Journal of South American Earth Sciences

Journal of South American Earth Sciences 37 (2012) 242e255 Contents lists available at SciVerse ScienceDirect Journal of South American Earth Scienc

4 downloads 255 Views 1MB Size

Recommend Stories


International Journal of Sport Sciences
International Journal of Sport Sciences April 2011, Vol.1 No.1 Edited by AIASS: AGON International Association of Sport Sciences AGON International

South American Archaeology Seminar: London
South American Archaeology Seminar: London 3rd December 2016 6th Floor Seminar Room Institute of Archaeology, UCL 34 Gordon Square, London WC1H 0PY C

References on South American Camelids
References on South American Camelids Aller JF, Rebuffi G, Cancino AK, Alberio RH. 1998. Ultrasonic diagnosis of pregnancy in vicunas (Vicugna vicugna

Story Transcript

Journal of South American Earth Sciences 37 (2012) 242e255

Contents lists available at SciVerse ScienceDirect

Journal of South American Earth Sciences journal homepage: www.elsevier.com/locate/jsames

An overview of the dinosaur fossil record from Chile David Rubilar-Rogers a, *, Rodrigo A. Otero a, Roberto E. Yury-Yáñez b, Alexander O. Vargas c, Carolina S. Gutstein d, e a

Área de Paleontología, Museo Nacional de Historia Natural, Casilla 787, Santiago, Chile Laboratorio de Zoología de Vertebrados, Departamento de Ciencias Ecológicas, Facultad de Ciencias, Universidad de Chile, Las Palmeras 3425, Ñuñoa, Santiago, Chile c Laboratorio de Ontogenia y Filogenia, Departamento de Biología, Facultad de Ciencias, Universidad de Chile, Las Palmeras 3425, Ñuñoa, Santiago, Chile d Laboratorio de Ecofisiología, Departamento de Ciencias Ecológicas, Facultad de Ciencias, Universidad de Chile, Las Palmeras 3425, Ñuñoa, Santiago, Chile e Department of Paleobiology, National Museum of Natural History, Smithsonian Institution, Washington, DC 20013-7012, USA b

a r t i c l e i n f o

a b s t r a c t

Article history: Received 19 January 2012 Accepted 23 March 2012

In Chile, the record of dinosaurs in Jurassic and Cretaceous sediments is often restricted to footprints, with few skeletal remains. Tetanuran theropods are known in the Upper Jurassic, and bones of titanosaur sauropods in the Late Cretaceous, including partial skeletons (e.g. Atacamatitan chilensis Kellner et al.). Also from the late Cretaceous, an ornithopod vertebra, a pair of theropod teeth and one tarsometatarsus of a gaviiform bird (Neogaeornis wetzeli Lambrecht) have been reported. The Cenozoic fossil record comprises abundant and well-preserved marine birds from Eocene and Miocene units, with a specially abundant record of Sphenisciformes and less frequently, Procellariiformes. There is an excellent Miocene ePliocene record of other birds such as Odontopterygiformes, including the most complete skeleton ever found of a pelagornithid, Pelagornis chilensis Mayr and Rubilar-Rogers. Fossil birds are also known from Pliocene and Pleistocene strata. A remarkable collection of birds was discovered in lacustrine sediments of late Pleistocene age associated to human activity. The perspectives in the study of dinosaurs in Chile are promising because plenty of material stored in institutional collections is not described yet. The record of Chilean dinosaurs is relevant for understanding the dynamics and evolution of this group of terrestrial animals in the western edge of Gondwana, while Cenozoic birds from the Region may contribute to the understanding of current biogeography for instance, the effect of the emergence and establishment of the Humboldt Current. Ó 2012 Elsevier Ltd. All rights reserved.

Keywords: Dinosaurs Birds Mesozoic Cenozoic Chile

1. Introduction Continental vertebrates of the Mesozoic terrestrial fauna of Chile are mainly represented by dinosaurs, with the exception of an aetosaurid from the Triassic of the Antofagasta Region, Chilenosuchus forttae Casamiquela (Casamiquela, 1980; Desojo, 2003) and another yet undetermined non-dinosaurian Ornithodira; isolated bones of pterosaurs from the Cretaceous of the Atacama Region (Bell and Suárez, 1989; Martill et al., 2000, 2006); terrestrial crocodiles from the Aysén Region (Lio et al., 2011); and isolated fragments of turtle plates from the Cretaceous of Coquimbo Region (Casamiquela et al., 1969). All other continental vertebrates are represented by dinosaurs. In the last two decades, knowledge of the record of dinosaurs has received much attention, not only because of the information provided about geological problems, for instance, narrowing the * Corresponding author. Tel.: þ56 26804651; fax: þ56 28958513. E-mail address: [email protected] (D. Rubilar-Rogers). 0895-9811/$ e see front matter Ó 2012 Elsevier Ltd. All rights reserved. doi:10.1016/j.jsames.2012.03.003

temporal range of continental deposits (e.g. Blanco et al., 2000), but also because of their contribution to the knowledge of the evolution of this clade in this Region of the South American continent, once part of the occidental margin of Gondwana. Thus, for example, the rich documentation of dinosaur prints in layers of the Jurassic and lower Cretaceous (Moreno et al., 2004; Rubilar-Rogers et al., 2008; among others) allows to appreciate the wide diversity of kind and size of dinosaurs, and the faunistic successions undergone between these periods. Further, the remains of titanosaurs found in different points throughout northern Chile can indicate how dinosaurs were affected by geographic restrictions (transgression forming epicontinental seas and expansion of arid zones) from land emerging during the latter part of the mesozoic, and if these phenomena generated isolation such that endemism evolved with regard to other dinosaurs of South America. During the cenozoic, the dinosaur record is much better represented temporally and in number of discoveries. In the Paleogene and Neogene, avian remains proceed from the rich marine deposits of the Atacama Region (e.g. Bahía Inglesa Formation) and Patagonia

D. Rubilar-Rogers et al. / Journal of South American Earth Sciences 37 (2012) 242e255

(Loreto, Río Turbio, and Río Baguales formations). Quaternary records of birds came mainly from lacustrine deposits of the O’Higgins Region (San Vicente de Taguatagua). The record of cenozoic fossil birds has received great attention, with several contributions dedicated to documenting these materials (Chávez, 2007a,b; Sallaberry et al., 2008, 2010a). So far, implications of these studies include, for example, the effects of the establishment of the Humboldt Cold Marine Current System and the succession of avian faunas throughout the cenozoic in the South Pacific. The current work presents an overview of the knowledge available about dinosaurs in Chile in recent years, updating previous work that implicitly or explicitly addressed this fauna (e.g. Chong and Gasparini, 1976; Gasparini, 1979; Salinas et al., 1991a; Rubilar-Rogers, 2003). Records are ordered by periods and within each period, the order is by antiquity. A list of the geological units where dinosaur remains have been found is also delivered below. Two general maps of Chile show geographical position of records of the Mesozoic and Cenozoic, respectively. 1.1. Institutional abbreviations SGO.PV.: Collection of Museo Nacional de Historia Natural, Santiago. SNGM: Servicio Nacional de Geología y Minería, Santiago. 2. Geological setting Several records of Mesozoic dinosaurs from Chile are known only by their mention in the literature since the materials were not figured or no hosting institution was properly given in the original publications (e.g. Biese, 1961; Salinas et al., 1991a, 1991b). As a consequence, the present review only considered the materials (Fig. 1) that are available with adequate institutional repository.

