cretaceous		China	A member of Sequoioideae described on the basis of fossil wood.
Yanliaoa daohugouensis[167]	Sp. nov	Valid	Tan et al.	Middle Jurassic	Daohugou Beds	China	A member of Cupressaceae sensu lato.

Other seed plants

Name	Novelty	Status	Authors	Age	Unit	Location	Notes	Images
Calycosperma[168]	Gen. et sp. nov	Valid	Liu et al.	Late Devonian	Wutong Formation	China	An early seed plant. Genus includes new species C. qii.
Cordaites daviessensis[169]	Sp. nov	Valid	Šimůnek	Carboniferous (early Westphalian D)	Staunton Formation	United States ( Indiana)
Cordaites kinneyensis[169]	Sp. nov	Valid	Šimůnek	Carboniferous (Stephanian B)	Atrasado Formation	United States ( New Mexico)
Cordaites minshallensis[169]	Sp. nov	Valid	Šimůnek	Carboniferous (Bolsovian)	Brazil Formation	United States ( Indiana)
Cordaites olneyensis[169]	Sp. nov	Valid	Šimůnek	Carboniferous (late Pennsylvanian)	Mattoon Formation	United States ( Illinois)
Cycadolepis ferrugineus[170]	Sp. nov	Valid	McLoughlin, Pott & Sobbe	Jurassic (Pliensbachian–Aalenian)		Australia	A member of Bennettitales belonging to the family Williamsoniaceae.
Cycadopites grossus[154]	Sp. nov	Valid	Perez Loinaze & Llorens	Early Cretaceous (Aptian)	Anfiteatro de Ticó Formation	Argentina	A pollen taxon, similar to many of the modern cycad pollen types.
Czekanowskia ottenii[171]	Sp. nov	Valid	Kiritchkova, Kostina & Nosova	Jurassic		Russia
Douropteris[172]	Gen. et sp. nov	In press	Correia et al.	Carboniferous (Gzhelian)	Douro Basin	Portugal	A seed fern belonging to the group Medullosales. Genus includes new species D. alvarezii.
Eamesia[173]	Gen. et sp. nov	Valid	Yang et al.	Early Cretaceous (Aptian)	Yixian Formation	China	A member of Ephedraceae. Genus includes new species E. chinensis.
Eretmophyllum neimengguensis[174]	Sp. nov	Valid	Li et al.	Middle Jurassic	Yan’an Formation	China	A member of Ginkgoales.
Eretmophyllum olchaense[171]	Sp. nov	Valid	Kiritchkova, Kostina & Nosova	Jurassic		Russia
Hexianthus[175]	Gen. et sp. nov	Valid	Wang & Sun in Wang et al.	Early Permian	Taiyuan Formation	China	A cone fossil belonging to the group Cordaitopsida and the family Cordaitaceae. Genus includes new species H. shenii.
Jugasporites vellicoites[176]	Sp. nov	Valid	Zavattieri, Gutiérrez & Ezpeleta	Permian (Lopingian)	La Veteada Formation	Argentina	A member of Voltziales described on the basis of fossil pollen grains.
Nilssoniopteris crassiaxis[177]	Sp. nov	Valid	Zhao & Deng in Zhao et al.	Middle Jurassic	Xishanyao Formation	China	A member of Bennettitales.
Nilssoniopteris hamiensis[177]	Sp. nov	Valid	Zhao & Deng in Zhao et al.	Middle Jurassic	Xishanyao Formation	China	A member of Bennettitales.
Nilssoniopteris neimenguensis[178]	Nom. nov	Valid	Zhao & Deng in Zhao et al.	Early and Middle Jurassic	Hongqi Formation Mentougou Formation	China	A member of Bennettitales; a replacement name for Nilssoniopteris angustifolia Wang (1984), preoccupied by Nilssoniopteris angustifolia Doludenko and Svanidze (1969).
Otozamites toshioensoi[179]	Sp. nov	Valid	Yamada, Legrand & Nishida	Early Cretaceous (Albian)	Sasayama Group	Japan
Pachytestopsis[180]	Gen. et sp. nov	Valid	McLoughlin, Bomfleur & Drinnan	Permian (Changhsingian)	Fort Cooper Coal Measures	Australia	A member of Glossopteridales. Genus includes new species P. tayloriorum.
Phoenicopsis kurminensis[181]	Sp. nov	Valid	Frolov in Frolov & Mashchuk	Middle Jurassic	Irkutsk Basin	Russia	A member of Leptostrobales (= Czekanowskiales).
Podozamites harrisii[182]	Sp. nov	Valid	Shi et al.	Early Cretaceous (Aptian–Albian)	Tevshiin Govi Formation	Mongolia	A conifer belonging to the family Podozamitaceae, described on the basis of leaves.
Pseudotorellia kiensis[183]	Sp. nov	Valid	Nosova & Golovneva	Late Cretaceous		Russia	A member of Ginkgoales, described on the basis of leaves.
Pseudotorellia palustris[182]	Sp. nov	Valid	Shi et al.	Early Cretaceous (Aptian–Albian)	Tevshiin Govi Formation	Mongolia	A member of Ginkgoales, described on the basis of leaves.
Pseudotorellia parvifolia[183]	Sp. nov	Valid	Nosova & Golovneva	Early Cretaceous		Russia	A member of Ginkgoales, described on the basis of leaves.
Pseudotorellia resinosa[182]	Sp. nov	Valid	Shi et al.	Early Cretaceous (Aptian–Albian)	Tevshiin Govi Formation	Mongolia	A member of Ginkgoales, described on the basis of leaves.
Pterophyllum philippoviae[184]	Sp. nov	Valid	Gnilovskaya & Golovneva	Late Cretaceous (Turonian–Coniacian)		Russia ( Magadan Oblast)	A member of Bennettitales.
Pterophyllum terechoviae[184]	Sp. nov	Valid	Gnilovskaya & Golovneva	Late Cretaceous (Maastrichtian)	Kakanaut Formation	Russia ( Koryak Okrug)	A member of Bennettitales.
Ptilozamites longifolia[185]	Sp. nov	Valid	Cariglino, Monti & Zavattieri	Middle Triassic	Quebrada de los Fósiles Formation	Argentina	A seed fern.
Samaropsis shenii[175]	Sp. nov	Valid	Wang & Sun in Wang et al.	Early Permian	Taiyuan Formation	China	A seed fossil belonging to the group Cordaitopsida and the family Cordaitaceae.
Solenites haojiagouensis[186]	Sp. nov	Valid	Yang et al.	Late Triassic	Haojiagou Formation	China	A member of Czekanowskiales.
Sphenopteris valentinii[187]	Sp. nov	Valid	Forte & Kerp in Forte et al.	Permian (Kungurian)	Tregiovo Formation	Italy	A fern-like plant, probably a seed fern.
Trisquama[188]	Gen. et sp. nov	Valid	Gordenko & Broushkin	Middle Jurassic (Bathonian)		Russia ( Kursk Oblast)	A gymnosperm of uncertain phylogenetic placement, belonging to the new order Trisquamales. Genus includes new species T. valentinii.
Williamsonia durikaiensis[170]	Sp. nov	Valid	McLoughlin, Pott & Sobbe	Jurassic (Pliensbachian–Aalenian)		Australia	A member of Bennettitales belonging to the family Williamsoniaceae.
Williamsonia eskensis[170]	Sp. nov	Valid	McLoughlin, Pott & Sobbe	Middle Triassic	Esk Formation	Australia	A member of Bennettitales belonging to the family Williamsoniaceae.
