Pelotas Basin

32°06′40″S 48°55′50″W / 32.11111°S 48.93056°W / -32.11111; -48.93056EtymologyPelotas (a city in the state of Rio Grande do Sul)RegionSouth AtlanticCountry Brazil
 UruguayState(s)Santa Catarina, Rio Grande do Sul
Cerro Largo, Rocha, Treinta y TresCitiesPorto Alegre, Rio GrandeCharacteristicsOn/OffshoreBoth, mostly offshoreBoundariesSerras de Sudeste, Florianópolis High, Polônio High, Cuchilla GrandePart ofBrazilian South Atlantic basinsArea~346,000 km² (134,000 sq mi)HydrologySea(s)South Atlantic OceanRiver(s)Urussanga, Araranguá, Mampituba, Jacuí, Guaíba, Camaquã, Jaguarão/Yaguarón, Cebollatí RiversLake(s)Lagoa dos Patos, Lagoon MirimGeologyBasin typePassive margin on rift basinPlateSouth AmericanOrogenyBreak-up of GondwanaAgeHauterivian-recentStratigraphyStratigraphyField(s)none (2017)

The Pelotas Basin (Portuguese: Bacia de Pelotas, Spanish: Cuenca de Pelotas) is a mostly offshore sedimentary basin of approximately 346,000 square kilometres (134,000 sq mi) in the South Atlantic, administratively part of the southern states Santa Catarina and Rio Grande do Sul of Brazil and the departments Cerro Largo, Rocha and Treinta y Tres of Uruguay.

The Pelotas Basin is one of the basins that formed on the present-day South Atlantic margins of South America and Africa due to the break-up of Gondwana in the Early Cretaceous. The sedimentary succession started as the other Brazilian marginal basins with a series of basalts, younger than the Paraná and Etendeka traps exposed in the Paraná Basin to the west, followed by shallow to deeper marine carbonate and clastic sediments. Other than the northern neighbours Santos and Campos Basins, the Pelotas Basin lacks a thick layer of salt and the pre-salt layer pinches out just in the north of the Pelotas Basin stratigraphy.

Within the Brazilian Atlantic margin, the Pelotas Basin is relatively underexplored. Twenty exploration wells have been drilled in the Brazilian portion of the basin with one ultra-deepwater exploration well drilled on the Uruguayan side in 2016. No hydrocarbon accumulations have been proven in the basin thus far.

Etymology

The basin is named after the city of Pelotas, the hometown of Rodi Ávila Medeiros, the geologist who studied the area.^[1]

Description

The Pelotas Basin is an approximately 346,000-square-kilometre-large (134,000 sq mi), mostly offshore sedimentary basin, located in the South Atlantic offshore Brazil and Uruguay. It covers the southern Brazilian states of Santa Catarina and Rio Grande do Sul and the Uruguayan departments Cerro Largo, Rocha and Treinta y Tres. About 40,900 square kilometres (15,800 sq mi) of the basin is onshore.^[2] The onshore part of the basin in Uruguay is locally called Merín Basin.^[3]

The basin is bound by the Florianópolis High, separating it from the Santos Basin in the north and the Polônio High in the south, forming the border with the Punta del Este Basin.^[4] The coastal ranges Serras de Sudeste in Brazil and Cuchilla Grande in Uruguay form the western boundary, underlain by the Sierra Ballena Shear Zone. The onshore part of the basin is from north to south crossed by the Urussanga, Araranguá, Mampituba, Jacuí, Guaíba, Camaquã, Jaguarão/Yaguarón and Cebollatí Rivers.^[5]

Tectonic history

The basins of the South Atlantic margin started forming in the Early Cretaceous with the break-up of Gondwana, the southern part of the former supercontinent Pangea. This tectonic movement resulted in a sequence of rift basins bordering the present-day South Atlantic on the Brazilian and southwestern African sides. The Pelotas-Namibia spreading commenced in the Hauterivian, around 133 million years ago, and reached the Santos Basin to the north in the Barremian. Seafloor spreading continued northwards to the Campos Basin in the Early Albian, at approximately 112 Ma.^{[citation needed]}

