-
(Table 12) Diatom biostratigraphy of ODP Hole 167-1021B sediments
DEPTH, sediment is given in mbsf. Abundance estimates as follows: A = abundant, C = common, F = few, R = rare, T = trace, and B = barren, - = not found. -
(Table 8) Diatom biostratigraphy of ODP Hole 167-1018A sediments
DEPTH, sediment is given in mbsf. Abundance estimates as follows: A = abundant, C = common, F = few, R = rare, T = trace, and B = barren, - = not found. -
(Table 6) Diatom biostratigraphy of ODP Hole 167-1014A sediments
DEPTH, sediment is given in mbsf. Abundance estimates as follows: A = abundant, C = common, F = few, R = rare, T = trace, and - = not found. -
(Table 2) Diatom community at DSDP Hole 95-613
indicates reworked species. Samples examined from Cores 4 to 11 were barren of diatoms except for one specimen of Paralia sulcata (found in Sample 613-6-2, 50-52 cm). -
(Table 1) Diatom community at DSDP Hole 95-612
indicates reworked species. Samples examined from Cores 4, 6 to 8, and 12 were barren of diatoms. -
(Table T2) Diatom stratigraphy in ODP Hole 182-1128C sediments
Sediment depth is given in mbsf. X = present, - = absent. -
(Table T1) Diatom biostratigraphy of ODP Hole 183-1140A
Sediment depth is given in mbsf. Abundance as follows: A = abundant, C = common, F = few, R = rare. Lowercase letters = reworking caused by drilling disturbance. -
(Table T4) Reworked diatoms and sponge spicules in ODP Hole 188-1165B sediments
Sediment depth is given in mbsf. Abundance estimate as follows: F = few, R = rare, X = present, - = absent. Abundance letter followed by 'r' = out of known biostratigraphic... -
(Table T2) Diatom abundance in ODP Hole 188-1165B sediments
Sediment depth is given in mbsf. Abundance estimate as follows: A = abundant, C = common, F = few, R = rare, Tr = trace, - = not found. Abundance letter followed by 'r' = out of... -
(Table 1) Diatom and silicoflagellate relative abundance in ODP Hole 207-1260A
This dataset has no description
-
(Table 2) Stratigraphic occurrences of Neogene diatoms in ODP Hole 127-794A
Sediment depth is given in mbsf, # indicates reworked specimens. -
(Table 4) Range chart of relative abundances of selected diatoms and silicofl...
Species abundances: X = very rare (only one observed specimen); R = rare (several specimens/slide); S = sparse (one specimen/20 fields of view); F = frequent (one specimen/10... -
(Table 4) Range chart of relative abundances of selected diatoms and silicofl...
Species abundances: X = very rare (only one observed specimen); R = rare (several specimens/slide); S = sparse (one specimen/20 fields of view); F = frequent (one specimen/10... -
(Table III) Occurrence of selected diatom taxa in DSDP Hole 18-173, Californi...
Taxa abundance: A = abundant, C = common, F = few, R = rare * = reworked, - = not present -
(Table II) Occurrence of selected diatom taxa in the western part of the Uppe...
Distance is Stratigraphic interval in m. Taxa abundance: A = abundant, C = common, F = few, R = rare * = reworked, - = not present -
(Table I) Occurrence of selected diatom taxa in the eastern part of the Upper...
Distance is stratigraphic interval in m. Taxa abundance: A = abundant, C = common, F = few, R = rare * = reworked, - = not present -
(Table 1) Stratigraphic distribution and relative abundances of selected diat...
Species abundance: R = rare; S = sparse; F = frequent; C = common; A = abundant; lower-case abundance designators are interpreted as reworked occurrences. -
(Table 2) Taxonomic composition of diatoms from bottom deposits of the Kronot...
Eocene diatom and silicoflagellate complexes from deposits of the Kronotsky Bay are presented. Pro tempore they are the most ancient finds of fossil phytoplankton with silica... -
(Table 2) Taxonomic composition of diatoms in dredged samples from the island...
Studies of diatoms from dredge samples collected on the island slope of the Kuril-Kamchatka Trench have allowed to recognize well-preserved marine diatom assemblages... -
Results of diatom analysis of Hole 302-M0002A
Relative abundance: A = abundant, C = common, F = few, R = rare, B=barren (numerical values are abundance in counts) / + = ?