Williamsonia gracilis[170]	Sp. nov	Valid	McLoughlin, Pott & Sobbe	Early Cretaceous (Berriasian–Hauterivian)	Lees Sandstone	Australia	A member of Bennettitales belonging to the family Williamsoniaceae.
Williamsonia ipsvicensis[170]	Sp. nov	Valid	McLoughlin, Pott & Sobbe	Late Triassic (Carnian or earliest Norian)	Blackstone Formation	Australia	A member of Bennettitales belonging to the family Williamsoniaceae.
Williamsonia rugosa[170]	Sp. nov	Valid	McLoughlin, Pott & Sobbe	Middle Jurassic (Aalenian–Bajocian)		Australia	A member of Bennettitales belonging to the family Williamsoniaceae.
Wintucycas beatrizae[189]	Sp. nov	Valid	Martínez, Ottone & Artabe	Paleocene	Pichaihue Limestone	Argentina	A cycad belonging to the group Encephalartoideae.
Zamia nelliae[190]	Sp. nov	Valid	Erdei & Calonje in Erdei et al.	Late Eocene	Gatuncillo Formation	Panama	A cycad, a species of Zamia.

Other plants

Name	Novelty	Status	Authors	Age	Unit	Location	Notes	Images
Acitheca murphyi[191]	Sp. nov	In press	Correia et al.	Carboniferous (Gzhelian)	Douro Basin	Portugal	A marattialean fern.
Adoketophyton pingyipuensis[192]	Sp. nov	Valid	Edwards & Li	Early Devonian	Pingyipu Group	China
Apiculatasporites ruptus[193]	Sp. nov	Valid	Noetinger, di Pasquo & Starck	Devonian		Argentina	A trilete spore.
Aptychellites[194]	Gen. et sp. nov	Valid	Schäfer-Verwimp, Hedenäs, Ignatov & Heinrichs in Kaasalainen et al.	Miocene	Dominican amber	Dominican Republic	A moss resembling members of the extant genus Aptychella of the family Pylaisiadelphaceae. Genus includes new species A. fossilis.
Arthropitys taoshuyuanensis[195]	Sp. nov	Valid	Chen et al.	Permian (Wuchiapingian)	Wutonggou Formation	China	A member of Calamitaceae.
Asinisetum plaatkopensis[196]	Sp. nov	Valid	Anderson & Anderson	Late Triassic (Carnian)	Molteno Formation	South Africa	A member of Equisetopsida belonging to the group Equisetales and the family Equisetaceae.
Azolla coloniensis[197]	Sp. nov	Valid	De Benedetti et al.	Late Cretaceous		Argentina	A species of Azolla.
Balenosetum[196]	Gen. et sp. nov	Valid	Anderson & Anderson	Late Triassic (Carnian)	Molteno Formation	South Africa	A member of Equisetopsida belonging to the group Echinostachyales. Genus includes new species B. candlewaxia.
Baoyinia[198]	Gen. et sp. nov	Valid	Edwards & Li	Early Devonian	Pingyipu Group	China	A zosterophyll. Genus includes new species B. sichuanensis.
Calamospora fissurata[199]	Sp. nov	Valid	Gutiérrez & Balarino	Carboniferous (Pennsylvanian)	Ordóñez Formation	Argentina	A spore taxon.
Callixylon wendtii[200]	Sp. nov	In press	Tanrattana, Meyer-Berthaud & Decombeix	Devonian (Famennian)		Morocco	An archaeopteridalean progymnosperm.
Cetistachys[196]	Gen. et sp. nov	Valid	Anderson & Anderson	Late Triassic (Carnian)	Molteno Formation	South Africa	A member of Equisetopsida belonging to the group Echinostachyales. Genus includes new species C. cetenis.
Cheilolejeunea lamyi[201]	Sp. nov	Valid	Heinrichs et al.	Miocene	Dominican amber	Dominican Republic	A member of Lejeuneaceae.
Cingulatisporites oligodistalis[85]	Sp. nov	In press	D'Apolito et al.	Pliocene–Pleistocene		Brazil	Fossil spore.
Concavissimisporites varzeanus[85]	Sp. nov	In press	D'Apolito et al.	Pliocene–Pleistocene		Brazil	Fossil spore.
Coniopteris sandaolingensis[202]	Sp. nov	In press	Yuan & Sun in Yuan et al.	Middle Jurassic	Xishanyao Formation	China
Cooksonia barrandei[203]	Sp. nov	Valid	Libertín et al.	Early Silurian	Motol Formation	Czech Republic
Coptospora santacrucensis[154]	Sp. nov	Valid	Perez Loinaze & Llorens	Early Cretaceous (Aptian)	Anfiteatro de Ticó Formation	Argentina	A spore taxon similar to spores of extant members of the families Sphaerocarpaceae, Ricciaceae and Riellaceae.
Crybelosporites corrugatus[154]	Sp. nov	Valid	Perez Loinaze & Llorens	Early Cretaceous (Aptian)	Anfiteatro de Ticó Formation	Argentina	A spore taxon related to the family Marsileaceae.
Culcita remberi[204]	Sp. nov	In press	Pinson, Manchester & Sessa	Miocene	Clarkia fossil beds	United States ( Idaho)	A species of Culcita.
Cyathocarpus yongchangensis[205]	Sp. nov	In press	Sun & Sun in Sun et al.	Permian (Cisuralian)	Shanxi Formation	China	A fern related to Psaronius.
Cymatiosphaera robusta[193]	Sp. nov	Valid	Noetinger, di Pasquo & Starck	Devonian		Argentina	A prasinophyte.
Densoisporites patagonicus[154]	Sp. nov	Valid	Perez Loinaze & Llorens	Early Cretaceous (Aptian)	Anfiteatro de Ticó Formation	Argentina	A spore taxon with affinities with the Lycopsida.
Dictyophyllum menendezii[206]	Sp. nov	Valid	Bodnar et al.	Middle Triassic (Ladinian)	Cortaderita Formation	Argentina	A fern belonging to the family Dipteridaceae.
Digitopteris[207]	Gen. et sp. nov	Valid	Pott & Bomfleur in Pott et al.	Late Triassic (Carnian)		Austria	A fern belonging to the family Dipteridaceae. Genus includes new species D. repanda.
Echinatisporis parviechinatus[85]	Sp. nov	In press	D'Apolito et al.	Pliocene–Pleistocene		Brazil	Fossil spore.
Echinosporis conicus[85]	Sp. nov	In press	D'Apolito et al.	Pliocene–Pleistocene		Brazil	Fossil spore.
Echinostachys tinensis[196]	Sp. nov	Valid	Anderson & Anderson	Late Triassic (Carnian)	Molteno Formation	South Africa	A member of Equisetopsida belonging to the group Echinostachyales and the family Echinostachyaceae.
Eddianna[208]	Gen. et sp. nov	Valid	Pfeiler & Tomescu	Devonian (Emsian)	Battery Point Formation	Canada ( Quebec)	A member of Rhyniopsida. Genus includes new species E. gaspiana
Emphanisporites genselae[209]	Sp. nov	Valid	Wellman	Devonian (Pragian-earliest Emsian)	Val d'Amour Formation	Canada ( New Brunswick)	A plant described on the basis of fossil spores.
Emphanisporites morrisae[209]	Sp. nov	Valid	Wellman	Devonian (Pragian-earliest Emsian)	Campbellton Formation Val d'Amour Formation	Canada ( New Brunswick)	A plant described on the basis of fossil spores.
Emphanisporites? tenuis[210]	Sp. nov	Valid	García Muro, Rubinstein & Steemans	Silurian (Přídolí)	Los Espejos Formation	Argentina	A plant described on the basis of fossil spores.