243

as a distinctive belt extended from Sierra Moreno to Huatacondo locality. This latter unit was dated based on ammonoids at several main local ravines (e.g. Quebrada Arca and Quebrada Huatacondo, among others, Vicente, 2006), indicating an Oxfordian age for the marine hosting levels that underlies the typical evaporitic beds, assigned to the early Kimmeridgian. In consequence, the age of the continental levels of the Quinchamale Formation is constrained to a maximum mid Kimmeridgian age. In Sierra Moreno, the roof of the unit is conformably overlaid by the volcanic succession Cuesta de Montecristo Volcanites (Charrier et al., 2007), that is partially equivalent to the Arca Formation (Maksaev, 1978) in the Quebrada Arca sector. The presence of dinosaur footprints in Quebrada Arca occurred on multiple layers of sandstones, associated to ripple marks and mud cracks (Rubilar-Rogers and Otero, 2008). Such structures and ichnites are consistent with those described in the upper levels of the Quinchamale Formation, and have not been observed in the volcanic facies of the overlying Cuesta de Montecristo Volcanites (Ladino et al., 1999). This is the reason why the outcrops that host the dinosaur footprints are here assigned to the upper levels of the Quinchamale Formation, and in consequence, constrained to a Kimmeridgian age. 2.1.3. El Toqui Formation (Suárez and De la Cruz, 1994; De la Cruz and Suárez, 2006) Deposits of a marine transgression over subaerial rocks, conformed mainly by calcareous and volcanoclastic sediments deposited on high-energy shorelines (Charrier et al., 2007). The volcanoclastic levels are characterized by alternating sandstones and sedimentary breccias with some levels of tuffs and ignimbrites, which contains fragmentary bone remains of dinosaurs, as well as fossil trunks and traces. This formation was assigned to the Upper Jurassic (Tithonian) based on stratigraphic correlations and radioisotopic dates (Salgado et al., 2008). It is conformably overlaid by the marine, anoxic sediments of the Katterfeld Formation.

2.1. Mesozoic units Besides the unconfirmed mention (without figures or repository information) of remains referred to Megalosauridae from early Callovian marine beds at Cerritos Bayos, northern Chile (Biese, 1961), the oldest record of dinosaurs in the country is restricted to the upper Jurassic (Salgado et al., 2008). Regrettably, most of the units of interest lack detailed striatigraphic/biostratigraphic correlations to constrain the age of the hosting levels of dinosaur remains. Due to this, most findings have been referred to broad chronostratigraphic intervals. The units including verifiable records of dinosaurs in Chile are the following: 2.1.1. Chacarilla Formation (Galli and Dingman, 1962) Clastic succession conformed by lower marine levels that reach a thickness of 1100 m. They were assigned by Galli and Dingman (1962) to the Oxfordian based on fossil invertebrates. The upper levels are comprised by gray-to-red sandstones that host dinosaur footprints and can be constrained to a minimal Kimmeridgiane lower Cretaceous age based on stratigraphic correlations (Charrier et al., 2007). 2.1.2. ‘Quinchamale Formation’ (sensu lato, Maksaev, 1978; Skarmeta and Marinovic, 1981) Backarc deposits with the lower beds comprising mainly limestones, and shales of Sinemurian to Oxfordian age based on fossil invertebrates (Maksaev, 1978; Vicente, 2006). The upper levels are characterized by evaporites (Vicente, 2006), while its uppermost levels are comprised by quarcites and red, continental shales (Skarmeta and Marinovic, 1981). The Quinchamale Formation is in part equivalent to the Aquiuno Formation defined by Garcia (1967)

2.1.4. San Salvador Formation (Lira, 1989) This unit is comprised by paralic and fine-grained continental deposits that overlie through a conformable contact to the Cerritos Bayos Formation (Biese, 1961; Baeza, 1979), and conformably underlie the Cuesta de Montecristo Volcanites. Due to its stratigraphic relations, it can be directly correlated with the continental levels of the Quinchamale Formation exposed in the northern and eastern part of Sierra Moreno, while the beds of the San Salvador Formation represent equivalent levels exposed in the southern part of Sierra Moreno (Charrier et al., 2007). In this unit, Moreno et al. (2004) reported the presence of dinosaur footprints, assigned by these authors to the Kimmeridgianelower Cretaceous. The beds with footprints appear to be consistent in facies and stratigraphic position with the upper levels of the Quinchamale Formation that host dinosaur trackways. In consequence, we propose a temptative Kimmeridgian age for the footprints of the San Salvador Formation (Moreno et al., 2004). 2.1.5. Quebrada Monardes Formation (Muzzio, 1980; Mercado, 1982) Succession of clastic rocks, mostly reddish in color, exposed in the Precordillera of Copiapó, in the Atacama Region. The basal member is comprised by mid-to-coarse grained sandstones and siltstones with cross-bedding (Suárez and Bell, 1986). It was interpreted by these authors (Suárez and Bell, 1986) as a system of braided rivers and eolic dunes with proximity to an inner lake, with several localities hosting dinosaur trackways. It overlies in conformable contact to the marine limestones of the Lautaro Formation assigned to the lowereearly middle Jurassic (Segerstrom, 1968), while its roof is uncertain. Due to this, it was

244

D. Rubilar-Rogers et al. / Journal of South American Earth Sciences 37 (2012) 242e255

Fig. 1. Geographic map showing the distribution of localities in Chile that have yielded remains of Mesozoic Dinosauria (marked with a circle): 1) Quebrada Chacarilla. 2) Huatacondo. 3) El Abra. 4) Quebrada Arca. 5) San Salvador. 6) Pajonales. 7) Quebrada Codocedo. 8) Cerro la Isla. 9) Cerro Algarrobito. 10) Pichasca. 11) Termas del Flaco. 12) Southern part of Lago General Carrera.

assigned by Suárez and Bell (1986) to the Kimmeridgianelower Cretaceous, while the basal member hosting dinosaur footprints (Bell and Suárez, 1989) could represent Kimmeridgian beds that are consistent with the age and facies of the backarc units of the second substage (Charrier et al., 2007) with similar ichnologic records.

volcanic unit Icanche Formation, assigned to the Eocene based on radioisotopic dating (Charrier et al., 2007). The Tolar Formation is assigned to the undifferentiated Late Cretaceous based on stratigraphic correlations. This unit has yielded the type material of Atacamatitan chilensis.

