Publication Date:
2024-04-20
Keywords:
Abies; Abrupt Climate Changes and Environmental Responses; Accumulation model; Acer; ACER; Alnus; Amaranthaceae/Chenopodiaceae; Apiaceae; Araliaceae; Artemisia; Asteraceae; Betula; Brassicaceae; Calendar age; Calendar age, maximum/old; Calendar age, minimum/young; Campanula; Carpinus/Ostrya; Caryophyllaceae; Castanea/Castanopsis; Celtis/Aphananthe; Classical age-modeling approach, CLAM (Blaauw, 2010); Corydalis; Corylus; Counting, palynology; Cryptomeria; Cyperaceae; DEPTH, sediment/rock; Drosera; Elaeagnus; Epilobium; Ericaceae; Euonymus; Fagus crenata; Fraxinus; Galium; Geranium; Geum; Hydrangea; Ilex; Juglans/Pterocarya; Kenbuchi_Basin; Lamiaceae; Larix; Leguminosae; Ligustrum; Liliaceae; Lonicera; Lycopodium; Lysichiton; Menyanthes; Morus; Myrica; Osmundaceae; Papaveraceae; Persicaria; Phellodendron; Picea; Pinus; Poaceae; Polemonium; Polygonum; Polygonum bistorta; Polypodiales; Quercus subgen. Lepidobalanus; Ranunculus; Rhamnaceae; Rhus; Rosaceae; Rumex; Salix; Sample ID; Sanguisorba; Saxifraga; Selaginella selaginoides; Sorbus; Sparganium/Typha; Sphagnum; Styrax; Thalictrum; Tilia; Tsuga; Type of age model; Ulmus/Zelkova; Valerianaceae; Viburnum
Type:
Dataset
Format:
text/tab-separated-values, 5830 data points
Permalink