Endosporites menendezi[199]	Nom. nov	Valid	Gutiérrez & Balarino	Carboniferous (Pennsylvanian)	Agua Colorada Formation	Argentina	A spore taxon; a replacement name for Endosporites parvus  Menéndez (1965).
Equisetites greenensis[196]	Sp. nov	Valid	Anderson & Anderson	Late Triassic (Carnian)	Molteno Formation	South Africa	A member of Equisetopsida belonging to the group Equisetales and the family Equisetaceae.
Equisetites kanensis[196]	Sp. nov	Valid	Anderson & Anderson	Late Triassic (Carnian)	Molteno Formation	South Africa	A member of Equisetopsida belonging to the group Equisetales and the family Equisetaceae.
Equisetites kapokensis[196]	Sp. nov	Valid	Anderson & Anderson	Late Triassic (Carnian)	Molteno Formation	South Africa	A member of Equisetopsida belonging to the group Equisetales and the family Equisetaceae.
Equisetites nuwensis[196]	Sp. nov	Valid	Anderson & Anderson	Late Triassic (Carnian)	Molteno Formation	South Africa	A member of Equisetopsida belonging to the group Equisetales and the family Equisetaceae.
Equisetites pentapenensis[196]	Sp. nov	Valid	Anderson & Anderson	Late Triassic (Carnian)	Molteno Formation	South Africa	A member of Equisetopsida belonging to the group Equisetales and the family Equisetaceae.
Equisetites umkensis[196]	Sp. nov	Valid	Anderson & Anderson	Late Triassic (Carnian)	Molteno Formation	South Africa	A member of Equisetopsida belonging to the group Equisetales and the family Equisetaceae.
Equisetostachys boesmansensis[196]	Sp. nov	Valid	Anderson & Anderson	Late Triassic (Carnian)	Molteno Formation	South Africa	A member of Equisetopsida belonging to the group Equisetales and the family Equisetaceae.
Equisetostachys calensis[196]	Sp. nov	Valid	Anderson & Anderson	Late Triassic (Carnian)	Molteno Formation	South Africa	A member of Equisetopsida belonging to the group Equisetales and the family Equisetaceae.
Equisetostachys cervensis[196]	Sp. nov	Valid	Anderson & Anderson	Late Triassic (Carnian)	Molteno Formation	South Africa	A member of Equisetopsida belonging to the group Equisetales and the family Equisetaceae.
Equisetostachys jaarensis[196]	Sp. nov	Valid	Anderson & Anderson	Late Triassic (Carnian)	Molteno Formation	South Africa	A member of Equisetopsida belonging to the group Equisetales and the family Equisetaceae.
Equisetostachys kroonensis[196]	Sp. nov	Valid	Anderson & Anderson	Late Triassic (Carnian)	Molteno Formation	South Africa	A member of Equisetopsida belonging to the group Equisetales and the family Equisetaceae.
Equisetostachys laggensis[196]	Sp. nov	Valid	Anderson & Anderson	Late Triassic (Carnian)	Molteno Formation	South Africa	A member of Equisetopsida belonging to the group Equisetales and the family Equisetaceae.
Equisetostachys luziensis[196]	Sp. nov	Valid	Anderson & Anderson	Late Triassic (Carnian)	Molteno Formation	South Africa	A member of Equisetopsida belonging to the group Equisetales and the family Equisetaceae.
Equisetostachys penensis[196]	Sp. nov	Valid	Anderson & Anderson	Late Triassic (Carnian)	Molteno Formation	South Africa	A member of Equisetopsida belonging to the group Equisetales and the family Equisetaceae.
Equisetostachys pokensis[196]	Sp. nov	Valid	Anderson & Anderson	Late Triassic (Carnian)	Molteno Formation	South Africa	A member of Equisetopsida belonging to the group Equisetales and the family Equisetaceae.
Escapia[211]	Gen. et sp. nov	Valid	Rothwell, Millay & Stockey	Early Cretaceous		Canada ( British Columbia)	A member of Marattiales. Genus includes new species E. christensenioides.
Frederica kurdistanensis[212]	Sp. nov	Valid	Bucur et al.	Paleogene	Khurmala Formation	Iraq	A green alga belonging to the group Dasycladales.
Frullania zerovii[213]	Sp. nov	Valid	Mamontov, Ignatov & Perkovsky	Eocene	Rovno amber	Ukraine	A liverwort, a species of Frullania.
Gleicheniorachis sinensis[214]	Sp. nov	Valid	Tian et al.	Late Jurassic	Manketouebo Formation	China	A fern belonging to the family Gleicheniaceae.
Groenlandia pescheri[215]	Sp. nov	Valid	Uhl & Poschmann	Oligocene (Chattian)	Enspel Formation	Germany	A species of Groenlandia.
Hausmannia olaensis[216]	Sp. nov	In press	Golovneva & Grabovskiy	Late Cretaceous (Santonian–early Campanian)		Russia	A member of the family Dipteridaceae.
Heilongjiangcaulis[217]	Gen. et sp. nov	Valid	Cheng & Yang	Cretaceous	Songliao Basin	China	A tree fern. Genus includes new species H. keshanensis.
Holttumopteris[218]	Gen. et sp. nov	Valid	Regalado et al.	Cretaceous (Albian–Cenomanian )	Burmese amber	Myanmar	An eupolypod fern. Genus includes new species H. burmensis.
Horriditriletes chacoparanensis[199]	Sp. nov	Valid	Gutiérrez & Balarino	Carboniferous (Pennsylvanian)	Ordóñez Formation	Argentina	A spore taxon.
Hypnites lycopodioides[219]	Nom. nov	Valid	Ignatov & Váňa in Winterscheid et al.	Late Oligocene	Rott Formation	Germany	A member of Hypnales of uncertain phylogenetic placement; a replacement name for Hypnum lycopodioides Weber in Wessel & Weber.
Jaffrezocodium[220]	Gen. et sp. nov	Valid	Granier	Cretaceous (Albian-Cenomanian)		France  Spain	A green alga belonging to the group Bryopsidales. Genus includes new species J. bipennatus.
Jiangyounia[198]	Gen. et sp. nov	Valid	Edwards & Li	Early Devonian	Pingyipu Group	China	A rhyniophyte. Genus includes new species J. gengi.
Knorripteris taylorii[221]	Sp. nov	Valid	Galtier et al.	Triassic		Germany	A pteridophyte of uncertain phylogenetic placement.
Kowieria[222]	Gen. et sp. nov	Valid	Gess & Prestianni	Devonian (Famennian)	Witpoort Formation	South Africa	A lycopsid. Genus includes new species K. alveoformis.
Kraaiostachys[196]	Gen. et sp. nov	Valid	Anderson & Anderson	Late Triassic (Carnian)	Molteno Formation Santa Clara Formation	Mexico  South Africa	A member of Equisetopsida belonging to the group Equisetales and the family Equisetaceae. Genus includes new species K. plaatkopensis.
Leiosphaeridia ibateensis[71]	Sp. nov	Valid	Arai & Dias-Brito	Late Cretaceous (Santonian)	São Carlos Formation	Brazil	An acritarch, probably a prasinophyte.
Leiotriletes malanzanensis[199]	Nom. nov	Valid	Gutiérrez & Balarino	Carboniferous (Pennsylvanian)	Malanzán Formation	Argentina	A spore taxon; a replacement name for Leiotriletes tenuis Azcuy (1975).
Lejeunea miocenica[194]	Sp. nov	Valid	Heinrichs, Schäfer-Verwimp, Renner & Lee in Kaasalainen et al.	Miocene	Dominican amber	Dominican Republic	A liverwort, a species of Lejeunea.