2.1.6. Tolar Formation (Maksaev, 1978) This unit is located on the west side of the Domeyko Range, Region de Antofagasta. It is comprised of well-stratified, red succession of breccias, conglomerates and sandstones. Its lower levels unconformably contact with the Early Cretaceous levels of the Arca Formation and probably with the rhyolites of the Peña Morada Formation, while its roof conformably contacts with the

2.1.7. Pajonales Formation (Harrington, 1961) It comprises continental red sandstones and conglomerates best exposed in the homonymous ravine, on Sierra de Almeyda, Antofagasta Region. It overlies the Pular Formation (Brüggen, 1942) through an angular, erosive discordant contact, and is covered by the same kind of contact with the Guanaqueros Formation (Pino and Fuenzalida, 1988). The dinosaur remains recovered in the

D. Rubilar-Rogers et al. / Journal of South American Earth Sciences 37 (2012) 242e255

Pajonales Formation have been assigned to Sauropoda indet (Salinas et al., 1991b), and were found in lower levels very close to the discordant contact with the underlying unit. The age of the fossiliferous beds was assigned to the Maastrichtian based on stratigraphic correlation (Salinas et al., 1991b). 2.1.8. Hornitos Formation (Segerstrom, 1959) Breccias and conglomerate levels in coarse sandstone matrix, including lenses of sandstones, calcareous mudstones and limestones, with discrete volcanic levels to the roof. It is assigned to the CampanianeMaastrichtian based on stratigraphic correlations (Sepúlveda and Naranjo, 1982; Charrier et al., 2007). This unit contained titanosaur bone remains (Chong, 1985). 2.1.9. Viñita Formation (Aguirre and Egert, 1965) It is comprised mainly by andesites and volcano-sedimentary rocks with pyroclastic intercalations. It includes fossiliferous beds with dinosaur bones and continental turtles (Casamiquela et al.,1969), characterized by a reddish matrix with volcanic, well-selected clasts. Its radioisotopic dates in levels of underlying and overlying units allowed constraining the age of the Viñita Formation to the SantonianeMaastrichtian interval (Pineda and Emparán, 2006). 2.1.10. Baños del Flaco Formation (Klohn, 1960) This unit is characterized by basal marine beds with fossil invertebrates (ammonoids) that allow assignation to a Tithonian age. Upper levels are comprised by near-shore, continental beds that include dinosaur trackways (Casamiquela and Fasola, 1968), presenting volcanic levels to the roof. These latter authors assigned an early Cretaceous age to the dinosaur trackways based on their relative stratigraphic position respect to lower Tithonian beds. 2.1.11. Quiriquina Formation (Biró-Bagóczky, 1982) This unit was formalized by this author, with its type locality on the homonymous island. It is comprised by a basal conglomerate, cross-bedded yellow sandstones with conglomerate lenses, coquinaceous horizons and green sandstones at the top that include concretionary nodules. It was originally assigned to the CampanianeMaastrichtian and later constrained to the late Maastrichtian based on biostratigraphic correlations (Stinnesbeck, 1996; Salazar et al., 2010). 2.2. Tertiary units The PaleogeneeNeogene units are the most recently studied and produced interesting and abundant avian records (Fig. 2). Like marine Eocene birds of Loreto Formation and the diverse fauna of marine birds of Bahia Inglesa Formation. 2.2.1. Estratos de Algarrobo (Gana et al., 1996) This succession is conformed by sandstones of variable grain size and hardness, very fossiliferous, with abundant concretionary nodules in different levels. It reaches about 150 m along the coast (95 m of thickness) and overlies the strata of Quebrada Municipalidad through an erosive discordance. The roof of the unit is constrained by a granitic basement through an inferred fault. This unit was assigned to the middle-to-late Eocene based on fossil invertebrates with good chronostratigraphic resolution (Brüggen, 1915; Tavera, 1980). 2.2.2. Río Turbio Formation (Feruglio, 1938; sensu lato.; emend. Hünicken, 1955; sensu Malumián and Caramés, 1997) This unit, originally defined in Argentina, crops out in part of southernmost Chile. This succession is comprised by sandstones, conglomerates and intercalated coquinaceous levels. Its age is

245

currently accepted to be middle-to-late Eocene, based on stratigraphic correlations and microfossils (Malumián and Caramés, 1997). This unit has yielded fossils of spheniscid and tentative ardeid birds (Sallaberry et al., 2010b). 2.2.3. Río Baguales Formation (Cecioni, 1956) Fossiliferous outcrops out in the northern part of Magallanes. Its stratigraphic relationships are not completely clear, nevertheless, it is possible to recognize a thick section of marine sediments that are consistent with the original definition of the Río Baguales Formation (Cecioni, 1956), reason why these are referred to this unit. The age of the beds that host fossil birds is based on the abundant and typical Eocene associated cartilaginous fishes (Sallaberry et al., 2010b). 2.2.4. Loreto Formation (Hoffstetter et al., 1957) It is comprised mostly by marine sediments that include abundant palynomporphs, wood remains, leaf prints, coal beds, as well as vertebrates, represented by spheniscid penguins and abundant cartilaginous fishes. The age of this unit was recently constrained to the late Eocene (Priabonian) based on vertebrates with good chronostratigraphic value, paleobotany and radiometric date (U/Pb Shrimp) (Otero et al., 2012). 2.2.5. La Portada Formation (Ferraris and Di Biase, 1978) This unit crops out in Mejillones Peninsula, Antofagasta, and is comprised by sandstones, occasional diatomites and fine conglomerates that host a rich vertebrate fauna, including bird remains. The age of this formation was assigned to the Pliocene based on microfossils and fossil invertebrates (Tsuchi et al., 1988; DeVries and Vermeij, 1997), as well as radiometric dating (Marquardt et al., 2005; Cortés et al., 2007). 2.2.6. The Bahía Inglesa Formation (Rojo, 1985) Located on the coast of Atacama Region (Rojo, 1985). It comprises phosphatic sandstones and conglomerates that overlie the Oligoceneeearly Miocene Gravas de Angostura unit and is discordantly covered by the Pleistocene unit of Estratos de Caldera (Marquardt et al., 2000). Also the unit is in lateral contact with fluvial deposits of the Gravas de Copiapó. Most of the fossil vertebrates come from the phosphatic “bonebed” (sensu Walsh and Naish, 2002), including an unusual abundance and diversity of pinnipeds (Walsh and Naish, 2002), cetaceans (Gutstein et al., 2009) and cartilaginous fishes (Long, 1993; Suárez et al., 2004). The age of this formation is constrained to the middle Mioceneeearly Pliocene based on radioisotopic dates on K/Ar (Marquardt et al., 2000), and middle Mioceneelate Pliocene on Sr (Achurra et al., 2009) that are consistent with the chronostratigraphic distribution of several fossil vertebrates hosted in the unit (Suárez and Marquardt, 2003). In the Bahía Inglesa Formation at least 4 localities are distinct, in order of antiquity, “Las Arenas”, “Mina Fosforita”, “El Morro”, and “Los Negros”, and “Las Arenas”, with bird remains mentioned in this work from the four units mentioned before. 2.2.7. Coquimbo Formation (Moscoso et al., 1982) Marine terraces conformed by sandstones and conglomerates, in part phosphatic, with abundant fossil invertebrates and vertebrates (the latter including birds), exposed on the coast of northcentral Chile. The age of this unit was originally assigned to the Pliocene and later constrained to the middle Mioceneeearly Pliocene based on fossil invertebrates (Covacevich and Frassinetti, 1990). Additional radioisotopic dates on Sr indicate 14.6 Ma for beds near the base and 2 Ma for their uppermost levels (Le Roux et al., 2005).

