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  • 1995-1999  (18)
  • 1990-1994  (13)
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  • 1
    Electronic Resource
    Electronic Resource
    Environmental control of pollen grain distribution patterns in the Gulf of Guinea and offshore NW-Africa (1991)
    Springer
    International journal of earth sciences 80 (1991), S. 567-589 
    Details
    ISSN: 1437-3262
    Source: Springer Online Journal Archives 1860-2000
    Topics: Geosciences
    Description / Table of Contents: Abstract The areas of marine pollen deposition are related to the pollen source areas by aeolian and fluvial transport regimes, whereas wind transport is much more important than river transport. Pollen distribution patterns ofPinus, Artemisia, Chenopodiaceae-Amaranthaceae, and Asteraceae Tubuliflorae trace atmospheric transport by the northeast trades. Pollen transport by the African Easterly Jet is reflected in the pollen distribution patterns of Chenopodiaceae-Amaranthaceae, Asteraceae Tubuliflorae, andMitracarpus. Grass pollen distribution registers the latitudinal extension of Sahel, savannas and dry open forests. Marine pollen distribution patterns of Combretaceae-Melastomataceae,Alchornea, andElaeis reflect the extension of wooded grasslands and transitional forests. Pollen from the Guinean-Congolian/Zambezian forest and from the Sudanian/Guinean vegetation zones mark the northernmost extension of the tropical rain forest.Rhizophora pollen in marine sediments traces the distribution of mangrove swamps. Only near the continent, pollen ofRhizophora, Mitracarpus, Chenopodiaceae-Amaranthaceae, and pollen from the Sudanian and Guinean vegetation zones are transported by the Upwelling Under Current and the Equatorial Under Current, where those currents act as bottom currents. The distribution of pollen in marine sediments, reflecting the position of major climatic zones (desert, dry tropics, humid tropics), can be used in tracing climatic changes in the past.
    Abstract: Résumé Les aires marines dans lesquelles se déposent les pollens sont en relation avec les aires continentales nourricières par l'intermédiaire des régimes de transport fluviatile et éolien, ce dernier jouant le rôle prépondérant. La distribution pollinique dePinus, Artenisia, des Chenopodiaceae-Amaranthaceae et Asteraceae-Tuliliflorae reflète un transport aérien du nord-est. Le transport pollinique par l'African Easterly Jet se traduit dans la distribution pollinique des Chenopodiaceae-Amaranthaceae, des Asteraceae-Tubuliflorae et deMitrocarpus. La distribution des pollens de graminées enregistre l'extension en latitude du Sahel, de la savane et de la forêt claire. La distribution dans la mer des pollens de Combretaceae-Melastomatoceae, d'Alchornea et d'Elaeis traduit l'extension des savanes boisées et des forêts de transition. Les pollens provenant de la forêt guinéennecongolaise-zambésienne et des zones végétales du Soudan et de Guinée marquent la limite septentrionale de la forêt humide tropicale. Les pollens deRhizophora dans les sédiments marins dessinent la distribution des mangroves. Ce n'est qu'à proximité du continent que les pollen deRizophora, deMitracarpus, des Chenopodiceae-Amaranthaceae ainsi que les pollens originaires des zones végétales du Soudan et de Guinée sont transportés par l'«Upwelling Under Current» et l'«Equatorial Under Current», qui se comportent là comme courants de fond. La distribution des pollens dans les sédiments marins, reflétant la position des zones climatiques principales (désertique, tropicale sèche, tropicale humide) peut être utilisée dans les reconstitutions paléoclimatiques.
