Publication Date:
2024-05-27
Keywords:
Abrupt Climate Changes and Environmental Responses; Acaena/Polylepis; Acalypha; Accumulation model; ACER; Alchornea; Alnus; Alternanthera; Amaranthaceae; Anacardiaceae; Antidaphne; Apiaceae; Arecaceae; Asteraceae; Bocconia-type; Bomarea-type; Borreria; Brassicaceae; Calendar age; Calendar age, maximum/old; Calendar age, minimum/young; Caryophyllaceae; Cecropia; Celtis; Chenopodiaceae; Classical age-modeling approach, CLAM (Blaauw, 2010); Cleome-type; Clethra; Clusia; Counting, palynology; Croton; Cyathea baculata; Cyatheaceae; Cyperaceae; Daphnopsis-type; DEPTH, sediment/rock; Dodonaea; Ericaceae; Euphorbiaceae; Gentianaceae; Geranium; Gomphrena-type; Grammitis-type; Gunnera; Hedyosmum; Hymenophyllum; Hypericum; Ilex; Isoetes; Jamesonia-type; Juglans; Lamiaceae; Leguminosae; Liliopsida; Lophosoria; Loranthaceae; Lycopodium; Malvaceae; Melastomataceae; Meliaceae; Myrica; Myriophyllum; Myrsine; Myrtaceae; Onagraceae; Ophioglossum; Passiflora-type; Plantago; Poaceae; Podocarpus; Polypodiales; Potamogeton; Proteaceae; Pteridaceae; Puya; Ranunculus-type; Rubiaceae; Rumex-type; Sample ID; Sapium; Satureja-type; Siberia1; Solanaceae; Styloceras-type; Thalictrum-type; Type of age model; Unknown; Urticales; Valeriana; Viburnum-type; Vicia; Weinmannia
Type:
Dataset
Format:
text/tab-separated-values, 5440 data points
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