246

D. Rubilar-Rogers et al. / Journal of South American Earth Sciences 37 (2012) 242e255

Fig. 2. Geographic map showing the distribution of localities in Chile that have yielded remains of Cenozoic Dinosauria (marked with a circle): 1) La Portada Formation, Antofagasta. 2) Bahía Inglesa Formation. 3) Coquimbo Formation. 4). Horcon Formation. 5) Estratos de Algarrobo. 6) Taguatagua. 7) Curamallín Formation. 8) Mocha Island. 9) Río Baguales Formation. 10) Río Turbio Formation. 11) Loreto Formation.

2.2.8. Horcón Formation (Thomas, 1958) It is comprised almost entirely by sandstones and less frequent fine conglomerates, exposed in the coast of central Chile. Its age was assigned to the Pliocene based on fossil invertebrates (Tavera, 1960). 2.2.9. Curamallín Formation (González and Vergara, 1962) Unit that crops out in the cordillieran part of south-central Chile. Lacustrine beds conformed by fine limolites, claystones and fine sandstones, assigned to the middleelate Miocene (Niemeyer and Muñoz, 1983). This unit has yielded bird remains in beds with radioisotopic date (KeAr), indicating 17.5  0.6 and 13.0  1.6 Ma (Suárez and Emparan, 1995).

2.3. Pleistocene units The following units are not ordered stratigraphically in formally described formations, so the term “locality” is used to refer to the deposits (Fig. 2). 2.3.1. Taguatagua Systematic excavations were carried out since 1967. An absolute dating of 11.380  320 years was obtained with Carbon14 from the level with human artifacts (Montané, 1968). Fossils of birds were found along with remains of gomphoteres, horses and human tools of archaeological interest. Although the

D. Rubilar-Rogers et al. / Journal of South American Earth Sciences 37 (2012) 242e255

larger fauna has been previously recognized (e.g. Casamiquela,1970; Casamiquela, 1976), besides minor mention in previous work, the smaller fauna has been studied only recently, comprising micromammals, amphibians (Jiménez-Huidobro et al., 2009) and birds. 2.3.2. Mocha Island Located in the Lebu province, Biobio Region, the first paleontological and geological studies of this island were carried out by Tavera and Veyl (1958) who recognized Miocene levels and assigned them to the Ranquil Formation (García, 1968) from the nearby península of Arauco, while an underlying unit was assigned to Navidad Formation. Toward the south of the island Pliocene levels were also recognized. Later studies of the invertebrate fauna were carried out by Nielsen and Frassinetti (2007) who describe that, with minor differences, the fauna of the island resembles Navidad and Ranquil formations. Finger et al. (2007) consider that Ranquil and Navidad formations are equivalent in age, sedimentology, fauna and history of depositation. The Pleistocene levels are the only in which remains of birds have been reported. These are recognized as sandstones that are found in a terrace of marine abrasion, these levels also contain much fractured remains of invertebrate shells. 2.3.3. Lower Pilauco This paleoindian site is found inward to the “los Notros” neighborhood in the city of Osorno. Absolute dating delivers an age of 14,649  382 years. Casually discovered in 1986, since 2007 systematic excavations have been carried out at this site. Initially, remains of mastodons were recovered and more recently, other large and small-sized mammals (horses, chingues, rodents) as well as insects, coprolites and plant remains (González-Guarda et al., 2008; Montero et al., 2008). 3. Jurassic The oldest bone remains of dinosaurs in Chile correspond to materials of two theropods (Theropoda and Tetanurae indet) from the Toqui Formation (late Jurassic, Tithonian) in the Aysén Region (south Chile). These materials correspond to an appendicular skeleton composed of a right Ilium (SNGM-1889), proximal end of left tibia (SNGM-1885), partial left pes, astragalus and calcaneum, distal tarsal IV, metatarsal IIeIV and articulated phalanges (SNGM1888) and distal end of right tibia (SNGM-1901) assigned to Theropoda; and dorsal vertebrae (SNGM-1894, 1898, 1900, 1903) and a partial left manus (SNGM-1887) referred to Tetanurae (Salgado et al., 2008). Interesting assemblages of sauropod and theropod icnites are known from the Tithonian of central Chile (Moreno and Pino, 2002; Moreno and Benton, 2005; Rubilar-Rogers, 2006) found in a coastal layer belonging to the Baños del Flaco Formation (late Jurassic, Tithonian). Other prints have been interpreted as belonging to ornithopods including an ichnospecies Camptosaurichnus fasolae (Casamiquela and Fasola,1968), however, given the preservation it is difficult to evaluate this proposal and these prints have been alternatively referred as Ornithopoda indet (Rubilar-Rogers, 2003). In nearby layers, the presence of dinosaur bones has been mentioned (Salinas et al., 1991b), however, the destiny of this material is unknown and thus this information cannot be confirmed. An assemblage of theropod prints was reported by Moreno et al. (2004) at the locality of San Salvador in the Antofagasta Region consisting of sauropod and theropod prints. The sauropod prints are narrow-gauged, a condition of sauropods with narrow hips (e.g. Diplodocimorpha). Three kinds of theropod prints are mentioned. Such association of narrow-hipped sauropods with theropods is characteristic of the Jurassic period, which is in concordance with the age proposed by Moreno et al. (2004) for the red sedimentites