    Notes: Zusammenfassung Vor der afrikanischen Küste zwischen Marokko und Kamerun gelangen Pollenkörner in die marinen Sedimente, die durch Wind oder mit dem Wasser von Flüssen herantransportiert worden sind. Dabei hat Windtransport eine größere Bedeutung als Flußtransport. Durch die Häufigkeit und Verbreitung der Pollenkörner (Isopollenkarten) vonPinus, Artemisia, Chenopodiaceae/Amaranthaceae und den Asteraceae Tubuliflorae in den marinen Sedimenten wird gezeigt, daß der Transport in diesen Fällen durch den Nordost-Passat erfolgt und daß seine Transportleistung sehr groß ist. Die Transportwirkung des African Easterly Jet wird aus den Isopollenkarten für Chenopodiaceae/Amaranthaceae, Asteraceae Tubuliflorae undMitracarpus abgeleitet. Die Häufigkeit des Pollens von Gräsern hält sich eng an die Grenzen der Sahel-Zone, der Savannen sowie der offenen Trockenwälder und kann deswegen als Zeiger für die Lage dieser Vegetations- und Klimazonen verwendet werden. Die Lage der baumreichen Savannen und der Wälder im Übergang zum tropischen Regenwald spiegelt sich in der Häufigkeit der Pollenanteile von Combretaceae/Melastomataceae,Alchornea undElaeis wider. Die Nordgrenze tropischer Regenwälder kommt in den Isopollenkarten für die Häufigkeit der Arten guineisch-kongolesischer Baumarten sowie der Pflanzen der sudanischen und guineischen Vegetationszonen zum Ausdruck. Für die Verbreitung von Mangroven werden die Pollenanteile vonRhizophora herangezogen. Nahe der Küste kann der Pollen vonRhizophora, Mitracarpus, Chenopodiaceae/Amaranthaceae und von Arten der sudanischen und guineischen Vegetationszonen auch mit dem »Upwelling Under Current« und dem »Equatorial Under Current« transportiert werden, sofern diese als Bodenströme auftreten. Die Ergebnisse zeigen, daß die Verteilung der Pollenkörner in marinen Sedimenten die Lage der wichtigsten Klimazonen (Wüsten, trockene und feuchte Tropen) widergibt und deswegen für paläoklimatische Untersuchungen angewendet werden kann.
    Type of Medium: Electronic Resource
    URL: http://dx.doi.org/10.1007/BF01803687
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  • 2
    Electronic Resource
    Electronic Resource
    Latitudinal shifts of forest and savanna in N. W. Africa during the Brunhes chron: further marine palynological results from site M 16415 (9°;N 19°W) (1992)
    Springer
    Vegetation history and archaeobotany 1 (1992), S. 163-175 
    Details
    ISSN: 1617-6278
    Keywords: Marine palynology ; Tropical rain forest ; North-west Africa ; Brunhes chron
    Source: Springer Online Journal Archives 1860-2000
    Topics: Archaeology , Biology
    Notes: Abstract Palynological data of the marine core M 16415-2 show latitudinal shifts of the northern fringe of the tropical rain forest in north-west Africa during the last 700 ka. Savanna and dry open forest expanded southwards and tropical rain forest expanded northwards during dry and humid periods, respectively. Until 220 ka B.P., the tropical rain forest probably kept its zonal character in West Africa during glacials and interglacials. It is only during the last two glacial periods that the rain forest possibly fragmented into refugia. Throughout the Brunhes chron, pollen and spore transport was mainly by trade winds.
    Type of Medium: Electronic Resource
    URL: http://dx.doi.org/10.1007/BF00191556
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  • 3
    Electronic Resource
    Electronic Resource
    Vegetation and climatic history of southwest Africa: A marine palynological record of the last 300,000 years (1997)
    Springer
    Vegetation history and archaeobotany 6 (1997), S. 117-131 
    Details
    ISSN: 1617-6278
    Keywords: Marine palynology ; Vegetation history ; Climate change ; Ocean currents ; Southwest Africa
    Source: Springer Online Journal Archives 1860-2000
    Topics: Archaeology , Biology
    Notes: Abstract A continuous palynological record from the marine core GeoB1016-3 from the Angola Basin reveals the regional vegetation and climate history of the last 300 ka. Pollen and spores found at the studied site have their source areas in the different vegetation zones of the adjacent part of the West African continent. Those vegetation zones comprise tropical rain forest, coastal mangrove swamp, Miombo woodland, dry forest, Afromontane forest, desert and semi-desert. The main pollen transport agent is the southeast trade wind system. Ocean currents also partly play a role in transporting pollen and spores. During the interglacial periods, ocean currents also transported palynomorphs southward. During the glacial periods, increased trade winds are indicated by high influx of pollen and spores and high pollen percentages of Poaceae and taxa from desert and semidesert vegetations. Reconstruction of the geographical position of palaeo-vegetation zones shows that the northern boundary of the Namib Desert did not move north of 12°S during the last 300 ka. This implies that northward shifts of the Angola-Benguela Front did not pass the latitude of 12°S.
