Skip to Main Content
Skip Nav Destination

A review of selected aspects of coccolithophore biology with implications for paleobiodiversity estimation

Micropaleontology (2005) 51 (4): 267–288.
This article has been cited by the following articles in journals that are participating in CrossRef Cited-by Linking.
Phosphatic scales in vase‐shaped microfossil assemblages from Death Valley, Grand Canyon, Tasmania, and Svalbard
Geobiology (2021)
Shifts in Phytoplankton Composition and Stepwise Climate Change During the Middle Miocene
Paleoceanography and Paleoclimatology (2020) 35 (8)
Ecological Response of Plankton to Environmental Change: Thresholds for Extinction
Annual Review of Earth and Planetary Sciences (2020) 48 (1): 403.
A new method for isolating and analysing coccospheres within sediment
Scientific Reports (2020) 10 (1)
The Preliminary Study of Late Oligocene to Early Miocene Calcareous Nannofossil in Klias Peninsula, Sabah
IOP Conference Series: Earth and Environmental Science (2020) 549: 012017.
Refining the alkenone-pCO2 method II: Towards resolving the physiological parameter ‘b’
Geochimica et Cosmochimica Acta (2020) 281: 118.
A 15-million-year-long record of phenotypic evolution in the heavily calcified coccolithophore <i>Helicosphaera</i> and its biogeochemical implications
Biogeosciences (2020) 17 (11): 2955.
Algal Sex Determination and the Evolution of Anisogamy
Annual Review of Microbiology (2019) 73 (1): 267.
Considering the Role of Adaptive Evolution in Models of the Ocean and Climate System
Journal of Advances in Modeling Earth Systems (2019) 11 (11): 3343.
The Early to Middle Eocene Transition: An Integrated Calcareous Nannofossil and Stable Isotope Record From the Northwest Atlantic Ocean (Integrated Ocean Drilling Program Site U1410)
Paleoceanography and Paleoclimatology (2019) 34 (12): 1913.
Diversity decoupled from ecosystem function and resilience during mass extinction recovery
Nature (2019) 574 (7777): 242.
Effects of elevated CO 2 on growth, calcification, and spectral dependence of photoinhibition in the coccolithophore Emiliania huxleyi (Prymnesiophyceae) 1
Journal of Phycology (2019) 55 (4): 775.
Coastal zones as important habitats of coccolithophores: A study of species diversity, succession, and life‐cycle phases
Limnology and Oceanography (2018) 63 (4): 1692.
Combination coccospheres from the Eastern Adriatic coast: New, verified and possible life-cycle associations
Marine Micropaleontology (2018) 141: 23.
Phytoplankton defenses: Do Emiliania huxleyi coccoliths protect against microzooplankton predators?
Limnology and Oceanography (2018) 63 (2): 617.
Coccolithophore diversity in open waters of the middle Adriatic Sea in pre- and post-winter periods
Marine Micropaleontology (2018) 143: 30.
Coccolithophore Cell Biology: Chalking Up Progress
Annual Review of Marine Science (2017) 9 (1): 283.
Coccolithophore diversity and dynamics at a coastal site in the Gulf of Trieste (northern Adriatic Sea)
Estuarine, Coastal and Shelf Science (2017) 196: 331.
Combining marine macroecology and palaeoecology in understanding biodiversity: microfossils as a model
Biological Reviews (2017) 92 (1): 199.
Physiology regulates the relationship between coccosphere geometry and growth phase in coccolithophores
Biogeosciences (2017) 14 (6): 1493.
Global coccolithophore diversity: Drivers and future change
Progress in Oceanography (2016) 140: 27.
Coccolithophore life-cycle dynamics in a coastal Mediterranean ecosystem: seasonality and species-specific patterns
Journal of Plankton Research (2016) 38 (5): 1178.
Stable isotope and calcareous nannofossil assemblage record of the late Paleocene and early Eocene (Cicogna section)
Climate of the Past (2016) 12 (4): 883.
Why marine phytoplankton calcify
Science Advances (2016) 2 (7): e1501822.