Lilingostrobus[223]	Gen. et sp. nov	Valid	Gerrienne et al.	Devonian (Famennian)	Xikuangshan Formation	China	A member of Lycopsida of uncertain phylogenetic placement. Genus includes new species L. chaloneri.
Marsilea mascogos[224]	Sp. nov	Valid	Estrada-Ruiz et al.	Late Cretaceous (late Campanian)	Olmos Formation	Mexico	A species of Marsilea.
Molaspora aspera[225]	Sp. nov	Valid	Zavialova & Batten	Late Cretaceous (Cenomanian)		France	A member of Marsileaceae described on the basis of megaspores.
Moltenomites[196]	Gen. et 2 sp. nov	Valid	Anderson & Anderson	Late Triassic (Carnian)	Molteno Formation	South Africa	A member of Equisetopsida belonging to the group Echinostachyales. Genus includes new species M. linearifolia and M. attenuatifolia.
Naybandoporella[226]	Gen. et sp. et comb. nov	Valid	Senowbari-Daryan	Late Triassic (Rhaetian)	Nayband Formation	Greece  Iran	A green alga belonging to the group Dasycladales, possibly a member of the family Triploporellaceae. Genus includes new species N. rhaetica, as well as "Probolocupsis" sarmeikensis Senowbari-Daryan (2014).
Oleandra bangmaii[227]	Sp. nov	Valid	Xie et al.	Late Miocene		China	A species of Oleandra.
Ornicephalum[192]	Gen. et comb. nov	Valid	Edwards & Li	Early Devonian	Pingyipu Group	China	A member of Lycophytina; a new genus for "Zosterophyllum" sichuanensis Geng (1992).
?Osmunda weylandii[219]	Sp. nov	Valid	Kvaček & Winterscheid in Winterscheid et al.	Late Oligocene	Rott Formation	Germany	A fern, possibly a species of Osmunda.
Palambages pariunta[228]	Sp. nov	In press	Wainman et al.	Late Jurassic (late Kimmeridgian–early Tithonian)	Surat Basin	Australia	A colonial alga belonging to the group Chlorophyta.
Paraschizoneura fredensis[196]	Sp. nov	Valid	Anderson & Anderson	Late Triassic (Carnian)	Molteno Formation	South Africa	A member of Equisetopsida belonging to the group Echinostachyales and the family Echinostachyaceae.
Paraschizoneura quadripenensis[196]	Sp. nov	Valid	Anderson & Anderson	Late Triassic (Carnian)	Molteno Formation	South Africa	A member of Equisetopsida belonging to the group Echinostachyales and the family Echinostachyaceae.
Paraschizoneura rooipoortensis[196]	Sp. nov	Valid	Anderson & Anderson	Late Triassic (Carnian)	Molteno Formation	South Africa	A member of Equisetopsida belonging to the group Echinostachyales and the family Echinostachyaceae.
Paraschizoneura telensis[196]	Sp. nov	Valid	Anderson & Anderson	Late Triassic (Carnian)	Molteno Formation	South Africa	A member of Equisetopsida belonging to the group Echinostachyales and the family Echinostachyaceae.
Peromonolites globosum[154]	Sp. nov	Valid	Perez Loinaze & Llorens	Early Cretaceous (Aptian)	Anfiteatro de Ticó Formation	Argentina	A spore taxon with affinities with the Filicales.
Pleurorhizoxylon[229]	Gen. et sp. nov	Valid	Zhang et al.	Late Devonian		China	An early euphyllophyte. Genus includes new species P. yixingense.
Polycladophyton[198]	Gen. et sp. nov	Valid	Edwards & Li	Early Devonian	Pingyipu Group	China	A rhyniophyte. Genus includes new species P. gracilis.
Polypodiisporites serratus[85]	Sp. nov	In press	D'Apolito et al.	Pliocene–Pleistocene		Brazil	Fossil spore of a member of the family Polypodiaceae.
Polypodiisporites timidus[85]	Sp. nov	In press	D'Apolito et al.	Pliocene–Pleistocene		Brazil	Fossil spore of a member of the family Polypodiaceae.
Pterospermella simplex[193]	Sp. nov	Valid	Noetinger, di Pasquo & Starck	Devonian		Argentina	A prasinophyte.
Radula intecta[194]	Sp. nov	Valid	Renner, Schäfer-Verwimp & Heinrichs in Kaasalainen et al.	Miocene	Dominican amber	Dominican Republic	A species of Radula
Rafaherbstia[230]	Ge. et sp. nov	Valid	Vera & Césari	Early Cretaceous (Aptian)	Cerro Negro Formation	Antarctica (Livingston Island)	A cyathealean tree fern. Genus includes new species R. nishidai.
Retitriletes ornatus[154]	Sp. nov	Valid	Perez Loinaze & Llorens	Early Cretaceous (Aptian)	Anfiteatro de Ticó Formation	Argentina	A spore taxon with affinities with the Lycopodiales.
Retusotriletes archangelskyi[199]	Sp. nov	Valid	Gutiérrez & Balarino	Carboniferous (Pennsylvanian)	Ordóñez Formation	Argentina	A spore taxon.
Schizoneura cucumis[196]	Sp. nov	Valid	Anderson & Anderson	Late Triassic (Carnian)	Molteno Formation	South Africa	A member of Equisetopsida belonging to the group Echinostachyales and the family Echinostachyaceae.
Schizoneura koningensis[196]	Sp. nov	Valid	Anderson & Anderson	Late Triassic (Carnian)	Molteno Formation	South Africa	A member of Equisetopsida belonging to the group Echinostachyales and the family Echinostachyaceae.
Scleropteris iljiniana[171]	Sp. nov	Valid	Kiritchkova, Kostina & Nosova	Jurassic		Russia
Sichuania[198]	Gen. et sp. nov	Valid	Edwards & Li	Early Devonian	Pingyipu Group	China	A zosterophyll. Genus includes new species S. uskielloides.
Sphenophyllum changxingense[231]	Sp. nov	Valid	Huang et al.	Late Devonian	Wutong Formation	China
Suppiluliumaella tarburensis[232]	Sp. nov	Valid	Rashidi & Schlagintweit	Late Cretaceous (Maastrichtian)	Tarbur Formation	Iran	A green alga belonging to the group Dasycladales.
Tauridium elongatum[233]	Sp. nov	In press	Jia & Song	Late Permian	Changxing Formation	China	A member of Gymnocodiaceae.
Taurocusporites inaequalis[154]	Sp. nov	Valid	Perez Loinaze & Llorens	Early Cretaceous (Aptian)	Anfiteatro de Ticó Formation	Argentina	A spore taxon with affinities with the Bryophyta sensu lato.
Tempskya zhangii[234]	Sp. nov	Valid	Xiaonan, Fengxiang & Yeming	Cretaceous		China	A tree fern
Tiaomaphyton[235]	Gen. et sp. nov	Valid	Xu, Fu & Wang	Middle Devonian	Tiaomachian Formation	China	A Colpodexylon-like lycopsid. Genus includes new species T. fui.
Townroviamites multifoliata[196]	Sp. nov	Valid	Anderson & Anderson	Late Triassic (Carnian)	Molteno Formation	South Africa	A member of Equisetopsida belonging to the group Equisetales and the family Equisetaceae.
Townroviamites petfredae[196]	Sp. nov	Valid	Anderson & Anderson	Late Triassic (Carnian)	Molteno Formation	South Africa	A member of Equisetopsida belonging to the group Equisetales and the family Equisetaceae.
Townroviamites stellata[196]	Sp. nov	Valid	Anderson & Anderson	Late Triassic (Carnian)	Molteno Formation	South Africa	A member of Equisetopsida belonging to the group Equisetales and the family Equisetaceae.
