Cuche Formation

The Cuche Formation (Spanish: Formación Cuche, Cc) is a geological formation of the Floresta Massif, Altiplano Cundiboyacense in the Eastern Ranges of the Colombian Andes. The sequence of siltstones, shales, and sandstone beds dates to the Late Devonian and Early Carboniferous periods, and has a maximum thickness of 900 metres (3,000 ft).

The formation was deposited in a tidal-dominated deltaic environment at high southern paleolatitudes at the edge of the Paleozoic Paleo-Tethys Ocean. The Cuche Formation is highly fossiliferous; many Placoderm fish fossils, flora, bivalves, arthropods, crustaceans and ostracods have been discovered in the youngest Paleozoic strate of the Floresta Massif, while the underlying Floresta Formation is richer in trilobite biodiversity.

Etymology

The formation was first described as part of the Floresta Series by Olsson and Carter in 1939. The current definition was given by Botero in 1950. The formation is named after the vereda Cuche of Floresta, Boyacá, where the formation outcrops. The word Cuche is taken from Muysccubun, the language of the indigenous Muisca, who inhabited the Altiplano Cundiboyacense before the Spanish conquest.

Regional setting

The Floresta Massif is a block in the northern part of the Altiplano Cundiboyacense, marked by a metamorphic crystalline core overlain by Devonian to Carboniferous sedimentary sequences; from old to young, the El Tíbet, Floresta and Cuche Formations. The Paleozoic succession is overlain by sediments of much younger date; the Late Jurassic Girón and Early Cretaceous Tibasosa Formations. The massif is bound to the east by the Soapaga Fault and to the west by the Boyacá Fault.

At time of deposition of the Devonian formations, present-day northern South America was located at the edge of the Paleo-Tethys Ocean on the southern hemisphere. The Paleozoic occurrence on the Altiplano is localized in outcrop; the majority of surface sediments are Cretaceous to Paleogene in age. Neogene uplift of the Eastern Ranges, with its main phase in the Plio-Pleistocene, caused the exhumation of older units at surface along major thrust faults in the Eastern Andes. In two phases during the Paleozoic, intrusions occurred into the sedimentary sequence, causing local metamorphism. The first phase is considered pre-Devonian and the latter phase post-Devonian. The remaining stratigraphy of the Cuche Formation appears little affected by this intrusive phase, although slight metamorphism has been identified in later research.

Description

Lithologies

The Cuche Formation is characterised by mostly cream and purple coloured shales, with a basal unit of micaceous siltstones with intercalated yellowish-grey shales and 30 metres (98 ft) thick quartzitic and feldspar-rich sandstone beds that colour red caused by meteoric waters. The sandstones have an iron-rich cementation. A middle unit of fine-grained sandstones with thin banks of siltstones follows the lower part and an upper sequence of shales with interbedded ferruginous red beds. The lower sequence contains runzelmark syn-sedimentary structures.

Stratigraphy and depositional environment

The Cuche Formation in some places discordantly and in other areas transitionally defined by colour changes, overlies the Floresta Formation in Boyacá and the Mogotes Formation in Santander, and is, by an angular unconformity up to 60 degrees, overlain by the Upper Jurassic Girón, and Early Cretaceous Tibasosa Formations. The angular unconformity between the Paleozoic and Mesozoic is exposed along the road between Duitama and Sogamoso, and is the location where the first flora fossils were found in 1978.

The age of the Cuche Formation has been estimated to be Late Devonian to Early Carboniferous, after an original designation as Permian-Carboniferous by Botero in 1950, further restricted to the Carboniferous by Julivert in 1968. The formation covers an area of approximately 36 square kilometres (14 sq mi) and ranges in thickness between 300 and 900 metres (980 and 2,950 ft). Stratigraphically, the Cuche Formation is time equivalent with the Diamante Formation of the Santander Massif to the north of the Altiplano Cundiboyacense. To the west of Paz de Río, the Cuche Formation is thrusted upon the Neogene Concentración Formation by the Soapaga Fault. In the northern part of the Floresta Massif, the contact between the metamorphic Otengá Stock and the Cuche Formation is formed by the Duga Fault.

Based on the preservation of fossils, the lithologies, syn-sedimentary structures and stratigraphic position, a depositional environment of shallow low energy waters has been proposed, possibly in a lagoonal setting at the edge of a regressional Paleo-Tethys Ocean. Other parts of the Cuche Formation were deposited in a continental environment, evidenced by the red beds and absence of marine fossils and abundant root imprints. Overall, the sequence represents a coastal deltaic environment with frequent marine incursions, a tidal deltaic setting.