    Type of Medium: Electronic Resource
    URL: http://dx.doi.org/10.1007/BF01261959
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  • 4
    Electronic Resource
    Electronic Resource
    Vegetation and climate changes during the last 21 000 years in S.W. Africa based on a marine pollen record (1998)
    Springer
    Vegetation history and archaeobotany 7 (1998), S. 127-140 
    Details
    ISSN: 1617-6278
    Keywords: Marine pollen record ; S.W. Africa ; Climate change ; Human impact ; Late Pleistocene ; Holocene
    Source: Springer Online Journal Archives 1860-2000
    Topics: Archaeology , Biology
    Notes: Abstract A high resolution marine pollen record from site GeoB1023, west of the northern Namib desert provides data on vegetation and climate change for the last 21 ka at an average resolution of 185 y. Pollen and spores are mainly delivered to the site by the Cunene river and by surface and mid-tropospheric wind systems. The main pollen source areas are located between 13°S and 21°S, which includes the northern Namib desert and semi-desert, the Angola-northern Namibian highland, and the north-western Kalahari. The pollen spectra reflect environmental changes in the region. The last glacial maximum (LGM) was characterised by colder and more arid conditions than at present, when a vegetation with temperate elements such as Asteroideae, Ericaceae, and Restionaceae grew north of 21°S. At 17.5 ka cal. B.P., an amelioration both in temperature and humidity terminated the LGM but, in the northern Kalahari, mean annual rainfall in the interval 17.5-14.4 ka cal. B.P. was probably 100–150 mm lower than at present (400–500 mm/y). The Late-glacial to early Holocene transition includes two arid periods, i.e. 14.4–12.5 and 10.9–9.3 ka cal. B.P. The last part of the former period may be correlated with the Younger Dryas. The warmest and most humid period in the Holocene occurred between 6.3 and 4.8 ka cal. B.P. During the last 2000 years, human impact, as reflected by indications of deforestation, enhanced burning and overgrazing, progressively intensified.
    Type of Medium: Electronic Resource
    URL: http://dx.doi.org/10.1007/BF01374001
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  • 5
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    Environmental control of pollen grain distribution patterns in the Gulf of Guinea and offshore NW-Africa (1991)
    Springer
    In:  Geologische Rundschau, 80 (3). pp. 567-589.
    Details
    Publication Date: 2020-07-30
    Description: The areas of marine pollen deposition are related to the pollen source areas by aeolian and fluvial transport regimes, whereas wind transport is much more important than river transport. Pollen distribution patterns ofPinus, Artemisia, Chenopodiaceae-Amaranthaceae, and Asteraceae Tubuliflorae trace atmospheric transport by the northeast trades. Pollen transport by the African Easterly Jet is reflected in the pollen distribution patterns of Chenopodiaceae-Amaranthaceae, Asteraceae Tubuliflorae, andMitracarpus. Grass pollen distribution registers the latitudinal extension of Sahel, savannas and dry open forests. Marine pollen distribution patterns of Combretaceae-Melastomataceae,Alchornea, andElaeis reflect the extension of wooded grasslands and transitional forests. Pollen from the Guinean-Congolian/Zambezian forest and from the Sudanian/Guinean vegetation zones mark the northernmost extension of the tropical rain forest.Rhizophora pollen in marine sediments traces the distribution of mangrove swamps. Only near the continent, pollen ofRhizophora, Mitracarpus, Chenopodiaceae-Amaranthaceae, and pollen from the Sudanian and Guinean vegetation zones are transported by the Upwelling Under Current and the Equatorial Under Current, where those currents act as bottom currents. The distribution of pollen in marine sediments, reflecting the position of major climatic zones (desert, dry tropics, humid tropics), can be used in tracing climatic changes in the past.