247

from the “Estación” member of the San Salvador Formation as belonging to the Kimmeridgian. At least four trackways of narrow-hipped sauropods (aff. Brontopodus) and an isolated theropod print were reported from Quebrada Arca (Quinchamale Formation) in the Antofagasta Region (Rubilar-Rogers and Otero, 2008). These trackways were attributed to this ichnogenus for its wide-gauge trackway, step angle greater than 100 , and the absence of claw marks in the manus. The theropod is distinguished by the separation of the digits with acuminate distal ends. Several hundreds of prints were also identified from photographs taken by amateurs, in different crops of this sedimentary sequence, data that still requires systematic recopilation. These sedimentary sequences extend for several kilometers and it is possible that several dinosaur types remain yet to be found. Biese (1961) mentions the presence of remains of a Megalosauridae in sandstones from the Tithonian of the Cerritos Bayos Formation. This finding could not be confirmed since the ultimate destiny of this material is unknown. 4. Cretaceous In situ Cretaceous prints are documented from the Codocedo ravine, the Tambería ravine, Los Pantanos, cerros bravos and cerro La Isla (Bell and Suárez, 1989). These tridactyl prints may correspond to theropods. Fragmentary dinosaur bones were collected from cerro La Isla. A caudal vertebra was mentioned by Bell and Suárez (1989) (identified by A.C. Milner) as belonging to an “Iguanodontid”. This would be the only reference to skeletal remains of ornithischians in Chile, however, this material is not available and its destiny is unknown, thus it is impossible to confirm this specimen’s taxonomic assignation. Also from cerro La Isla, a sauropod ulna or fibula is mentioned but as in the previous case the destiny of this important material is unknown. In the upper Jurassicelower cretaceous range, great assemblages of dinosaur prints are known from the Chacarilla Formation in northern Chile. At “site III” of the Chacarilla ravine and unusual assemblage of theropod dinosaurs is described (80% of ichnites referred to this group, the remaining 20% belonging to ornithopods) where at least two pedal morphotypes can be distinguished (Rubilar-Rogers et al., 2008). These generally are large predators which indicate these carnivores were established during the lower Cretaceous along the occidental margin of Gondwana. In other outcrops of the same ravine there are narrow and wide-gauged prints of trackways of sauropods (related to the ichnogenera Parabrontopodus and Brontopodus) as well as some trackways possibly belonging to Thyreophora. Toward the base of the Chacarilla Formation, ornithopod prints were reported that are consistent with a Cretaceous age for this formation (Blanco et al., 2000; Rubilar-Rogers et al., 2000). The prints of the Chacarilla Formation were made in a meandriform river paleoenvironment. Tridactyl prints were reported in Huatacondo ravine by Salinas et al. (1991b), who suggested these could belong to theropods and ornithopods. The first new species of non-avian dinosaur ever discovered in Chile A. chilensis Kellner et al. (2011) was found in the Tolar Formation. This titanosaur comprises a right femur, a proximal end of a humerus, two dorsal vertebrae, two posterior caudal vertebrae, dorsal ribs and a plate-shaped bone referred as part of a sternal plate (Kellner et al., 2011, Fig. 3). It is worth noting that the remains of A. chilensis reveal a gracile titanosaur with femur proportions different to those of titanosaurs of similar body size. In order to establish the phylogenetic position of A. chilensis, a preliminary cladistic analysis using parsimony was performed for

248

D. Rubilar-Rogers et al. / Journal of South American Earth Sciences 37 (2012) 242e255

this review. The data matrix used here corresponds to the one proposed by Wilson (2002), which was specifically designed to test sauropod phylogeny at the genus level. It was possible to score only nineteen characters for A. chilensis, out of a total of 324 characters in Wilson’s matrix (presented in Appendix). The analysis of the matrix was performed using PAUP* software version 4.0 (Swofford, 2003) with ACCTRAN as character-state optimization and unordered multistate characters. In this analysis A. chilensis is included as a Lithostrotia (Fig. 4), a clade that includes the most recent common ancestor of Saltasaurus and Malawisaurus and all its descendants (Upchurch et al., 2004). A heuristic search produced 21 most parsimonious trees (MPTs) with a length of 434 steps (CI ¼ 0.6; RI ¼ 0.8). In the strict consensus tree A. chilensis appears inside Lithostrotia group more closely related to Saltasaurus than to Malawisaurus, in a node that includes a politomy with Saltasauridae, Nemegtosaurus, Rapetosaurus and Titanosaurus colberti. Similar results were obtained with bootstrap and jackknife analysis. In the 50% majority rule bootstrap analysis of the matrix (using a search with 100 replicates) the tree topology shows a wellsupported node for Saltasauridae (clade formed by the most recent common ancestor between Saltasaurus and Neuquensaurus), Rapetosaurus, Nemegtosaurus, T. colberti and A. chilensis. In a posterior phylogenetic analysis Curry-Rogers (2005) proposed a more

inclusive definition for Saltasauridae, which includes genera such as Malawisaurus, Rapetosaurus, Nemegtosaurus and Titanosaurus considered non saltasaurids by Wilson (2002). However, the database of Curry-Rogers (2005) is of little help, because in the matrix there are a lot of uninformative characters, resulting in wide polytomies and low support values for titanosaur ingroups. Additionally a revision of all titanosaur taxa is beyond the purpose of the present work. A broader data set (not available at the moment) with more characters may change the hypothesis of relationships of this specimen specially in reference to Saltasauridae. Up to the moment another specimen referred to the Lithostrotia clade is reported for the Cretaceous of the Atacama Region (SNGM-1; Rubilar-Rogers et al., in prep.), however, the scarce materials of A. chilensis and the geographic distance of these records (approximately more than 700 km) makes it difficult to comment on the relationship between these specimens. An interesting fact is that in comparison with other titanosaurs of the same size, A. chilensis has slender proportions. Under this assumption we plotted measurements in different sections of the femur of saltasaurids such as Titanosaurus falloti, Titanosaurus robustus, Saltasaurus loricatus, Opisthocoelicaudia skarszinsky, Rapetosaurus krauseni, Alamosaurus sanjuanensis, Magyarosaurus dacus, Neuquensaurus australis and the specimens referred to the

Fig. 3. Bones of Atacamatitan chilensis, so far the only new species of dinosaur discovered in Chile. AeH, dorsal vertebrae in AeB, EeF, anterior view and CeD, GeH lateral view; IeL, rib; MeN, humerus; and OeP, right femur. nc: neural channel, pl: pleurocoel, lb: lateral bulge. Scale bar equals 10 cm. Illustrations: Jocelyn Navarro.

D. Rubilar-Rogers et al. / Journal of South American Earth Sciences 37 (2012) 242e255

249

Fig. 4. Consensus tree of the 21 most parsimonious trees. IC: 0.66; IR: 0.8; TL: 434, indicating Phylogenetic position of A. chilensis based on a matrix preformed by Wilson (2002) for sauropod dinosaurs.

last species MCS-5/28 and MCS-5/25 indicated as Neuquensaurus C and Neuquensaurus D (Fig. 5). In the case of A. chilensis the measurement of the distal condyles is only estimated, due to diagenetic distortion. In the graph it is possible to see the gracile limbs of the Chilean specimen. The evolution of these differences may relate to geographic isolation or special environmental conditions during the cretaceous in northern Chile, restricted to a slender continental border surrounded by epicontinental seas that were only connected to the mainland by its southern portion, a predominant condition during the cretaceous in the north and central Chile. The evolution of these slender-limbed titanosaurs could relate to this restricted area, which could be compared with the island rule of ecological theory (e.g. Foster, 1964). This hypothesis requires a comparison with more taxa and a deeper study of geological conditions during the Upper Cretaceous in the Atacama Desert, including the dynamics of deserts in northern Chile. Slender limbs may reflect a general evolutionary trend of a linage including the Chilean specimens. To discuss this possibility, a complete phylogenetic analysis, including some taxa suspected of dwarfism (e.g. Magyarosaurus) is necessary (Rubilar-Rogers, 2008). Elements of another sauropod specimen referred to Titanosauriformes (Rubilar-Rogers, 2005) have been recovered from the same Tolar Formation which indicates the potential for further discovery of more specimens.