Fossil content

Fossil flora from the Cuche Formation were identified as "*Ginkgo*-like" species, as this *Baiera* reconstruction. Proper *Ginkgo* do not appear in the geological record until the Middle Permian

The first identification of fossil content of the Cuche Formation was done by Botero, who studied the formation in 1950. Research in the early 1980s revealed the presence of many more fossils in the formation and among the first fossil flora found were species then identified as the genera Ginkgo and Baiera. The lower units show poorly preserved plant remains and the overlying shales provided arthropods and crustaceans. In the middle units of the formation, more and better preserved plant fossils were found alongside bivalves, ostracods (of the genus Welleria) and arthropods.

The Cuche Formation contains unique Placoderm fish fossils, first noted by Mojica and Villarroel in 1984. Across the section, also plant fossils and bivalves are found. In this part of the sequence the first fish fossils were discovered. The top section provided brachiopods (genus Lingula) and other at that moment undetermined fossil fragments.

Later research has provided more insight into the flora of the formation, with the "Ginkgo" species possibly a Ginkgophyton sp.. Additionally, fossil flora of Colpodexylon cf. deatsii and cf. Archaeopteris sp. have been described from the formation. In the continental sandstone facies of the Cuche Formation, ichnofossils of Diplichnites have been described.

Fishes

Remains of the cartilaginous fish Antarctilamna sp., the Placoderms Asterolepis sp. and two species of Bothriolepis, the spiny shark ?Cheiracanthoides sp., the Porolepiform Holoptychius sp., and the Rhizodontid ?Strepsodus sp. have been uncovered from the Cuche Formation. Several other fossils are less well recognizable at the genus level, among others Actinopterygii, Sarcopterygii, and Osteolepiformes. The fish specimens were found in sediments possibly representing localized transgressive marine incursions into brackish lagoonal settings, in all cases associated with the presence of bivalves, ostracods and brachiopods.

The fossil fish assemblage of the Cuche Formation presents a curious mixture of Euramerican "Old Red Sandstone" (Catskills, Greenland, Scotland and the Baltic states) species (Asterolepis and Holoptychius), and Gondwanan taxa (Antarctilamna), suggesting the interchange of species between the paleogeographical regions, possibly at closer distance than is presented in most paleogeographical models. This hypothesis is further strengthened by the discovery of typical Euramerican flora, as Archaeopteris.

Asterolepis has been known only from Euramerican fossils, except for a specimen found in Iran. The fish of the Cuche Formation are quite different from Bolivian Devonian fossils, with the exception of Antarctilamna. The similar sediments of the Colpacucho Formation in Bolivia have not provided the species discovered in the Cuche Formation, probably because of the cooler climate of the Devonian Bolivian seas more to the south than the paleogeographical position of northern Colombia (already around 51°S) at that time.

Fossils assigned to Florestacanthus cf. morenoi, Colombiaspis rinconensis and Colombialepis villarroeli were later described from the Cuche Formation.

Eurypterids

In 2019, fragments of the eurypterid Pterygotus were retrieved from the formation. The find represents the first sea scorpion from Colombia and the fourth from South America. The specimen (SGC-MGJRG.2018.I.5), assigned with uncertainty to P. bolivianus due to similarities with its holotype, represents the first eurypterid of Colombia and the fourth of South America. The fossil was dated as Frasnian (Late Devonian), showing that Pterygotus did not become extinct during the Middle Devonian as previously thought.

Outcrops

The Cuche Formation is found at the Floresta Massif around its type locality in Floresta, Boyacá, stretching across Floresta to the west close to Belén and Paz de Río, up to north of Tibasosa in the valley of the Chicamocha River.