    Type: Article , PeerReviewed
    Format: text
    DOI: 10.1007/BF01803687
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    OceanRep: Article in a Scientific Journal - peer-reviewed
  • 6
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    Analysis of organic matter in ODP Hole 159-962B (1999)
    PANGAEA
    Details
    Publication Date: 2024-02-02
    Keywords: 159-962B; Carbon, organic, total; DEPTH, sediment/rock; DRILL; Drilling/drill rig; DSDP/ODP/IODP sample designation; Element analyser CHN, LECO; Gulf of Guinea; Joides Resolution; Leg159; Ocean Drilling Program; ODP; Pyrolysis temperature maximum; Rock eval pyrolysis (Behar et al., 2001); Sample code/label; SFB261; South Atlantic in Late Quaternary: Reconstruction of Budget and Currents
    Type: Dataset
    Format: text/tab-separated-values, 213 data points
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  • 7
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    Pollen analysis of sediment core GIK15669-1 (1992)
    PANGAEA
    Details
    Publication Date: 2024-03-06
    Keywords: Acacia/Parkia; Acanthaceae; Acer; Alnus; Ambrosia-type; Anthoceros; Antidesma-type; Artemisia (Africa); Asphodelus; Betula; Boscia-type; Brassicaceae; Bridelia; Butyrospermum; Canthium; Capparis; Carpinus; Caryophyllaceae; Caryophyllaceae, Chenopodiaceae, Amaranthaceae; Cassia-type; Cedrus; Celtis; Centaurea perrottettii-type; Centaurea scabiosa-type (Africa); Ceratonia; Cleome; Combretaceae/Melastomataceae; Commiphora; Compositae Liguliflorae; Compositae Tubuliflorae; Corylus; Counting, palynology; Cyperaceae undifferentiated; Depth, bottom/max; DEPTH, sediment/rock; Depth, top/min; Ephedra distachya-type; Ephedra fragilis-type; Epilobium; Ericaceae undifferentiated; Erodium; Euphorbia-type; Fagus; Fern spores; GIK15669-1; Gravity corer (Kiel type); Gymnosporia; Gypsophila; Helianthemum; Indeterminata/varia; Isoetes; Juglans; Juniperus (Africa); Ligustrum; M53; M53_169; Marker, added; Marker, found; Meteor (1964); Myrica; Myrtaceae (Africa); off West Africa; Olea; Papilionoideae; Paronychia; Phillyrea; Phyllanthus; Picconia; Picea; Pilea; Pinus; Pistacia; Pityrogramma; Plantago; Poaceae undifferentiated; Pollen, total; Polycarpaea-type; Polygonum aviculare-type; Portulacaceae; Quercus ilex-type; Quercus pubescens-type; Ranunculaceae; Rhamnaceae undifferentiated; Rhus-type; Rosaceae (Africa); Rumex; Salix cf. Salix chevalieri; Salvadora persica; Schizaea-type; SL; Spores, monolete psilate; Spores, monolete verrucate; Spores, trilete psilate; Spores, trilete verrucate; Thymelaeaceae; Tilia; Tribulus; Ulmus; Umbelliferae; Viburnum (Africa); Vigna; Volume; Zygophyllum
    Type: Dataset
    Format: text/tab-separated-values, 4136 data points
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    DATA PANGAEA
  • 8
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    Pollen analysis of ODP Hole 108-658A, Part I (1994)
    PANGAEA
    Details
