Middle Eocene Rhodoliths from Tropical and Mid-Latitude Regions
Abstract
:1. Introduction
2. Materials and Methods
3. Study Areas: Location and Geological Settings
3.1. Southern Spain
3.2. Dominican Republic
3.3. Colombia
4. Results
4.1. Salinas Menores Ravine
4.2. Sierra del Zacatín
4.3. Dominican Republic
4.4. Colombia
5. Discussion
5.1. Paleoenvironmental Interpretation
5.2. Taxonomic Composition
5.3. Rhodolith Beds during the Eocene
6. Conclusions
- In two tropical settings, the Dominican Republic and Colombia, middle Eocene coralline algae occur as dense concentrations of rhodoliths in rhodolith rudstone lithofacies. Rhodoliths are ellipsoidal to spheroidal in shape and are composed by encrusting to warty coralline algal thalli in association with benthic foraminifers, bryozoans, corals, and other calcareous red algae such as Parachaetetes asvapatii and Polystrata alba.
- In mid-latitude areas in Southern Spain, coralline algae occur in two different contexts. In Salinas Menores ravine, rhodoliths are spheroidal to ellipsoidal and occur dispersed in planktic foraminifer-rich marls. In the Sierra del Zacatín, LBF dominate the middle Eocene carbonate deposits and rhodoliths are scarce. Coralline algae mostly occur attached to and intergrown with corals. Rhodoliths consist of encrusting and warty (occasionally fruticose) algal thalli intergrown with bryozoans, corals, and benthic foraminifers.
- In all the study areas, coralline algal assemblages are dominated by Hapalidiales and Sporolithales. The order Corallinales is scarcely represented, except in Salinas Menores, where its members are relatively abundant and diverse. Within this group, Subterraniphyllum thomasii is found in the Salinas Menores section. The oldest previously known record of this species is from the late Eocene; therefore, our finding extends the occurrence of S. thomasii back to the middle Eocene.
- Rhodoliths in the two tropical areas developed in relatively deep platform settings (tens of meters of water depth) as shown by the LBF and coralline algal assemblages. In the Salinas Menores section, miliolids in the internal voids indicate that rhodoliths grew in a shallow-water inner platform or lagoon and were re-deposited in deep outer-shelf settings.
- During the greenhouse conditions in the early–middle Eocene, shallow-water carbonate platforms from the tropics to intermediate latitudes were depauperate in rhodolith beds. The key paleoenvironmental factors accounting for this decline remain elusive up to now. Extremely high global temperatures due to high atmospheric CO2 concentrations could negatively affect coralline algae. In addition, distribution of oceanic productivity might account for the main carbonate producers in marine shelves: mesotrophic conditions associated with upwelling areas in tropical regions could have favored the development of rhodolith beds, such as those in the Dominican Republic and Colombia, while oligotrophic conditions in mid–high latitudes catalyzed the widespread dominance by larger benthic foraminifer assemblages, as observed in Southern Spain.
Supplementary Materials
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
References
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Species | Salinas Menores (Southern Spain) | Sierra del Zacatín (Southern Spain) | San Jacinto Fold Belt (Colombia) | Bahoruco Peninsula (Dominican Republic) |
---|---|---|---|---|
Sporolithales | 12.5% | 72% | 21.4% | 54.3% |
S. liberum | X | X | X | X |
S. cf. oulianovi | - | X | - | X |
S. lugeonii | X | X | X | X |
S. nummuliticum | X | X | X | X |
Sporolithon sp. | - | X | - | - |
Hapalidiales | 50.8% | 8.6% | 43.3% | 40% |
Melobesia sp. | - | - | X | - |
Lithothamnion camarasae | X | - | X | - |
L. corallinaeforme | X | - | - | - |
‘Palaeothamnium’ kossovense | X | - | X | X |
Lithothamnion sp. 1 | - | - | X | - |
Lithothamnion sp. 2 | - | X | X | - |
Lithothamnion sp. 3 | - | - | X | X |
Lithothamnion sp. 4 | X | - | X | X |
Lithothamnion sp. 5 | X | - | - | X |
Mesophyllum sp. 1 | X | - | - | X |
Mesophyllum sp. 2 | X | - | - | - |
Corallinales | 19.4% | 2% | 1% | - |
Lithoporella sp. | X | X | X | - |
Subterraniphyllum thomasii | X | - | - | - |
Karpathia sphaerocellulosa | X | - | - | - |
Hydrolithon cf. lemoinei | X | - | - | - |
Distichoplax biserialis | - | X | - | - |
Spongites sp. 1 | X | - | - | - |
Spongites sp. 2 | X | - | - | - |
Spongites sp. 3 | X | - | - | - |
Spongites sp. 4 | X | - | - | - |
Neogoniolithon sp. 1 | X | - | - | - |
Neogoniolithon sp. 2 | - | X | - | - |
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Aguirre, J.; Braga, J.C.; Pujalte, V.; Orue-Etxebarria, X.; Salazar-Ortiz, E.; Rincón-Martínez, D.; Abad, M.; Pérez-Valera, F. Middle Eocene Rhodoliths from Tropical and Mid-Latitude Regions. Diversity 2020, 12, 117. https://doi.org/10.3390/d12030117
Aguirre J, Braga JC, Pujalte V, Orue-Etxebarria X, Salazar-Ortiz E, Rincón-Martínez D, Abad M, Pérez-Valera F. Middle Eocene Rhodoliths from Tropical and Mid-Latitude Regions. Diversity. 2020; 12(3):117. https://doi.org/10.3390/d12030117
Chicago/Turabian StyleAguirre, Julio, Juan C. Braga, Victoriano Pujalte, Xabier Orue-Etxebarria, Edward Salazar-Ortiz, Daniel Rincón-Martínez, Manuel Abad, and Fernando Pérez-Valera. 2020. "Middle Eocene Rhodoliths from Tropical and Mid-Latitude Regions" Diversity 12, no. 3: 117. https://doi.org/10.3390/d12030117
APA StyleAguirre, J., Braga, J. C., Pujalte, V., Orue-Etxebarria, X., Salazar-Ortiz, E., Rincón-Martínez, D., Abad, M., & Pérez-Valera, F. (2020). Middle Eocene Rhodoliths from Tropical and Mid-Latitude Regions. Diversity, 12(3), 117. https://doi.org/10.3390/d12030117