Regional correlations

Stratigraphy of the Llanos Basin and surrounding provinces
Ma	Age	Paleomap	Regional events	Catatumbo	Cordillera	proximal Llanos	distal Llanos	Putumayo	VSM	Environments
0.01	Holocene		Holocene volcanism Seismic activity	alluvium		Overburden
1	Pleistocene		Pleistocene volcanism Andean orogeny 3 Glaciations	Guayabo	Soatá Sabana	Necesidad	Guayabo	Gigante Neiva	Alluvial to fluvial (Guayabo)	550 m (1,800 ft) (Guayabo)
2.6	Pliocene		Pliocene volcanism Andean orogeny 3 GABI	Subachoque
5.3	Messinian	Andean orogeny 3 Foreland	Marichuela	Caimán	Honda
13.5	Langhian	Regional flooding	León	hiatus	Caja	León	Lacustrine (León)	400 m (1,300 ft) (León)	Seal
16.2	Burdigalian	Miocene inundations Andean orogeny 2	C1	Carbonera C1	Ospina	Proximal fluvio-deltaic (C1)	850 m (2,790 ft) (Carbonera)	Reservoir
17.3	C2	Carbonera C2	Distal lacustrine-deltaic (C2)	Seal
19	C3	Carbonera C3	Proximal fluvio-deltaic (C3)	Reservoir
21	Early Miocene	Pebas wetlands	C4	Carbonera C4	Barzalosa	Distal fluvio-deltaic (C4)	Seal
23	Late Oligocene		Andean orogeny 1 Foredeep	C5	Carbonera C5	Orito	Proximal fluvio-deltaic (C5)	Reservoir
25	C6	Carbonera C6	Distal fluvio-lacustrine (C6)	Seal
28	Early Oligocene	C7	C7		Pepino	Gualanday	Proximal deltaic-marine (C7)	Reservoir
32	Oligo-Eocene	C8	Usme	C8	onlap	Marine-deltaic (C8)	Seal Source
35	Late Eocene		Mirador	Mirador	Coastal (Mirador)	240 m (790 ft) (Mirador)	Reservoir
40	Middle Eocene	Regadera	hiatus
45
50	Early Eocene		Socha	Los Cuervos	Deltaic (Los Cuervos)	260 m (850 ft) (Los Cuervos)	Seal Source
55	Late Paleocene	PETM 2000 ppm CO2	Los Cuervos	Bogotá	Gualanday
60	Early Paleocene	SALMA	Barco	Guaduas	Barco	Rumiyaco	Fluvial (Barco)	225 m (738 ft) (Barco)	Reservoir
65	Maastrichtian		KT extinction	Catatumbo	Guadalupe	Monserrate	Deltaic-fluvial (Guadalupe)	750 m (2,460 ft) (Guadalupe)	Reservoir
72	Campanian	End of rifting	Colón-Mito Juan
83	Santonian	Villeta/Güagüaquí
86	Coniacian
89	Turonian	Cenomanian-Turonian anoxic event	La Luna	Chipaque	Gachetá	hiatus	Restricted marine (all)	500 m (1,600 ft) (Gachetá)	Source
93	Cenomanian		Rift 2
100	Albian	Une	Une	Caballos	Deltaic (Une)	500 m (1,600 ft) (Une)	Reservoir
113	Aptian		Capacho	Fómeque	Motema	Yaví	Open marine (Fómeque)	800 m (2,600 ft) (Fómeque)	Source (Fóm)
125	Barremian	High biodiversity	Aguardiente	Paja	Shallow to open marine (Paja)	940 m (3,080 ft) (Paja)	Reservoir
129	Hauterivian		Rift 1	Tibú- Mercedes	Las Juntas	hiatus	Deltaic (Las Juntas)	910 m (2,990 ft) (Las Juntas)	Reservoir (LJun)
133	Valanginian	Río Negro	Cáqueza Macanal Rosablanca	Restricted marine (Macanal)	2,935 m (9,629 ft) (Macanal)	Source (Mac)
140	Berriasian	Girón
145	Tithonian	Break-up of Pangea	Jordán	Arcabuco	Buenavista Batá	Saldaña	Alluvial, fluvial (Buenavista)	110 m (360 ft) (Buenavista)	"Jurassic"
150	Early-Mid Jurassic		Passive margin 2	La Quinta	Montebel Noreán	hiatus	Coastal tuff (La Quinta)	100 m (330 ft) (La Quinta)
201	Late Triassic		Mucuchachi	Payandé
235	Early Triassic		Pangea		hiatus		"Paleozoic"
250	Permian
300	Late Carboniferous		Famatinian orogeny		Cerro Neiva ()
340	Early Carboniferous	Fossil fish Romer's gap	Cuche (355-385)	Farallones ()		Deltaic, estuarine (Cuche)	900 m (3,000 ft) (Cuche)
360	Late Devonian		Passive margin 1	Río Cachirí (360-419)			Ambicá ()	Alluvial-fluvial-reef (Farallones)	2,400 m (7,900 ft) (Farallones)
390	Early Devonian		High biodiversity	Floresta (387-400) El Tíbet				Shallow marine (Floresta)	600 m (2,000 ft) (Floresta)
410	Late Silurian	Silurian mystery
425	Early Silurian	hiatus
440	Late Ordovician		Rich fauna in Bolivia	San Pedro (450-490)		Duda ()
470	Early Ordovician	First fossils	Busbanzá (>470±22) ChuscalesOtengá	Guape ()		Río Nevado ()	Hígado ()Agua Blanca Venado (470-475)
488	Late Cambrian		Regional intrusions	Chicamocha (490-515)	Quetame ()	Ariarí ()		SJ del Guaviare (490-590)	San Isidro ()
515	Early Cambrian	Cambrian explosion
542	Ediacaran		Break-up of Rodinia	pre-Quetame	post-Parguaza	El Barro ()	Yellow: allochthonous basement (Chibcha terrane) Green: autochthonous basement (Río Negro-Juruena Province)		Basement
600	Neoproterozoic		Cariri Velhos orogeny	Bucaramanga (600-1400)	pre-Guaviare
800		Snowball Earth
1000	Mesoproterozoic		Sunsás orogeny	Ariarí (1000)	La Urraca (1030-1100)
1300	Rondônia-Juruá orogeny	pre-Ariarí	Parguaza (1300-1400)	Garzón (1180-1550)
1400		pre-Bucaramanga
1600	Paleoproterozoic	Maimachi (1500-1700)	pre-Garzón
1800		Tapajós orogeny	Mitú (1800)
1950	Transamazonic orogeny	pre-Mitú
2200	Columbia
2530	Archean		Carajas-Imataca orogeny
3100	Kenorland
Sources