    Publication Date: 2024-03-06
    Keywords: 108-658A; Acacia/Parkia; Acalypha; Acanthaceae; Agavaceae; Aizoaceae; Alchornea; Allophylus; Alnus; Amaranthaceae/Chenopodiaceae; Amphimas; Anthoceros; Araliaceae undifferentiated; Arecaceae; Artemisia (Africa); Asphodelus; Balanites; Baphia-type; Barleria; Betula; Bignoniaceae; Blighia-type; Boerhavia; Boraginaceae (Africa); Borassus-type; Borreria; Boscia-type; Bosqueia; Botryococcus; Brassicaceae; Bridelia; Butyrospermum; Cadaba; Calamus; Calligonum; Canarias Sea; Canthium; Capparidaceae; Capparis; Caryophyllaceae; Cassia-type; Celastraceae/Hippocrateaceae; Celtis; Centaurea (Africa); Chrozophora; Cissus; Cistaceae (Africa); Cleome; Cnestis-type; Coffea-type; Combretaceae/Melastomataceae; Commiphora; Compositae Liguliflorae; Compositae Tubuliflorae; Convolvulaceae (Africa); Corbichonia; Corchorus; Corylus; Counting, palynology; Crossopteryx; Croton-type; Cuviera; Cyperaceae undifferentiated; Delonix; DEPTH, sediment/rock; Diodia-type; Diospyros; Dodonaea viscosa; DRILL; Drilling/drill rig; DSDP/ODP/IODP sample designation; Elaeis guineensis; Entada-type; Ephedra distachya-type; Ephedra fragilis-type; Epilobium; Ericaceae undifferentiated; Erodium; Euphorbiaceae undifferentiated; Euphorbia-type; Fern spores; Filipendula; Fraxinus; Geraniaceae (Africa); Gymnocarpos; Heliotropium; Hibiscus-type; Hildebrandtia; Hygrophila-type; Hymenocardia; Hyphaene; Hypoestes type; Icacina; Ilex cf.. mitis; Indeterminata/varia; Indigofera-type; Iodes; Ixora; Jatropha; Joides Resolution; Justicia/Monechma; Lannea; Leea; Leg108; Liliaceae undifferentiated; Lycopodium (Africa); Macaranga-type; Maerua-type; Mallotus; Malvaceae (Africa); Manilkara; Marker, added; Marker, found; Mitracarpus; Morelia senegalensis; Morus-type; Myrica; Myriophyllum; Neurada; Nitraria; Nyctaginaceae; Ocean Drilling Program; Ochnaceae; ODP; Olea; Oleaceae (Africa); Ophioglossum; Ormocarpum; Papilionoideae; Parinari; Pavetta; Pediastrum; Petersianthus macrocarpus; Phillyrea; Phyllanthus; Picea; Piliostigma; Pinus; Plantago; Plantago maritima-type; Plumbaginaceae undifferentiated; Poaceae undifferentiated; Podocarpus; Pollen, total; Polycarpaea-type; Polycarpon; Polygala-type; Polygonum aviculare-type; Polygonum senegalense-type; Pteris; Pterocarya; Pycnanthus; Quercus; Ranunculaceae; Rhamnaceae undifferentiated; Rhizophora; Rhus-type; Rhynchosia-type; Riccia; Rubiaceae monade; Rubiaceae tetrade; Rubiaceae-type; Rumex; Sabicea; Sample code/label; Sapium-type; Sapotaceae/Meliaceae; Sesbania-type; Solanum-type; Sphagnum; Spondianthus; Spores, monolete; Spores, monolete psilate; Spores, trilete; Spores, trilete psilate; Sterculia-type; Stipularia africana; Tamarix (Africa); Tephrosia; Tetraploa aristata conidia; Tetrorchidium; Tilia; Tribulus; Trichilia; Tsuga; Typha angustifolia-type; Typha latifolia; Uapaca; Ulmus; Umbelliferae; Vigna; Volume; Zanthoxylum; Zygophyllum; Zygophyllum/Peganum
    Type: Dataset