Five tectonic stages have been identified in the Brazilian basins:^[7]

1. Pre-rift stage – Jurassic to Valanginian
2. Syn-rift stage – Hauterivian to Late Barremian
3. Sag stage – Late Barremian to Late Aptian
4. Post-rift stage – Early to Middle Albian
5. Drift stage – Late Albian to Holocene

While the basins to the north of Pelotas Basin, the Santos, Campos and Espírito Santo Basins, are characterised by a thick sequence of salt and an accompanying pre-salt layer, evaporites are almost absent in the Pelotas Basin.^[8]

Stratigraphy

The sedimentary succession of the Pelotas Basin is underlain by an extremely deformed (highly stretched, thinned and faulted) continental crust, covered by grabens that can achieve thicknesses of more than 20 kilometres (66,000 ft).^[9] The nature of the lower crust below the Pelotas Basin remains uncertain, but by analogy with the Namibian conjugate margin, it may correspond to a high-density igneous crust-mantle interface intruded by the Tristan da Cunha plume.^[7] The central onshore boundary of the basin is formed by the Neoproterozoic Pelotas Batholith.^[10][11] The stratigraphy of the Pelotas Basin and the Punta del Este Basin to the south had a different history due to the Polônio paleohigh until the Late Maastrichtian.^[12]

The basinal sequence starts with the Imbituba Formation, a unit consisting of basaltic volcanic rocks. Parts of these rocks have been dated at ages between 125 ± 0.7 Ma and 118 ± 1.9 Ma, more recent than the flood basaltic Serra Geral Formation of the Paraná and Etendeka traps to the west in the Paraná Basin.^[10] The basalts are exposed in the Serra Geral National Park as a 700-metre-high (2,300 ft) cliff.^[13] The volcanic deposits form seaward dipping reflectors (SDR) in the seismic surveys of the basin.^[14] The conglomerates, siltstones and diamictites of the Cassino Formation represent the top of the Gondwana break-up unconformity, dates to the Middle Aptian.^[15] The depositional environment has been interpreted as fluvio-deltaic to lacustrine. The formation is followed by the volcanics of the Curumim Formation, dated at 113 ± 0.1 Ma, and small incursions in the northern area of Pelotas Basin of the Ariri Formation, the evaporites that form the salt layer in the Santos Basin to the north.^[16]

The rapid subsidence from the Albian to Turonian created a wide marine platform with in the north elevated areas due to the doming of the Curumim Formation. On this platform, the marine limestones and siliciclastics of the Porto Belo Formation were deposited. Shales comprise the outer marine deposition of this stratigraphic unit, considered as a potential source rock.^[16] Overlying the Porto Belo Formation are the proximal Tramandaí and the distal Atlántida Formations, composed of coarse-grained fluvial to alluvial clastics, intercalated with siltstones and shales.^[17] This phase is characteristic of a large-scale prolonged transgression that lasted until the Oligocene. As in other areas of the Brazilian continental margin, the Late Turonian is marked by a regional unconformity.^[18]

The Late Cretaceous to recent sequence is subdivided into the proximal Cidreira Formation, related to the fluvial progradation of the Rio Grande,^[15] and a distal part known as the Imbé Formation, consisting of shales, intercalated with sporadic siltstones and fine-grained sandstones.^[17] The transgressive series is interrupted by the presence of various Paleogene hiatuses, that appear also in the regressive Miocene to recent beds.^[18] The unconformities have been analysed in detail using ⁸⁷Sr/⁸⁶Sr ratios.^[19]