Tricarinella[236]	Gen. et sp. nov	Valid	Savoretti et al.	Early Cretaceous (Valanginian)		Canada ( British Columbia)	A moss belonging to the family Grimmiaceae. Genus includes new species T. crassiphylla.
Verrucatotriletes laesuraverrucatus[85]	Sp. nov	In press	D'Apolito et al.	Pliocene–Pleistocene		Brazil	Fossil spore.
Verrucatotriletes tortus[85]	Sp. nov	In press	D'Apolito et al.	Pliocene–Pleistocene		Brazil	Fossil spore.
Viridistachys[196]	Gen. et 2 sp. nov	Valid	Anderson & Anderson	Late Triassic (Carnian)	Molteno Formation	South Africa	A member of Equisetopsida belonging to the group Equisetales and the family Equisetaceae. Genus includes new species V. moltenensis and V. gypsensis.
Zonulamites annumensis[196]	Sp. nov	Valid	Anderson & Anderson	Late Triassic (Carnian)	Molteno Formation	South Africa	A member of Equisetopsida belonging to the group Equisetales and the family Equisetaceae.
Zonulamites collensis[196]	Sp. nov	Valid	Anderson & Anderson	Late Triassic (Carnian)	Molteno Formation	South Africa	A member of Equisetopsida belonging to the group Equisetales and the family Equisetaceae.
Zonulamites elandensis[196]	Sp. nov	Valid	Anderson & Anderson	Late Triassic (Carnian)	Molteno Formation	South Africa	A member of Equisetopsida belonging to the group Equisetales and the family Equisetaceae.
Zonulamites viridensis[196]	Sp. nov	Valid	Anderson & Anderson	Late Triassic (Carnian)	Molteno Formation	South Africa	A member of Equisetopsida belonging to the group Equisetales and the family Equisetaceae.
Zosterophyllum ovatum[192]	Sp. nov	Valid	Edwards & Li	Early Devonian	Pingyipu Group	China

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95. Vandana Prasad; Anjum Farooqui; Srikanta Murthy; Omprakash S. Sarate; Sunil Bajpai (2018). "Palynological assemblage from the Deccan Volcanic Province, central India: Insights into early history of angiosperms and the terminal Cretaceous paleogeography of peninsular India". Cretaceous Research. 86: 186–198. doi:10.1016/j.cretres.2018.03.004.
96. Hongshan Wang; David L. Dilcher (2018). "A new species of Donlesia (Ceratophyllaceae) from the Early Cretaceous of Kansas, USA". Review of Palaeobotany and Palynology. 252: 20–28. doi:10.1016/j.revpalbo.2018.02.002.
97. Brian A. Atkinson; Ruth A. Stockey; Gar W. Rothwell (2018). "Tracking the initial diversification of asterids: anatomically preserved cornalean fruits from the early Coniacian (Late Cretaceous) of western North America". International Journal of Plant Sciences. 179 (1): 21–35. doi:10.1086/695339.
98. Rashmi Srivastava; Regis B. Miller; Pieter Baas (2018). "More Malpighiales: Woods of Achariaceae and/or Salicaceae from the Deccan Intertrappean Beds, India". Journal of Systematics and Evolution. in press. doi:10.1111/jse.12455.
99. George O. Poinar Jr.; Kenton L. Chambers (2018). "Endobeuthos paleosum gen. et sp. nov., fossil flowers of uncertain affinity from mid-Cretaceous Myanmar amber". Journal of the Botanical Research Institute of Texas. 12 (1): 133–139.
100. Jian Huang; Tao Su; Lin-Bo Jia; Zhe-Kun Zhou (2018). "A fossil fig from the Miocene of southwestern China: Indication of persistent deep time karst vegetation". Review of Palaeobotany and Palynology. 258: 133–145. doi:10.1016/j.revpalbo.2018.07.005.
101. Zixi Wang; Fankai Sun; Sanping Xie; Jidong Wang; Yijie Li; Junling Dong; Mingxuan Sun; Bainian Sun (2018). "A new species of Garcinia (Clusiaceae) from the middle Miocene of Fujian, China, and a phytogeographic analysis". Geological Journal. in press. doi:10.1002/gj.3228.
102. Anumeha Shukla; R.C. Mehrotra; Sheikh Nawaz Ali (2018). "Early Eocene leaves of northwestern India and their response to climate change". Journal of Asian Earth Sciences. in press. doi:10.1016/j.jseaes.2018.07.035.
103. Else Marie Friis; Peter R. Crane; Kaj Raunsgaard Pedersen (2018). "Extinct taxa of exotestal seeds close to Austrobaileyales and Nymphaeales from the Early Cretaceous of Portugal" (PDF). Fossil Imprint. 74 (1–2): 135–158. doi:10.2478/if-2018-0010.
104. Ye-Ming Cheng; Xiao-Nan Yang; Zhe-Feng He; Bing Mao; Ya-Fang Yin (2018). "Early Miocene angiosperm woods from Sihong in the Jiangsu Province, Eastern China". IAWA Journal. 39 (1): 125–142. doi:10.1163/22941932-20170189.
105. Maria de Jesus Hernandez-Hernández; Carlos Castañeda-Posadas (2018). "Gouania miocenica sp. nov. (Rhamnaceae), a Miocene fossil from Chiapas, México and paleobiological involvement". Journal of South American Earth Sciences. 85: 1–5. doi:10.1016/j.jsames.2018.04.018.
106. Tao Su; Shu-Feng Li; He Tang; Yong-Jiang Huang; Shi-Hu Li; Cheng-Long Deng; Zhe-Kun Zhou (2018). "Hemitrapa Miki (Lythraceae) from the earliest Oligocene of southeastern Qinghai-Tibetan Plateau and its phytogeographic implications". Review of Palaeobotany and Palynology. 257: 57–63. doi:10.1016/j.revpalbo.2018.06.001.
107. Gaurav Srivastava; Rakesh C. Mehrotra; David L. Dilcher (2018). "Paleocene Ipomoea (Convolvulaceae) from India with implications for an East Gondwana origin of Convolvulaceae". Proceedings of the National Academy of Sciences of the United States of America. 115 (23): 6028–6033. doi:10.1073/pnas.1800626115. PMC 6003353. PMID 29784796.
108. Rafał Kowalski; Elżbieta Worobiec (2018). "Revision of Comarostaphylis globula (Ericaceae) from Cenozoic of Central Europe". Review of Palaeobotany and Palynology. 254: 20–32. doi:10.1016/j.revpalbo.2018.04.009.
109. Hui Jiang; Tao Su; William Oki Wong; Feixiang Wu; Jian Huang; Gongle Shi (2018). "Oligocene Koelreuteria (Sapindaceae) from the Lunpola Basin in central Tibet and its implication for early diversification of the genus". Journal of Asian Earth Sciences. in press. doi:10.1016/j.jseaes.2018.01.014.
110. Else Marie Friis; Peter R. Crane; Kaj Raunsgaard Pedersen (2018). "Rightcania and Kvacekispermum: Early Cretaceous seeds from eastern North America and Portugal provide further evidence of the early chloranthoid diversification" (PDF). Fossil Imprint. 74 (1–2): 65–76. doi:10.2478/if-2018-0006.
111. Nathan A. Jud; Maria A. Gandolfo; Ari Iglesias; Peter Wilf (2018). "Fossil flowers from the early Palaeocene of Patagonia, Argentina, with affinity to Schizomerieae (Cunoniaceae)". Annals of Botany. 121 (3): 431–442. doi:10.1093/aob/mcx173. PMC 5838809. PMID 29309506.