Large-sized bones (SGO.PV. 322) were found in the Pajonales Formation (Upper Cretaceous). P. Taquet (in Salinas et al., 1991b) identified these remains as titanosaurian sauropods. Since only the diaphysis of these bones is preserved, it is impossible to identify them at a less inclusive level than Sauropoda (Rubilar-Rogers, 2003). Several fossil remains of titanosaurian sauropods have been reported for the Viñita Formation, including the incomplete proximal portion of a right humerus, part of a left scapulo-coracoid, rib fragments, ischium fragment, the proximal portion of a metapodial bone, and an incomplete centrum of a caudal vertebra. Based on these materials Casamiquela et al. (1969) distinguish at least two kind of titanosaurs. The proximal portion of the humerus was compared and referred to the genus Antarctosaurus (cf. Antarctosaurus wichmannianus), while the scapulo-coracoid was reconsidered to be an undetermined titanosaur. Rubilar-Rogers (2003) pointed out that the affinities of the humerus fragment to A. wichmannianus, cannot be discussed since this element is not used in the diagnosis of this taxon (Powell, 1986). More recently, additional material has been found and described for this same site. This includes the anterior half of a large dorsal vertebra, which preserves the base of the spine and part of the neural arch (SGO.PV. 959, Vargas et al., 2000). Additionally two teeth assigned to titanosaurs were reported (Salinas and Marshall, 1991; see also Rubilar-Rogers, 2003). The distal ends are preserved which

250

D. Rubilar-Rogers et al. / Journal of South American Earth Sciences 37 (2012) 242e255

An interesting specimen of titanosaur was found in the Hornitos Formation comprising several axial and appendicular elements. This material is currently under study (Rubilar-Rogers et al., in prep.). Previously Chong (1985) reported a fragment of a left humerus and rib segments from the same geological unit that was identified and assigned to the Titanosauridae by Bonaparte (in Chong, 1985). The only material of Mesozoic birds known from Chile proceeds from the Quiriquina Formation, an isolated metatarsal referred to a species of diving bird Neogaeornis wetzeli Lambrecht (1929). Another similar element was mentioned by Oliver-Schneider (1940) found in San Vicente bay, however, it was not illustrated nor adequately described. Salinas et al. (1991a) reported remains of a large bone from the strata of Quebrada Blanca that was attributed to a dinosaur, possibly a sauropod. Salinas et al. (1991a) mentioned the presence of dinosaur bones and “large bones” in cerro Negro and cerro Mesa, both localities belonging to the Las Chilcas Formation. However, the destiny of these materials is unknown. Thus, these may even belong to marine reptiles since they are found in predominantly marine levels. 5. Paleogene

Fig. 5. Charts showing femur width in different specimens of titanosaurs (n ¼ 1 for each species, except Neuquensaurus C and D). A, ratio between the width at midshaft and total length in natural logarithmic scale. B, width of femur across the shaft: 1) width of condyles, 2) width at the distal quarter, 3) width at the midshaft, 4) width at proximal quarter, 5) width at the lateral bulge level, 6) width at femoral head level. Note that the Chilean specimen (A. chilensis) show low values of width/length ratio (below) and greater relative length than width values (above).

resemble pencil tips and are 13.0  4.6 mm and 7.75  4.5 mm respectively, with the larger one possessing, in transeversal section, an ellipse of 3.0  4.0 mm. In the smaller tooth, it is possible to see a weared surface toward lingual, while the larger tooth a wear surface is hardly visible. This suggests a recently erupted tooth or alternatively a juvenile individual. The only known cranial remains of non-avian theropod dinosaurs proceed from the “Monumento Natural Pichasca (Pichasca Natural Monument) in the Viñita Formation. These consist of two isolated teeth reported by Salinas and Marshall (1991) and referred by these authors to coleurosaurs. Rubilar-Rogers (2003) described these teeth and assigned them as Theropoda indet. The specimens are small lateral teeth, with no preserved root (crown heights of 16.6 and 12.0 mm). The teeth are laterally compressed: in the best, larger, specimen the fore-aft basal length is the double of the basal width. The basal cross section is not preserved but the tooth tends to be nearly symmetrical and teardrop-shaped. It possesses 3 denticles/mm (per millimeter) along the posterior carina and 4 denticles/mm along the anterior one. The denticles are generally low. The denticles in anterior and posterior borders are slightly pointed toward the apex of the crown. On the posterior carina, denticles are almost as long as they are wide. Blood grooves are generally shallow and poorly defined. They are oriented slightly toward the axis of the tooth. This kind of morphology is very similar to an undescribed non-avian theropod closely related to dromaeosaurids found in the cretaceous of Madagascar (Fanti and Therrien, 2007). Nevertheless possible affinity to abelisaurid cannot be excluded.

The fossil record of Dinosauria in Chile after the K/T event is restricted to the living order Neornithes of modern birds. The fossil record of birds in Chile has been revised in several publications (Chávez, 2007a; Sallaberry et al., 2008, 2010a) but the increasing work on the group and different localities have made every review rapidly obsolete. The fossil record of birds in the Paleogene is represented by levels strictly of middle to late Eocene age from central Chile (Fm. Algarrobo) and best represented in southernmost Chile (with three localities) (Sallaberry et al., 2010b; Yury-Yáñez et al., in press), contrary to the previous assumption that Paleogene marine vertebrate-bearing strata were absent in the Chilean record (Clarke et al., 2003; Chávez, 2007a). Paleogene fossil birds are almost entirely restricted to the order Sphenisciformes (penguins), marine diving birds exclusively from the Southern Hemisphere, which lost their ability to fly. Because of their heavy bones, and their high colonial concentrations, is one of best represented marine vertebrates during the Cenozoic (de la Cruz, 2007). Also the record of aquatic birds attributed to Ardeidae and a record of a supposed marine bird is considered in the currently understudied Chilean Paleogene (Sallaberry et al., 2010b; YuryYáñez et al., in press). Paleogene fossil penguins are recognized from three localities in Magallanes Region, southernmost Chile, described in Sallaberry et al. (2010b): Río de Las Minas (Loreto Formation Hoffstetter et al., 1957), Sierra Dorotea (Río Turbio Formation Feruglio, 1938; sensu lato; emend. Hünicken, 1955; sensu Malumián and Caramés, 1997), and Sierra Baguales (Río Baguales Formation, Cecioni, 1956). In these formations, fossil penguins are represented by two fragments: an ungual phalanx, and a tarsometatarsus in Río de las Minas. Even though the tarsometatarsus is very diagnostic in penguin taxonomy, the poor preservation of this fossil does not allow a more accurate designation. However, the high level of fusion of the metatarsals is considered a common feature of Paleogene penguins, not shared by the crown group Spheniscidae (Göhlich, 2007) that comprises the extant species and dates back to the middle Miocene. The ungual phalanx also is considered similar to one described from the late Eocene of Seymour Island, Antarctica (fig. 19:iej; Jadwiszczak, 2006a). Sierra Baguales represents the poorest record of fossil penguins: two heavily eroded fragments of humeri which are recognized by the flattened cross section that is characteristic of penguins.