Age	Formation		Lithologies		Maximum thickness		Notes
Pleistocene	Cidreira Fm.	Imbé Fm.	Sandstones, shales	Shales, siltstones, sandstones	7,000 m (23,000 ft)		[17][20]
Pliocene
Messinian
							[21]
Tortonian							[20]
							[21]
Serravallian
Langhian
							[20]
Chattian
Rupelian
							[21]
Bartonian							[21]
Priabonian
Lutetian							[20]
Ypresian							[21]
							[20]
Paleocene
Maastrichtian
Campanian
Santonian
Coniacian
Late Turonian
Early Turonian	Tramandaí Fm.	Atlántida Fm.	Sandstones, siltstones, shales	Shales		900 m (3,000 ft)	[17][20]
Cenomanian
Late Albian
Early Albian		Porto Belo Fm.		Limestones, shales		700 m (2,300 ft)	[20]
	Ariri Fm.		Thin evaporites		800 m (2,600 ft)		[20]
Aptian	Curumim Fm.		Basalts				[20]
	Cassino Fm.		Conglomerates, siltstones		1,800 m (5,900 ft)		[20]
	Imbituba Fm.		Basalts				[20]
Barremian
	Serra Geral Fm.		Flood basalts				[20]
Hauterivian
Valanginian
	Botucatu Fm.		Quartzitic sandstones				[20][22]
Berriasian
Tithonian
Early-Late Jurassic
Late Triassic
Permo-Triassic	Rio do Rasto Fm.		Red sandstones				[20][23]
	Teresina Fm.		Fine sandstones and carbonates				[20][24]
	Irati Fm.		Black shales and carbonates				[20][25]
	Palermo Fm.		Siltstones, fine sandstones				[20][26]
	Rio Bonito Fm.		Sandstones, siltstones, shales				[20][27]
Early-Late Paleozoic
Precambrian	Pelotas Batholith, Dom Feliciano Belt		Granite, gabbro, diorite, rhyolitic to basaltic dikes				[20][28]

Exploration

The Pelotas Basin is relatively underexplored. The Brazilian part of the basin had a total of twenty exploration wells drilled until 2017. The first eight wells were drilled in the onshore section in the 1950s and 1960s. After acquiring seismic survey in the 1970s, seven more wells were drilled in the shallow offshore part. Five other offshore wells were drilled between 1995 and 2001. The first and hitherto only well drilled in the Uruguayan part of the basin was drilled in 2016. Hydrocarbon accumulations have yet to be discovered in Pelotas Basin.^[4] An exploration area of approximately 15,000 square kilometres (5,800 sq mi) was offered in the Brazil Bidding Round of 2017.^[29]

See also

• Campos Basin
• Paraná Basin
• Santos Basin

References

Bibliography

Brazil general

• Beasley, Craig J.; Joseph Carl Fiduk; Emmanuel Bize; Austin Boyd; Marcelo Frydman; Andrea Zerilli; John R. Dribus; Jobel L.P. Moreira, and Antonio C. Capeleiro Pinto. 2010. Brazil's Pre-Salt Play. Oilfield Review 22. 28–37. Accessed 2017-09-09.
• Bryant, Ian; Nora Herbst; Paul Dailly; John R. Dribus; Roberto Fainstein; Nick Harvey; Angus McCoss; Bernard Montaron, and David Quirk, Paul Tapponnier. 2012. Basin to Basin: Plate Tectonics in Exploration. Oilfield Review 24. 38–57. Accessed 2017-09-09.
• Da Costa, Guilherme Estevam. 2015. Fácies sedimentares e composição de folhelhos da Formação Irati (Eopermiano) da Bacia do Paraná na região de Bom Retiro, Leste de Santa Catarina, 1–67. Universidade Federal de Santa Catarina, UFSC. Accessed 2017-09-09.
• Mello, Marcio Rocha; Nilo C. De Azambuja Filho; André A. Bender; Silvana Maria Barbanti; Webster Mohriak; Priscila Schmitt, and Carlos Luciano C. De Jesus. 2012. The Namibian and Brazilian southern South Atlantic petroleum systems: are they comparable analogues?. Geological Society, London, Special Publications 369. 1–18. Accessed 2017-09-09.
• Petersohn, Eliane. 2017. Brazil Bidding Rounds 2017, 1–45. ANP. Accessed 2017-09-09.
• Petrolli, Larissa, and Ana Maria Pimentel Mizusaki. 2014. Formação Botucatu (Jurássico, Bacia do Paraná) – análogo como reservatório de hidrocarbonetos para as bacias da margem continental brasileira, 1. Universidade Federal do Rio Grande do Sul. Accessed 2017-09-09.
• Philipp, Ruy Paulo; Marcio Martins Pimentel, and Farid Chemale Jr. 2016. Tectonic evolution of the Dom Feliciano Belt in Southern Brazil: Geological relationships and U-Pb geochronology. Brazilian Journal of Geology 46. 83–104. Accessed 2017-09-09.
• Rohn, Rosemarie, and Oscar Rösler. 1990. Conchostráceoas da Formação Rio do Rasto (Bacia do Paraná, Permiano Superior): Bioestratigrafia e implicações paleoambientais. Revista Brasileira de Geociências 19. 486–492. Accessed 2017-09-09.
• Roisenberg, Ari; Juliana Charão Marques; Flávio Antônio Bachi, and José Carlos Frantz. 2008. Nota explicativa da folha Gravataí (SH.22-X-C-V) - 1:100,000, 1–72. Serviço Geológico do Brasil. Accessed 2017-09-09.
• Warren, Lucas Veríssimo; Mario Luis Assine; Marcello Guimarães Simões; Claudio Riccomini, and Luís Eduardo Anelli. 2015. A Formação Serra Alta, Permiano, no centro‑leste do Estado de São Paulo, Bacia do Paraná, Brasil. Brazilian Journal of Geology 45. 109–126. Accessed 2017-09-09.