112. Emilio Estrada-Ruiz; Elisabeth A. Wheeler; Garland R. Upchurch Jr.; Greg H. Mack (2018). "Late Cretaceous angiosperm woods from the McRae Formation, south-central New Mexico, USA: Part 2". International Journal of Plant Sciences. 179 (2): 136–150. doi:10.1086/695503.
113. Zixi Wang; Fankai Sun; Jidong Wang; Defei Yan; Junling Dong; Mingxuan Sun; Bainian Sun (2018). "New fossil leaves and fruits of Lauraceae from the Middle Miocene of Fujian, southeastern China differentiated using a cluster analysis". Historical Biology: An International Journal of Paleobiology. in press. doi:10.1080/08912963.2017.1379517.
114. Camila Martínez; María A. Gandolfo; N. Rubén Cúneo (2018). "Angiosperm leaves and cuticles from the uppermost Cretaceous of Patagonia, biogeographic implications and atmospheric paleo-CO₂ estimates". Cretaceous Research. 89: 107–118. doi:10.1016/j.cretres.2018.03.015.
115. Atsushi Yabe; Tomio Nakagawa (2018). "A new legume fruit species from the mid-Miocene Climatic Optimum in Japan". Review of Palaeobotany and Palynology. 257: 35–42. doi:10.1016/j.revpalbo.2018.06.006.
116. Junling Dong; Bainian Sun; Teng Mao; Defei Yan; Chunhui Liu; Zixi Wang; Peihong Jin (2018). "Liquidambar (Altingiaceae) and associated insect herbivory from the Miocene of southeastern China". Palaeogeography, Palaeoclimatology, Palaeoecology. 497: 11–24. doi:10.1016/j.palaeo.2018.02.001.
117. Lu-Liang Huang; Jin Sun; Jian-Hua Jin; Cheng Quan; Alexei A. Oskolski (2018). "Litseoxylon gen. nov. (Lauraceae): The most ancient fossil angiosperm wood with helical thickenings from southeastern Asia". Review of Palaeobotany and Palynology. in press. doi:10.1016/j.revpalbo.2018.08.006.
118. Camila Martínez (2018). "Dalbergieae (Fabaceae) samara fruits from the Late Eocene of Colombia". International Journal of Plant Sciences. 179 (7): 541–553. doi:10.1086/698937.
119. María Jimena Franco (2018). "Small Celastraceae and Polygonaceae twigs from the Upper Cenozoic (Ituzaingó Formation) of the La Plata Basin, Argentina". Historical Biology: An International Journal of Paleobiology. 30 (5): 646–660. doi:10.1080/08912963.2017.1313840.
120. Nathan A. Jud; Ari Iglesias; Peter Wilf; Maria A. Gandolfo (2018). "Fossil moonseeds from the Paleogene of West Gondwana (Patagonia, Argentina)". American Journal of Botany. 105 (5): 927–942. doi:10.1002/ajb2.1092. PMID 29882954.
121. Fei Liang; Ge Sun; Tao Yang; Shuchong Bai (2018). "Nelumbo jiayinensis sp. nov. from the Upper Cretaceous Yong'ancun Formation, Heilongjiang, Northeast China". Cretaceous Research. 84: 134–140. doi:10.1016/j.cretres.2017.11.007.
122. Zhongjian Liu; Xin Wang (2018). "A novel angiosperm from the Early Cretaceous and its implications for carpel-deriving". Acta Geologica Sinica (English Edition). 92 (4): 1293–1298. doi:10.1111/1755-6724.13627.
123. Else Marie Friis; Peter R. Crane; Kaj R. Pedersen (2018). "Fossil seeds with affinities to Austrobaileyales and Nymphaeales from the Early Cretaceous (early to middle Albian) of Virginia and Maryland, USA: new evidence for extensive extinction near the base of the angiosperm tree". In Michael Krings; Carla J. Harper; Néstor Rubén Cúneo; Gar W. Rothwell (eds.). Transformative paleobotany. Papers to commemorate the life and legacy of Thomas N. Taylor. Academic Press. pp. 417–435. doi:10.1016/B978-0-12-813012-4.00017-6. ISBN 978-01-281-3012-4.
124. Else Marie Friis; Mário Miguel Mendes; Kaj Raunsgaard Pedersen (2018). "Paisia, an Early Cretaceous eudicot angiosperm flower with pantoporate pollen from Portugal". Grana. 57 (1–2): 1–15. doi:10.1080/00173134.2017.1310292.
125. Kathleen B. Pigg; Finley A. Bryan; Melanie L. DeVore (2018). "Paleoallium billgenseli gen. et sp. nov.: fossil monocot remains from the latest Early Eocene Republic Flora, northeastern Washington State, USA". International Journal of Plant Sciences. 179 (6): 477–486. doi:10.1086/697898.
126. Jun-Ling Dong; Bai-Nian Sun; Teng Mao; Pei-Hong Jin; Yi-Jie Li; Ji-Dong Wang; Zi-Xi Wang (2018). "New materials of Rhamnaceae from the middle Miocene rainforest of Southeast China". Review of Palaeobotany and Palynology. in press. doi:10.1016/j.revpalbo.2018.09.004.
127. Samar Nour-El-Deen; Romain Thomas; Wagieh El-Saadawi (2018). "First record of fossil Trachycarpeae in Africa: three new species of Palmoxylon from the Oligocene (Rupelian) Gebel Qatrani Formation, Fayum, Egypt". Journal of Systematic Palaeontology. 16 (9): 741–766. doi:10.1080/14772019.2017.1343258.
128. Eliana Moya; Mariana Brea; Alicia I. Lutz (2018). "Redescription and reassignment of the fossil wood Menendoxylon piptadiensis from the Pliocene Andalhuala Formation, South America". Journal of Systematic Palaeontology. 16 (13): 1145–1157. doi:10.1080/14772019.2017.1386727.
129. Ünal Akkemik; Gökhan Atıcı; Imogen Poole; Mehmet Çobankaya (2018). "Three new silicified woods from a newly discovered earliest Miocene forest site in the Haymana Basin (Ankara, Turkey)". Review of Palaeobotany and Palynology. 254: 49–64. doi:10.1016/j.revpalbo.2018.04.012.
130. Gaurav Srivastava; R. C. Mehrotra; C. Srikarni (2018). "Fossil wood flora from the Siwalik Group of Arunachal Pradesh, India and its climatic and phytogeographic significance". Journal of Earth System Science. 127 (1): Article 2. doi:10.1007/s12040-017-0903-2.
131. Dmitry D. Sokoloff; Michael S. Ignatov; Margarita V. Remizowa; Maxim S. Nuraliev; Vladimir Blagoderov; Amin Garbout; Evgeny E. Perkovsky (2018). "Staminate flower of Prunus s. l. (Rosaceae) from Eocene Rovno amber (Ukraine)". Journal of Plant Research. in press. doi:10.1007/s10265-018-1057-2. PMID 30032395.
132. Steven R. Manchester; Behnaz Balmaki (2018). "Spiny fruits revealed by nano-CT scanning: Pseudoanacardium peruvianum (Berry) gen. et comb. nov. from the early Oligocene Belén flora of Peru". Acta Palaeobotanica. 58 (1): 41–48. doi:10.2478/acpa-2018-0005.
133. Friðgeir Grímsson; Guido W. Grimm; Alastair J. Potts; Reinhard Zetter; Susanne S. Renner (2018). "A Winteraceae pollen tetrad from the early Paleocene of western Greenland, and the fossil record of Winteraceae in Laurasia and Gondwana". Journal of Biogeography. 45 (3): 567–581. doi:10.1111/jbi.13154.