Sinking phytoplankton associated with carbon flux in the Atlantic Ocean
Limnology and Oceanography (2016) 61 (4): 1172.
Exploring the potential of clumped isotope thermometry on coccolith-rich sediments as a sea surface temperature proxy
Geochemistry, Geophysics, Geosystems (2016) 17 (10): 4092.
Morphometry, biogeography and ecology of Calcidiscus and Umbilicosphaera in the South Atlantic
Revue de Micropaléontologie (2016) 59 (3): 239.
Negative effects of ocean acidification on calcification vary within the coccolithophore genus Calcidiscus
Marine Biology (2015) 162 (6): 1287.
Microfossil evidence for trophic changes during the Eocene–Oligocene transition in the South Atlantic (ODP Site 1263, Walvis Ridge)
Climate of the Past (2015) 11 (9): 1249.
Carbon and oxygen isotopes of bulk carbonate in sediment deposited beneath the eastern equatorial Pacific over the last 8 million years
Paleoceanography (2015) 30 (10): 1261.
Eco-physiological adaptation shapes the response of calcifying algae to nutrient limitation
Scientific Reports (2015) 5 (1)
On the Ultrastructure ofGephyrocapsa oceanica(Haptophyta) Life Stages
Cryptogamie, Algologie (2014) 35 (4): 379.
MorphospeciesversusPhylospecies Concepts for Evaluating Phytoplankton Diversity: The Case of the Coccolithophores
Cryptogamie, Algologie (2014) 35 (4): 353.
Syracosphaera pemmadiscus sp. nov. (Prymnesiophyceae), an extant coccolithophore from the southwest Pacific Ocean near New Zealand
Phycologia (2013) 52 (6): 618.
A reassessment of ‘<i>Globigerina bathoniana</i>’ Pazdrowa, 1969 and the palaeoceanographic significance of Jurassic planktic foraminifera from southern Poland
Journal of Micropalaeontology (2012) 31 (2): 97.
Evolving Phytoplankton Stoichiometry Fueled Diversification of the Marine Biosphere
Geosciences (2012) 2 (2): 130.
Environmental controls on coccolithophore calcification
Marine Ecology Progress Series (2012) 470: 137.
Alkenone producers during late Oligocene-early Miocene revisited
Paleoceanography (2012) 27 (1): n/a.
Global coccolith size variability in Holocene deep-sea sediments
Marine Micropaleontology (2012) 82-83: 1.
Cenozoic coccolith size changes—Evolutionary and/or ecological controls?
Palaeogeography, Palaeoclimatology, Palaeoecology (2012) 333-334: 92.
Coccolithogenesis InScyphosphaera apsteinii(Prymnesiophyceae)
Journal of Phycology (2012) 48 (6): 1343.
The deep-sea microfossil record of macroevolutionary change in plankton and its study
Geological Society, London, Special Publications (2011) 358 (1): 141.
Reply to the comment on "Orbitally forced climate and sea-level changes in the Paleoceanic Tethyan domain (marl–limestone alternations, Lower Kimmeridgian, SE France)" by S. Boulila, M. de Rafélis, L. A. Hinnov, S. Gardin, B. Galbrun, P.-Y. Collin [Palaeogeography Palaeoclimatology Palaeoecology 292 (2010) 57–70]
Palaeogeography, Palaeoclimatology, Palaeoecology (2011) 306 (3-4): 252.
A Time line of the Environmental Genetics of the Haptophytes
Molecular Biology and Evolution (2010) 27 (1): 161.
<i>Kataspinifera baumannii</i>: a new genus and species of deep photic coccolithophores resembling the non-calcifying haptophyte <i>Chrysochromulina</i>
Journal of Micropalaeontology (2010) 29 (2): 135.
Significant CO2 fixation by small prymnesiophytes in the subtropical and tropical northeast Atlantic Ocean
The ISME Journal (2010) 4 (9): 1180.
Journal of Phycology (2009) 45 (1): 213.
Ocean Acidification: The Other CO2Problem
Annual Review of Marine Science (2009) 1 (1): 169.
Exceptionally well preserved upper Eocene to lower Oligocene calcareous nannofossils (Prymnesiophyceae) from the Pande Formation (Kilwa Group), Tanzania
Journal of Systematic Palaeontology (2009) 7 (4): 359.
A sea of Lilliputians
Palaeogeography, Palaeoclimatology, Palaeoecology (2009) 284 (1-2): 88.
Close Modal

or Create an Account

Close Modal
Close Modal