Legend

group
important formation
fossiliferous formation
minor formation
(age in Ma)
proximal Llanos (Medina)
distal Llanos (Saltarin 1A well)

Notes

Bibliography

Geology

Geoestudios; ANH (2006), (PDF), ANH, pp. 1–239
Giraldo Gallego, Diana Andrea (2014), , Forma y Función, 27 (2): 41–94, doi:, hdl:
Mojica, Jairo; Villarroel, Carlos (1984), (PDF), Geología Colombiana, 13: 55–80
Pardo Díaz, Marta Yolima; Gil Padilla, Marta Liliana; Garavito Rincón, Laura Natalia; Corredor Vargas, Pedro; Gutiérrez Barrios, Carolina; Parra, Wilson; Amaya Pedraza, Nancy (2014), Estudios técnicos, económicos, sociales y ambientales Complejo de Páramos Altiplano Cundiboyacense, Instituto de Investigación de Recursos Biológicos Alexander von Humboldt & CORPOBOYACÁ, pp. 1–546
Rodríguez Gutiérrez, Madeleidy (2017), Criterios de Análisis y Validación del Comportamiento de los Túneles con Squeezing en Rocas, Escuela Colombiana de Ingeniería Julio Garavito, pp. 1–541
Rodríguez Parra, Antonio José; Solano Silva, Orlando (2000), Mapa Geológico del Departamento de Boyacá - 1:250,000 - Memoria explicativa, INGEOMINAS, pp. 1–120
Villafañez Cardona, Yohana (2012), Análisis de procedencia de areniscas cuarzosas del Devónico-Carbonífero de la Formación Floresta (Norte de Santander): Consideraciones paleogeográficas regionales, EAFIT, pp. 1–89

Paleontology

Olive, Sébastien; Pradel, Alan; Martinez Pérez, Carlos; Janvier, Philippe; Lamsdell, James C.; Gueriau, Pierre; Rabet, Nicolas; Duranleau-Gagnon, Philippe; Cardenas Rozo, Andres L.; Zapata Ramirez, Paula A.; Botella, Héctor (2019), , Journal of Vertebrate Paleontology, e1620247 (3): 1–18, Bibcode:, doi:, hdl: doi:
Gómez Cruz, Arley de Jesús; Moreno Sánchez, Mario; Lemus Restrepo, Alexander (2015), , Tercer Simposio Latinoamericano de Icnología, Colonia de Sacramento, Uruguay, pp. _
Morzadec, Pierre; Mergl, Michal; Villarroel, Carlos; Janvier, Philippe; Racheboeuf, Patrick R. (2015), (PDF), Bulletin of Geosciences, 90: 331–358, doi:
Giroud López, Marie Joëlle (2014), , Universidad de La Habana, pp. 1–174
Berry, Christopher M.; Morel, Eduardo; Mojica, Jairo; Villarroel, Carlos (2000), , Geological Magazine, 137 (3): 257–268, Bibcode:, doi:
Janvier, Philippe; Villarroel, Carlos (2000), , Palaeontology, 43 (4): 729–763, Bibcode:, doi:
Janvier, Philippe; Villarroel, Carlos (1998), , Geología Colombiana, 23: 3–18

Maps

Renzoni, Giancarlo; Rosas, Humberto (2009), , INGEOMINAS, p. 1
Ulloa, Carlos E.; Guerra, Álvaro; Escovar, Ricardo (1998), , INGEOMINAS, p. 1
Renzoni, Giancarlo; Rosas, Humberto; Etayo Serna, Fernando (1998), , INGEOMINAS, p. 1

External links

(in Spanish)