    Format: text/tab-separated-values, 22816 data points
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  • 9
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    Pollen analysis of ODP Hole 108-658A, Part II (1994)
    PANGAEA
    Details
    Publication Date: 2024-03-06
    Keywords: 108-658A; Abies; Acacia/Parkia; Acalypha; Acanthaceae; Afzelia; Agavaceae; Aizoaceae; Alchornea; Alismataceae; Alnus; Amaranthaceae/Chenopodiaceae; Amphimas; Anthoceros; Antidesma-type; Araliaceae; Arecaceae; Artemisia (Africa); Asphodelus; Balanites; Baphia-type; Barleria; Betula; Bignoniaceae; Blepharis; Blighia-type; Bombax; Boraginaceae (Africa); Borassus-type; Borreria; Boscia-type; Bosqueia; Botryococcus; Brassicaceae; Bridelia; Burkea; Butyrospermum; Cadaba; Calligonum; Calycobolus-type; Canarias Sea; Canthium; Capparidaceae; Carpinus; Caryophyllaceae; Cassia-type; Caylusea; Celastraceae/Hippocrateaceae; Celtis; Centaurea (Africa); Chrozophora; Cissus; Cistaceae (Africa); Cistus; Cleome; Cnestis-type; Combretaceae/Melastomataceae; Commiphora; Compositae Liguliflorae; Compositae Tubuliflorae; Convolvulaceae (Africa); Corchorus; Corylus; Counting, palynology; Crossopteryx; Croton-type; Crudia-type; Cuviera; Cyperaceae undifferentiated; DEPTH, sediment/rock; Detarium; Dichrostachys cinerea; Diodia-type; Diospyros; Dodonaea viscosa; DRILL; Drilling/drill rig; Drypetes molunduana; DSDP/ODP/IODP sample designation; Elaeis guineensis; Entada-type; Ephedra distachya-type; Ephedra fragilis-type; Ericaceae undifferentiated; Erodium; Eucommia; Eugenia/Syzygium; Euphorbiaceae undifferentiated; Euphorbia-type; Fagus; Fern spores; Filipendula; Gaertnera; Geraniaceae (Africa); Gymnocarpos; Helianthemum; Heliotropium; Hildebrandtia; Hygrophila-type; Hymenocardia; Hyphaene; Hypoestes type; Ilex cf.. mitis; Indeterminata/varia; Indigofera-type; Isoberlinia-type; Ixora; Jasminum; Jatropha; Joides Resolution; Justicia/Monechma; Kedrostis; Labiatae; Lannea; Leea; Leg108; Leucas; Liliaceae undifferentiated; Lophira; Lycopodium (Africa); Macaranga-type; Maerua-type; Mallotus; Malvaceae (Africa); Manilkara; Marker, added; Marker, found; Mitracarpus; Morelia senegalensis; Mussaenda; Myrica; Myriophyllum; Nauclea/Mitragyna; Neurada; Nitraria; Nyctaginaceae; Nymphaea; Ocean Drilling Program; ODP; Olea; Oleaceae (Africa); Ophioglossum; Papilionoideae; Paramacrolobium; Parinari; Pavetta; Pediastrum; Peristrophe; Phillyrea; Phoenix; Phyllanthus; Phytolacaceae; Picea; Piliostigma; Pinaceae; Pinaceae cf. Cathaya; Pinus; Plantago; Plantago maritima-type; Plumbaginaceae undifferentiated; Poaceae undifferentiated; Podocarpus; Pollen, total; Polycarpaea-type; Polycarpon; Polygala-type; Polygonum aviculare-type; Ponteridaceae; Potamogeton (Africa); Protea; Pteris; Pterocarpus; Pterocarya; Pycnanthus; Quercus; Ranunculaceae; Rauvolfia; Rhamnaceae undifferentiated; Rhizophora; Rhus-type; Rhynchosia-type; Riccia; Rosaceae (Africa); Rubiaceae