Skip to Main Content
Skip Nav Destination

Persistence of a freshwater surface ocean after a snowball Earth

Geology (2017) 45 (7): 615–618.
This article has been cited by the following articles in journals that are participating in CrossRef Cited-by Linking.
Melting the Marinoan Snowball Earth: The impact of deglaciation duration on the sea-level history of continental margins
Earth and Planetary Science Letters (2025) 650: 119132.
Post-Marinoan paleoredox and paleoproductivity record in Puga cap carbonate: Implication for coastal life colonization at the Amazon Craton marginal Sea
Palaeogeography, Palaeoclimatology, Palaeoecology (2025) 657: 112600.
Marine nitrogen cycling in the aftermath of the Marinoan Snowball Earth
Palaeogeography, Palaeoclimatology, Palaeoecology (2024) 639: 112065.
Rare earth elements as indicators of post-Marinoan (∼635 Ma) paleoceanographic changes from the Amazon Craton
Precambrian Research (2024) 413: 107575.
Dynamic evolution of marine productivity, redox, and biogeochemical cycling track local and global controls on Cryogenian sea-level change
Geochimica et Cosmochimica Acta (2024) 365: 114.
Critical Role of Vertical Radiative Cooling Contrast in Triggering Episodic Deluges in Small‐Domain Hothouse Climates
Journal of Advances in Modeling Earth Systems (2024) 16 (6)
Questioning the role of methane in the wake of a snowball Earth: Insights from isotopically anomalous cap dolostone cements with a complex diagenetic history
Geochimica et Cosmochimica Acta (2024) 364: 195.
Three-stage formation of cap carbonates after Marinoan snowball glaciation consistent with depositional timescales and geochemistry
Nature Communications (2024) 15 (1)
Paleomagnetic investigation of the basal Maieberg Formation (Namibia) cap carbonate sequence (635 Ma): Implications for Snowball Earth postglacial dynamics
Geological Society of America Bulletin (2024) 136 (11-12): 4775.
Lithium isotope evidence for a plumeworld ocean in the aftermath of the Marinoan snowball Earth
Proceedings of the National Academy of Sciences (2024) 121 (46)
Palaeoenvironment characteristics of the Ediacaran Doushantuo Shale, Yichang area, South China: Implications for organic matter accumulation mechanism
Fuel (2024) 357: 129673.
Constraining the diagenesis of the Puga cap carbonate from U–Pb in‐situ dating of seafloor crystal fans, southern Amazonian craton, Brazil
Terra Nova (2023) 35 (4): 276.
The origin of cap carbonate after the Ediacaran glaciations
Global and Planetary Change (2023) 226: 104141.
Snowball earth: The African legacy
Journal of African Earth Sciences (2023) 205: 104976.
Application of the δ44/40Ca-δ88/86Sr multi-proxy to Namibian Marinoan cap carbonates
Geochimica et Cosmochimica Acta (2023) 353: 13.
Widespread clay authigenesis and highly congruent silicate weathering in the Marinoan aftermath
Earth and Planetary Science Letters (2023) 623: 118423.
The high-frequency sea-level change in the aftermath of the Marinoan snowball Earth: Evidence from the Doushantuo formation in the northern margin of the Yangtze Craton, South China
Energy Exploration & Exploitation (2023) 41 (3): 941.
Himalayan magnesite records abrupt cyanobacterial growth that plausibly triggered the Neoproterozoic Oxygenation Event
Precambrian Research (2023) 395: 107129.
Tonian Low‐Latitude Marine Ecosystems Were Cold Before Snowball Earth
Geophysical Research Letters (2023) 50 (5)
Natural climate change and glaciations
Earth-Science Reviews (2023) 241: 104435.
Diagenesis of the Marinoan cap dolostone, Southern Amazon Craton: An unconventional petroleum system in the evolution of the Araras-Alto Paraguai Basin
Marine and Petroleum Geology (2023) 158: 106496.
Energetic Constraints on Ocean Circulations of Icy Ocean Worlds
The Planetary Science Journal (2023) 4 (6): 117.