D. Rubilar-Rogers et al. / Journal of South American Earth Sciences 37 (2012) 242e255

In contrast, Sierra Dorotea yields the largest amount of fossil penguins with seven remains, including one that can be assigned at genus level as Palaeeudyptes. This genus represents one of the most widespread fossil penguins from the Paleogene being registred in Australia, New Zealand, and Antarctica (besides Chile). Jadwiszczak (2011) proposed it to be congeneric with the endemic penguin fossils from southern Peru, such as, Inkayacu or Icadyptes (Clarke et al., 2007, 2010). More recently it has been proposed that both genera of giant penguins, Anthropornis and Palaeeudyptes from the Eocene of Antarctica should be considered monoespecific (Jadwiszczak and Mörs, 2011) and not two separate species. Highly abundant in the marine La Meseta Formation from Seymour Island are the fossils of penguins. Assignations of bones different to the tarsometatarsus, the most diagnostic element of Eocene penguins (Myrcha et al., 2002) were based on dubious criteria, such as, size (Jadwiszczak, 2006b) highly criticized (Tambussi et al., 2006). The finding of articulated skeletons of Palaeeudyptes gunnari allows correlating bones for which taxonomical criteria were problematic such as the humerus (AcostaHospitaleche and Reguero, 2010). In the light of the new data it can be confirmed that Chilean humerus is assignable to Palaeeudyptes, confirming the criteria of Sallaberry et al. (2010b). Two size classes of fossil penguins are found in the Chilean Eocene strata. Although only one big sized humerus could be recognized at the genus level, the remaining bones show size affinities with other medium and small sized genera from the Eocene of Antarctica such as Marambiornis, Mesetaornis or Delphinornis (Sallaberry et al., 2010b). Non spheniscid remains are only known from a record assigned to Ardeidae also from the Sierra Dorotea locality, a proximal fragment of tibiotarsus lacking an extension from the crista cnemialis cranialis in proximal direction, as in other aquatic birds assigned to this family, suggesting also it was a non-exclusively marine environment (Sallaberry et al., 2010b). From strata of Algarrobo, central Chile, an incomplete fragmentary femur is the only record of an Eocene bird from this locality. This does not represent a fossil penguin, and thus poses question about the environment and taphonomical influences during depositation of the sediments in this locality. It also comprises a locality that is intermediate in latitude between southernmost Chile, Antarctica and fossil penguin localities in Southern Peru (Yury-Yáñez et al., in press). The fragmentary nature of the fossil does not allow more specific taxonomic affinities, but in general anatomy it could be related to an aquatic bird, most probably a procelariid. 6. Neogene The Neogene fossil record of modern birds is the most studied and abundant of the order Dinosauria. Regardless of the enormous localities of Cenozoic vertebrates from continental sediments studied during the last decades (Croft et al., 2008), almost no bird has been recorded from continental levels, with the exception of Meganhinga chilensis. In this sense, as with the Paleogene record, most birds are also from marine localities in the Neogene. We will introduce first the marine taxa (given the amount of data available) and conclude with the fewer continental records. Three formations northern to 30 S are the most studied and yield the highest amounts of fossil birds. These are, from North to South: La Portada Formation (late MioceneePliocene, Antofagasta Region), Bahía Inglesa Formation (late MioceneePliocene, Atacama Region) and the Coquimbo Formation (middle Miocene-Pliocene, Coquimbo Region). In the central part of the country, isolated remains have been recorded in the Horcón Formation (Pliocene, Valparaíso Region). The only exclusively continental formation with bird remains is the lacustrine Curamallín Formation (Miocene) in the Biobio Region.

251

Fossil penguins are again the most remarkable group (in number and diversity), including several endemic taxa. All Neogene records belong to the crown group Spheniscidae and particularly to extant genera, with the exception of one record of a humerus cf. Palaeospheniscus from the Coquimbo Formation (AcostaHospitaleche et al., 2006a). This extinct genus is considered in phylogenetical analysis just outside the crown group and is recorded originally in the early Miocene of Argentinean Patagonia (Acosta-Hospitaleche et al., 2007). One enigmatic tarsometatarsus from the Bahía Inglesa Formation is attributable to Spheniscidae cf. Palaeospheniscus in the size range of P. biloculata, but preservation does not allow assessing the presence of this genus with certainty in the late Miocene of Chile (Soto-Acuña et al., 2008). Records from Bahía Inglesa Formation assigned to Argentinean genera (such as Paraptenodytes or Palaeospheniscus) were reassigned to extant taxa, particularly cranial remains. The taxonomical problem of Miocene Chilean penguins have been discussed elsewhere, and here we will only be considering recent assignments accepted in previous reviews, in which all cranial and appendicular remains (with the exceptions listed above) are restricted to extant genera of the crown group (Chávez, 2007a,b; Acosta-Hospitaleche and Canto, 2005; Acosta-Hospitaleche and Canto, 2007; Acosta-Hospitaleche et al., 2005; Soto-Acuña et al., 2008). Three neogene endemic species have being described: Spheniscus chilensis Emslie and Guerra-Correa (2003), Pygoscelis grandis Walsh and Suárez (2006), and Pygoscelis calderensis AcostaHospitaleche et al. (2006b). The first one from the La Portada Formation is a specimen of the penguin genus Spheniscus that is present in South American Atlantic and Pacific coasts comprising the species S. humboldti and Spheniscus magellanicus and the Galápagos penguin S. mendiculus. S. chilensis is a medium small sized penguin Pliocene in age. P calderensis and P. grandis are both recovered from different levels of the Bahía Inglesa Formation. P. calderensis was recovered from late Miocene levels of phosphatic deposits and comprises a species in the size range of the extant members of the genera. P. grandis is a large sized extinct species that was recovered from Pliocene levels of the Bahia Inglesa Formation near the size of the extant king penguin (Aptenodytes forsteri). From the late Miocene levels of Bahía Inglesa Formation there are records belonging to the extant genus Spheniscus and characterized by their big size. Spheniscus urbinai and Spheniscus megaramphus are represented by several neurocrania, an isolated rostrum and appendicular bones (Soto-Acuña et al., 2008; Chávez, 2007c, 2006). Only S. urbinai is known from associated skeletons from the levels of “El Morro” locality from the Bahía Inglesa Formation (Yury-Yáñez et al., 2009) and is also represented (by cranial remains) in the Chañaral de Aceituno locality from the Coquimbo Formation (Chávez, 2005). Besides Spheniscidae, seven other families of Neornithes are known from the Chilean Neogene fossil record: Diomedeidae, Procellariidae, Phalacrocoracidae, Sulidae, Anhingidae, Falconidae and Pelagornithidae. The order Procellariiformes is the second best represented in Bahía Inglesa Formation (after penguins) and comprises two families. Diomedeidae (mollymawks or albatrosses) is recognized by cranial remains of the genus Thalassarche (according to Nunn et al., 1996) or Diomedea (Walsh and Hume, 2001). Procellariidae (petrels and others) is represented by several genera currently under study, recognizing at least the tribe Puffininni (particularly the genus Calonectris, Yury-Yáñez et al., 2008), gadfly petrels comparable to Pterodroma, petrels related to Pagodroma, a procelariid of uncertain affinities (probably Pterodroma, YuryYáñez et al., 2010a) and the genus Pachiptyla (Sallaberry et al., 2007). The diversity of sulids (also exclusively from Bahía Inglesa Formation) comprises big sized forms with affinities to known