monade; Rubiaceae-type; Rumex; Rutaceae; Sabicea; Salix cf. Salix chevalieri; Salvadora persica; Sample code/label; Sanguisorba minor; Sapotaceae/Meliaceae; Schrebera; Securinega; Selaginella; Sesbania-type; Sherbournea; Solanum-type; Sphagnum; Spores, monolete; Spores, monolete psilate; Spores, monolete verrucate; Spores, trilete; Spores, trilete psilate; Sporomorphes, reworked; Sterculia-type; Symphytum; Tamarindus/Cryptosepalum; Tamarix (Africa); Tetraploa aristata conidia; Tetrorchidium; Teucrium; Thymelaeaceae; Tilia; Tribulus; Typha angustifolia-type; Typha latifolia; Uapaca; Ulmus; Umbelliferae; Vigna; Virectaria; Volume; Zanthoxylum; Zygophyllum
    Type: Dataset
    Format: text/tab-separated-values, 53105 data points
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  • 10
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    Pollen analysis of sediment core GIK15627-3 (1992)
    PANGAEA
    Details
    Publication Date: 2024-03-06
    Keywords: Acanthus; Acer; Alnus; Antidesma-type; Arbutus; Artemisia (Africa); Asphodelus; Balanites; Betula; Boraginaceae (Africa); Borago; Brassicaceae; Cadaba; Calligonum; Carpinus; Caryophyllaceae, Chenopodiaceae, Amaranthaceae; Caylusea; Cedrus; Celosia; Celtis; Centaurea perrottettii-type; Cistus; Clematis-type; Cleome; Compositae Liguliflorae; Compositae Tubuliflorae; Corylus; Counting, palynology; Crotalaria; Cucurbitaceae; Cyperaceae undifferentiated; Depth, bottom/max; DEPTH, sediment/rock; Depth, top/min; Echinops (Africa); Echiochilon; Echium (Africa); Encephalartos; Ephedra distachya-type; Ephedra fragilis-type; Ericaceae undifferentiated; Erodium; Euphorbiaceae undifferentiated; Euphorbia-type; Fagus; Fern spores; Galium (Africa); Geraniaceae (Africa); GIK15627-3; Gisekia; Gymnocarpos; Gypsophila; Haloragaceae; Helianthemum; Heliotropium; Hyphaene; Indeterminata/varia; Isoetes; Juglans; Juniperus (Africa); KOL; Labiatae; Lannea; Liliaceae undifferentiated; Linaceae; Linum (Africa); Lonicera (Africa); Lythraceae; M53; Maerua-type; Mallotus; Marker, added; Marker, found; Mercurialis (Africa); Meteor (1964); Mollugo; Moltkia; Myrtus; Northeast Atlantic; Nymphaea; Olea; Onagraceae (Africa); Ophioglossum; Ostrya; Papilionoideae; Phaseolus; Phillyrea; Phyllanthus; Pinus; Pistacia; Piston corer (Kiel type); Plantago; Plumbaginaceae undifferentiated; Poaceae undifferentiated; Pollen, total; Polycarpaea-type; Polycarpon; Polygala-type; Polygonum aviculare-type; Protea; Quercus ilex-type; Quercus pubescens-type; Ranunculaceae; Resedaceae; Rhamnaceae undifferentiated; Rhus-type; Rosaceae (Africa); Rumex; Salix cf. Salix chevalieri; Sanguisorba minor; Solanum-type; Spores, monolete verrucate; Tamarix (Africa); Tilia; Tribulus; Trichodesma; Typha angustifolia-type; Ulmus; Umbelliferae; Veronica-type; Vitaceae (Africa); Volume; Warionia
    Type: Dataset
    Format: text/tab-separated-values, 7602 data points
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