Facies and stratigraphy of the basal Ediacaran cap carbonate, Naukluft Mountains, Namibia
Precambrian Research (2023) 394: 107113.
Zinc, carbon, and oxygen isotopic variations associated with the Marinoan deglaciation
Mineralogy and Petrology (2023) 117 (2): 373.
Sedimentology of the Ediacaran barite‐bearing cap dolostone from Gaolan, northern Three Gorges, South China
Sedimentology (2023) 70 (2): 381.
Coupled dolomite and silica precipitation from continental weathering during deglaciation of the Marinoan Snowball Earth
Precambrian Research (2022) 380: 106824.
A transient peak in marine sulfate after the 635-Ma snowball Earth
Proceedings of the National Academy of Sciences (2022) 119 (19)
Sea-glacier retreating rate and climate evolution during the marine deglaciation of a snowball Earth
Global and Planetary Change (2022) 215: 103877.
Evaluation of alkalinity sources to Cryogenian cap carbonates, and implications for cap carbonate formation models
Global and Planetary Change (2022) 217: 103949.
Climate and ocean circulation in the aftermath of a Marinoan snowball Earth
Climate of the Past (2022) 18 (4): 759.
Enigmatic super-heavy pyrite formation: Novel mechanistic insights from the aftermath of the Sturtian Snowball Earth
Geochimica et Cosmochimica Acta (2022) 334: 65.
Ocean Circulation on Enceladus with a High- versus Low-salinity Ocean
The Planetary Science Journal (2021) 2 (4): 151.
Snowballs in Africa: sectioning a long-lived Neoproterozoic carbonate platform and its bathyal foreslope (NW Namibia)
Earth-Science Reviews (2021) 219: 103616.
A rapid rise of seawater δ13C during the deglaciation of the Marinoan Snowball Earth
Global and Planetary Change (2021) 207: 103672.
Precipitation of Marinoan cap carbonate from Mn-enriched seawater
Earth-Science Reviews (2021) 218: 103666.
Life in the aftermath of Marinoan glaciation: The giant stromatolite evolution in the Puga cap carbonate, southern Amazon Craton, Brazil
Precambrian Research (2021) 354: 106059.
Adaptation to a Viscous Snowball Earth Ocean as a Path to Complex Multicellularity
The American Naturalist (2021) 198 (5): 590.
Waxing and waning of microbial laminites in the aftermath of the Marinoan glaciation at the margin of the Amazon Craton (Brazil)
Precambrian Research (2020) 348: 105856.
Cryogenian cap carbonate models: a review and critical assessment
Palaeogeography, Palaeoclimatology, Palaeoecology (2020) 552: 109727.
The Enigma of Neoproterozoic Giant Ooids—Fingerprints of Extreme Climate?
Geophysical Research Letters (2020) 47 (4)
Oceanographic Considerations for Exoplanet Life Detection
The Astrophysical Journal (2020) 895 (1): 19.
Marinoan glacial aftermath in South China: Paleo-environmental evolution and organic carbon accumulation in the Doushantuo shales
Chemical Geology (2020) 555: 119838.
Toward refining the onset age of Sturtian glaciation in South China
Precambrian Research (2020) 338: 105555.
Effect of dolomitization on isotopic records from Neoproterozoic carbonates in southwestern Mongolia
Precambrian Research (2020) 350: 105902.
Hydrothermal influence on barite precipitates in the basal Ediacaran Sete Lagoas cap dolostone, São Francisco Craton, central Brazil
Precambrian Research (2020) 340: 105628.
A Decrease to Low Carbonate Clumped Isotope Temperatures in Cryogenian Strata
AGU Advances (2020) 1 (3)
Digging deeper: why we need more Proterozoic algal fossils and how to get them
Journal of Phycology (2019) 55 (1): 1.
Coupled carbon and silica cycle perturbations during the Marinoan snowball Earth deglaciation
Geology (2019) 47 (4): 317.
Bisnorgammacerane traces predatory pressure and the persistent rise of algal ecosystems after Snowball Earth
Nature Communications (2019) 10 (1)
Major shoreline retreat and sediment starvation following Snowball Earth
Terra Nova (2019) 31 (6): 495.
Close Modal

or Create an Account

Close Modal
Close Modal