134. Xiao‐Yan Liu; Sheng‐Lan Xu; Meng Han; Jian‐Hua Jin (2018). "An early Oligocene fossil acorn, associated leaves and pollen of the ring‐cupped oaks (Quercus subg. Cyclobalanopsis) from Maoming Basin, South China". Journal of Systematics and Evolution. in press. doi:10.1111/jse.12450.
135. John G. Conran; Elizabeth M. Kennedy; Jennifer M. Bannister (2018). "Early Eocene Ripogonaceae leaf macrofossils from New Zealand". Australian Systematic Botany. 31 (1): 8–15. doi:10.1071/SB17016.
136. A.L. Hernández-Damián; S.L. Gómez-Acevedo; S.R.S. Cevallos-Ferriz (2018). "Fossil flower of Salacia lombardii sp. nov. (Salacioideae-Celastraceae) preserved in amber from Simojovel de Allende, Mexico". Review of Palaeobotany and Palynology. 252: 1–9. doi:10.1016/j.revpalbo.2018.02.003.
137. Sandip More; Rajarshi Rit; Mahasin Ali Khan; Dipak Kumar Paruya; Suchana Taral; Tapan Chakraborty; Subir Bera (2018). "Record of leaf and pollen cf. Sloanea (Elaeocarpaceae) from the Middle Siwalik of Darjeeling sub-Himalaya, India and its palaeobiogeographic implications". Journal of the Geological Society of India. 91 (3): 301–306. doi:10.1007/s12594-018-0854-5.
138. Maria A. Gandolfo; Kevin C. Nixon; William L. Crepet; David A. Grimaldi (2018). "A late Cretaceous fagalean inflorescence preserved in amber from New Jersey". American Journal of Botany. 105 (8): 1424–1435. doi:10.1002/ajb2.1103. PMID 29901855.
139. Yongjiang Huang; Arata Momohara; Yuqing Wang (2018). "Selective extinction within a Tertiary relict genus in the Japanese Pleistocene explained by climate cooling and species-specific cold tolerance". Review of Palaeobotany and Palynology. 258: 1–12. doi:10.1016/j.revpalbo.2018.06.009.
140. Meng Han; Steven R. Manchester; Qiong-Yao Fu; Jian-Hua Jin; Cheng Quan (2018). "Paleogene fossil fruits of Stephania (Menispermaceae) from North America and East Asia". Journal of Systematics and Evolution. 56 (2): 81–91. doi:10.1111/jse.12288.
141. Else Marie Friis; Peter R. Crane; Kaj Raunsgaard Pedersen (2018). "Tanispermum, a new genus of hemi‐orthotropous to hemi‐anatropous angiosperm seeds from the Early Cretaceous of eastern North America". American Journal of Botany. 105 (8): 1369–1388. doi:10.1002/ajb2.1124. PMID 30080239.
142. William L. Crepet; Kevin C. Nixon; Andrea Weeks (2018). "Mid‐Cretaceous angiosperm radiation and an asterid origin of bilaterality: diverse and extinct "Ericales" from New Jersey". American Journal of Botany. 105 (8): 1412–1423. doi:10.1002/ajb2.1131. PMID 30075046.
143. N. I. Blokhina; O. V. Bondarenko (2018). "Fossil wood of Ulmus priamurica sp. nov. (Ulmaceae) from the Miocene of the Erkovetskii Brown Coal Field, Amur Region, Russia". Paleontological Journal. 52 (2): 208–218. doi:10.1134/S003103011802003X.
144. Xiao-Qing Liang; Ping Lu; Jian-Wei Zhang; Tao Su; Zhe-Kun Zhou (2018). "First fossils of Zygogynum from the Middle Miocene of Central Yunnan, Southwest China, and their palaeobiogeographic significance". Palaeoworld. 27 (3): 399–409. doi:10.1016/j.palwor.2018.05.003.
145. Ignacio H. Escapa; Ari Iglesias; Peter Wilf; Santiago A. Catalano; Marcos A. Caraballo‐Ortiz; N. Rubén Cúneo (2018). "Agathis trees of Patagonia's Cretaceous‐Paleogene death landscapes and their evolutionary significance". American Journal of Botany. 105 (8): 1345–1368. doi:10.1002/ajb2.1127. PMID 30074620.
146. M. Philippe; M. Rioult; J.-Ph. Rioult; F. Thévenard (2018). "A reappraisal of Lignier's Mesozoic fossil wood collection: Ages, nomenclature and taxonomy". Review of Palaeobotany and Palynology. 252: 10–19. doi:10.1016/j.revpalbo.2018.02.001.
147. Adriana C. Kloster; Silvia C. Gnaedinger (2018). "Coniferous wood of Agathoxylon from the La Matilde Formation, (Middle Jurassic), Santa Cruz, Argentina". Journal of Paleontology. 92 (4): 546–567. doi:10.1017/jpa.2017.145.
148. Gongle Shi; Haomin Li; Andrew B. Leslie; Zhiyan Zhou (2018). "Araucaria bract-scale complex and associated foliage from the early-middle Eocene of Antarctica and their implications for Gondwanan biogeography". Historical Biology: An International Journal of Paleobiology. in press. doi:10.1080/08912963.2018.1472255.
149. Ana Andruchow‐Colombo; Ignacio H. Escapa; N. Rubén Cúneo; María A. Gandolfo (2018). "Araucaria lefipanensis (Araucariaceae), a new species with dimorphic leaves from the Late Cretaceous of Patagonia, Argentina". American Journal of Botany. 105 (6): 1067–1087. doi:10.1002/ajb2.1113. PMID 29995329.
150. Rafael Souza Faria; Fresia Ricardi-Branco; Rosemarie Rohn; Marcelo Adorna Fernandes; Isabel Christiano-De-Souza (2018). "Permian woods with preserved primary structures from the southeast of Brazil (Irati Formation, Paraná basin)". Palaeobiodiversity and Palaeoenvironments. 98 (3): 385–401. doi:10.1007/s12549-018-0320-9.
151. Brian A. Atkinson; Rudolph Serbet; Timothy J. Hieger; Edith L. Taylor (2018). "Additional evidence for the Mesozoic diversification of conifers: Pollen cone of Chimaerostrobus minutus gen. et sp. nov. (Coniferales), from the Lower Jurassic of Antarctica". Review of Palaeobotany and Palynology. 257: 77–84. doi:10.1016/j.revpalbo.2018.06.013.
152. Wen-Na Ding; Lutz Kunzmann; Tao Su; Jian Huang; Zhe-Kun Zhou (2018). "A new fossil species of Cryptomeria (Cupressaceae) from the Rupelian of the Lühe Basin, Yunnan, East Asia: Implications for palaeobiogeography and palaeoecology". Review of Palaeobotany and Palynology. 248: 41–51. doi:10.1016/j.revpalbo.2017.09.003.
153. Tatiana Kodrul; Natalia Gordenko; Aleksandra Sokolova; Natalia Maslova; Xinkai Wu; Jianhua Jin (2018). "A new Oligocene species of Cunninghamia R. Brown ex Richard et A. Richard (Cupressaceae) from the Maoming Basin, South China". Review of Palaeobotany and Palynology. in press. doi:10.1016/j.revpalbo.2018.09.003.
154. Valeria S. Perez Loinaze; Magdalena Llorens (2018). "Palynology of the Baqueró Group (upper Aptian), Patagonia Argentina: An integrated study". Cretaceous Research. 86: 219–237. doi:10.1016/j.cretres.2018.02.004.