Pelotas Basin

• Arnemann Batista, Carlos Mikael. 2015. Bacia de Pelotas - Sumário Geológico e Setores em Oferta, 1–19. ANP. Accessed 2017-09-09.
• Conti, Bruno; Jose Alexandre de Jesus Perinotto; Gerardo Veroslavsky; María Gabriela Castillo; Hector De Santa Ana; Matías Soto, and Ethel Morales. 2017. Speculative petroleum systems of the southern Pelotas Basin, offshore Uruguay. Marine and Petroleum Geology 83. 1–25. Accessed 2017-09-09.
• Contreras, Jorham. 2011. Seismo-stratigraphy and numerical basin modeling of the southern Brazilian continental margin (Campos, Santos, and Pelotas basins) (PhD thesis), 1–171. Ruprecht-Karls-Universität Heidelberg. Accessed 2017-09-09.
• Correa da Camara Rosa, Maria Luiza; Eduardo Guimarães Barboza; Vitor Dos Santos Abreu; Luiz José Tomazelli, and Sérgio Rebello Dillenburg. 2017. High-Frequency Sequences in the Quaternary of Pelotas Basin (coastal plain): a record of degradational stacking as a function of longer-term base-level fall. Brazilian Journal of Geology 47. 183–207. Accessed 2017-09-09.
• De Santa Ana, Héctor; César Goso Aguilar; Jorge Montaño; Graciela Piñeiro; Rossana Muzio; Eduardo Rossello; Daniel Perea, and Nelson Ucha. 2004. Cuencas sedimentarias de Uruguay - geología, paleontología y recursos naturales - Mesozóico, 1–219. División Relaciones y Actividades Culturales de Facultad de Ciencias. Accessed 2017-09-09.
• De Santana dos Anjos Zerfass, Geise; Farid Chemale Jr.; Candido Augusto Veloso Moura; Karen Badaraco Costa, and Koji Kawashita. 2014. Strontium isotope stratigraphy of the Pelotas Basin. Brazilian Journal of Geology 44. 23–38. Accessed 2017-09-09.
• Soto, Matías; Ethel Morales; Gerardo Veroslavsky; Héctor De Santa Ana; Nelson Ucha, and Pablo Rodríguez. 2011. The continental margin of Uruguay: Crustal architecture and segmentation. Marine and Petroleum Geology 28. 1–14. Accessed 2017-09-09.
• Zalán, Pedro Victor. 2017. Where Should We Drill in the Deep Waters of the Pelotas Basin, Southern Brazil and Uruguay?, 1–7. AAPG Annual Convention & Exhibition, Houston, Texas. Accessed 2017-09-09.

External links

• Love, Frank. 2013. South Atlantic Pre-Salt Play Elements, Play Potential and Continental Margin Types, 1:06:49. Houston Geological Society. Accessed 2017-09-09.