155. Pei-Hong Jin; Jun-Ling Dong; Zi-Xi Wang; Xiu-Cai Yuan; Yi-Fan Hua; Bao-Xia Du; Bai-Nian Sun (2018). "A new species of Elatides from the Lower Cretaceous in Shandong province, Eastern China and its geographic significance". Cretaceous Research. 85: 109–127. doi:10.1016/j.cretres.2017.11.022.
156. Amit K. Ghosh; Ratan Kar; Reshmi Chatterjee; Arindam Chakraborty; Jayasri Banerji (2018). "Two new conifers from the Early Cretaceous of the Rajmahal Basin, India: implications on palaeoecology and palaeogeography". Ameghiniana. in press. doi:10.5710/AMGH.17.02.2018.3124.
157. Ruth A. Stockey; Nicholas J. P. Wiebe; Brian A. Atkinson; Gar W. Rothwell (2018). "Cupressaceous pollen cones from the Early Cretaceous of Vancouver Island, British Columbia: Morinostrobus holbergensis gen. et sp. nov". International Journal of Plant Sciences. 179 (5): 402–414. doi:10.1086/697728.
158. Mahasin Ali Khan; Subir Bera (2018). "Pinus daflaensis (Pinaceae), a replacement name for P. arunachalensis Khan & Bera". Phytotaxa. 334 (2): 200. doi:10.11646/phytotaxa.334.2.9.
159. Alexander B. Doweld (2018). "New names of fossil Pinus and Pinuspollenites (Pinaceae) of Northern Eurasia". The Journal of Japanese Botany. 93 (3): 215–219.
160. Peng-Cheng An; De-Liang Tang; Hui Chen; Qian Yang; Su-Ting Ding; Jing-Yu Wu (2018). "Pliocene white pine (Pinus subgenus Strobus) needles from western Yunnan, southwestern China". Historical Biology: An International Journal of Paleobiology. in press. doi:10.1080/08912963.2018.1461216.
161. Wenlong He; Liang Xiao; Xiangchuan Li; Shuangxing Guo (2018). "An ancient example of Platycladus (Cupressceae) from the early Miocene of northern China: origin and biogeographical implications". Historical Biology: An International Journal of Paleobiology. in press. doi:10.1080/08912963.2017.1339038.
162. Chris Mays; David J. Cantrill (2018). "Protodammara reimatamoriori, a new species of conifer (Cupressaceae) from the Upper Cretaceous Tupuangi Formation, Chatham Islands, Zealandia". Alcheringa: An Australasian Journal of Palaeontology. in press. doi:10.1080/03115518.2017.1417478.
163. Maria Edenilce P. Batista; Lutz Kunzmann; Francisco Irineudo Bezerra; José Artur F.G. de Andrade; Artur A. Sá; Maria Iracema B. Loiola (2018). "A new cheirolepidiaceous conifer Pseudofrenelopsis salesii sp. nov. from the Early Cretaceous of Brazil (Romualdo Formation, Araripe Basin): Paleoecological and taphonomic significance". Review of Palaeobotany and Palynology. 258: 154–162. doi:10.1016/j.revpalbo.2018.08.002.
164. Jiří Kvaček; Eduardo Barrón; Zuzana Heřmanová; Mário Miguel Mendes; Jakub Karch; Jan Žemlička; Jan Dudák (2018). "Araucarian conifer from late Albian amber of northern Spain". Papers in Palaeontology. in press. doi:10.1002/spp2.1223.
165. Long Li; Jian-Hua Jin; Steven R. Manchester (2018). "Cupressaceae fossil remains from the Paleocene of Carneyville, Wyoming". Review of Palaeobotany and Palynology. 251: 1–13. doi:10.1016/j.revpalbo.2017.12.003.
166. Ning Tian; Zhipeng Zhu; Yongdong Wang; Marc Philippe; Chunyong Chou; Aowei Xie (2018). "Sequoioxylon zhangii sp. nov. (Sequoioideae, Cupressaceae s.l.), a new coniferous wood from the Upper Cretaceous in Heilongjiang Province, Northeastern China". Review of Palaeobotany and Palynology. 257: 85–94. doi:10.1016/j.revpalbo.2018.07.008.
167. Xiao Tan; David L. Dilcher; Hongshan Wang; Yi Zhang; Yu-Ling Na; Tao Li; Yun-Feng Li; Chun-Lin Sun (2018). "Yanliaoa, an extinct genus of Cupressaceae s. l. from the Middle Jurassic, northeastern China". Palaeoworld. 27 (3): 360–373. doi:10.1016/j.palwor.2018.03.001.
168. Le Liu; De-Ming Wang; Mei-Cen Meng; Pu Huang; Jin-Zhuang Xue (2018). "A new seed plant with multi-ovulate cupules from the Upper Devonian of South China". Review of Palaeobotany and Palynology. 249: 80–86. doi:10.1016/j.revpalbo.2017.11.006.
169. Zbyněk Šimůnek (2018). "Cuticular analysis of new Westphalian and Stephanian Cordaites species from the USA". Review of Palaeobotany and Palynology. 253: 1–14. doi:10.1016/j.revpalbo.2018.03.001.
170. Stephen McLoughlin; Christian Pott; Ian H. Sobbe (2018). "The diversity of Australian Mesozoic bennettitopsid reproductive organs". Palaeobiodiversity and Palaeoenvironments. 98 (1): 71–95. doi:10.1007/s12549-017-0286-z.
171. À.I Kiritchkova; E.I. Kostina; N.V. Nosova (2018). "Jurassic flora of the Irkutsk coal basin". Botanical Journal. 103 (1): 36–63.
172. Pedro Correia; Zbynĕk Šimůnek; Christopher J. Cleal; Artur A. Sá (2018). "Douropteris alvarezii gen. nov., sp. nov., a new medullosalean pteridosperm from the Late Pennsylvanian of Portugal". Geological Journal. in press. doi:10.1002/gj.3251.
173. Yong Yang; Longbiao Lin; David K. Ferguson; Yingwei Wang (2018). "Macrofossil evidence unveiling evolution of male cones in Ephedraceae (Gnetidae)". BMC Evolutionary Biology. 18: 125. doi:10.1186/s12862-018-1243-9. PMID 30157769.
174. Yun-Feng Li; Chun-Lin Sun; Hongshan Wang; David L. Dilcher; Xiao Tan; Tao Li; Yu-Ling Na (2018). "First record of Eretmophyllum (Ginkgoales) with well-preserved cuticle from the Middle Jurassic of the Ordos Basin, Inner Mongolia, China". Palaeoworld. 27 (2): 188–201. doi:10.1016/j.palwor.2017.09.002.
175. Zixi Wang; Bainian Sun; Fankai Sun; Conghui Xiong; Yingquan Chen; Xuelian Wang (2018). "Microstructure and significance of cordaitean reproductive organs from the lower Permian of Gansu, Northwest China". Journal of Asian Earth Sciences. 158: 49–64. doi:10.1016/j.jseaes.2018.02.016.
176. Ana María Zavattieri; Pedro Raúl Gutiérrez; Miguel Ezpeleta (2018). "Gymnosperm pollen grains from the La Veteada Formation (Lopingian), Paganzo Basin, Argentina: biostratigraphic and palaeoecological implications". Alcheringa: An Australasian Journal of Palaeontology. 42 (2): 276–299. doi:10.1080/03115518.2017.1410571.
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178. Yi Zhao; Yuanzheng Lu; Ping Shang; Shenghui Deng; Xunlian Wang (2018). "An amended species, Nilssoniopteris neimenguensis nom. nov., from the Lower Jurassic of the Xilinhot Basin, Inner Mongolia, northern China, with a reexamination of Nilssoniopteris species". Review of Palaeobotany and Palynology. 255: 22–34. doi:10.1016/j.revpalbo.2018.04.013.
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