252

D. Rubilar-Rogers et al. / Journal of South American Earth Sciences 37 (2012) 242e255

Fig. 6. Pelagornis chilensis, the most complete pelagornithid worldwide. A, cranium in lateral view. B, mounted skeleton. C, cranium in palatal view. Fur, furrow; nar, narial opening; nvf, neurovascular foramen; qud, quadrate; fos, fossae for reception of the mandibular pseudo-teeth. Image by S. Tränkner.

species in Pisco Formation (Peru), and two other size classes, all recognized as belonging to the genus Sula. Three forms of Sulidae are known (Walsh and Hume, 2001; Chávez and Stucchi, 2006; Soto-Acuña et al., 2009) Sula cf. variegata, Sula magna and Sula cf. sulita. S. magna should be considered the best represented based in cranial remains. Other family, Phalacrocoracidae, is based on appendicular bones that were described by Walsh and Hume (2001). With the Neogene marine avian fauna, the Pelagornithidae is the most outstanding bird family, typically known from Paleogene and Neogene levels from every continent. Until now, in Chile, it is only recognized from the late Miocene of Bahía Inglesa Formation based on several isolated remains and the complete articulated skeleton of Pelagonis chilensis, which Mayr and Rubilar-Rogers (2010) considered as the bird with the largest well established wingspan, within both living and extinct birds (Fig. 6). This specimen is also important due to its exquisite preservation, allowing cranialepostcranial correlations which were impossible until this finding. Based on Mayr and Rubilar-Rogers (2010), it is highly probable that all Bahía Inglesa Formation material (several isolated bones) belong to the genus Pelagornis, coinciding with earlier identifications (Chávez et al., 2007). Undescribed fossil birds from the Pliocene of the Horcón Formation have been mentioned (Carrillo-Briceño et al., 2011) as Charadriiformes, Sphenisciformes and Phalacrocoracidae, but at least one fossil of Spheniscus from this unit is recognized at the genus level (Yury-Yáñez et al., 2010b). Two records of Neogene birds are ascribed as the only nonmarine birds, the Falconidae Milvago sp. from La Portada Formation (Emslie and Guerra Correa, 2003) and M. chilensis described as flightless and big sized snake bird (Anhingidae; Alvarenga, 1995). 7. Quaternary A large number of unpublished materials (hundreds of isolated specimens) have been recovered from the Pleistocene of San Vicente de Taguatagua, mainly from plaster jackets of vertebrate remains recovered by Lautaro Núñez and Rodolfo Casamiquela in the 1980’s. These comprise well-preserved and diagnostic remains that will allow determining temporal variation in the taxa composition of the zone from the Pleistocene to present. Bird remains have also been found at the Pleistocene locality of Pilauco Bajo, in the city of Osorno which have been informally mentioned and are currently under study (Montero et al., 2008). The collection of the department of Geology of the University of Chile houses undetermined fragments from the Pleistocene of Mocha Island of penguins of similar size to the modern genus Spheniscus that were collected by Tavera and Veyl in 1958, but remain unstudied.

8. Conclusions and perspectives No dinosaur remains have been recorded from the Triassic period in Chile. However, this trend may be more related to the lack of systematic field work rather than the absence of such remains. The Triassic outcrops of the strata of El Bordo, in the Antofagasta Region, are auspicious since they consist of a sequence of lacustrine deposits where two forms of non-dinosaurian archosaurs have been found. Projected prospection of such outcrops should be a priority because of the great importance that these levels represent for understanding the evolutionary history of dinosaurs. For now, Jurassic dinosaurs are scarcely represented. The discovery of theropod skeletons in the Aysen Region and the deposits of dinosaur footprints from the Antofagasta Region are promising. Doubtless, more material of theropod dinosaurs can be recovered from the strata of “El Toqui” and possibly new prints will be documented in quebrada Arca. Cretaceous deposits have delivered a very abundant record of dinosaur prints that allow us to know about the fauna of the time despite the absence of skeletal remains. Some formations of this period overlie Jurassic deposits, such that it becomes possible to understand changes in faunal composition across these periods. Additionally, the titanosaurs represent the best-documented nonavian dinosaurs in Chile. Doubtless, new forms of these dinosaurs will continue to be discovered in sites like La Higuera ravine in the Atacama Region, where new and more complete specimens are likely to be collected. As mentioned above, teeth possibly belonging to a dromaeosaurid are the only cranial remains of non-avian dinosaurs currently known from Chile. If this identification is correct, this evidence would be the first record of this kind of dinosaur from Chile and one of the few currently known for Gondwana. The only record of birds from the cretaceous in Chile is two isolated tarsometatarsi from the Quiriquina Formation. This material is important since it is one of the few occurrences of Mesozoic birds known for Gondwana. New field work in this formation is necessary in order to find new evidence of these birds. Until now, there is no information from Chile about other terrestrial taxa that must have co-existed with dinosaurs during the Mesozoic, such as mammals and ophidians. This fact is defined mainly by the lack of systematic search for other components of the Mesozoic biota. Reports of lizards and amphibians must be corroborated since current mentions are unclear and the destiny of these materials is unknown. Continental Mesozoic vertebrates are very important to narrow down possible ages of continental levels (Blanco et al., 2000; Rubilar-Rogers, 2003). Thus they will continue to be a good tool for establishing biochrones of Mesozoic continental levels in Chile.

D. Rubilar-Rogers et al. / Journal of South American Earth Sciences 37 (2012) 242e255

Among perspectives for research on dinosaurs and other Mesozoic continental vertebrates, an interesting problem is the degree of endemism that may have evolved in relation to the separation produced by epicontinental seas. Acknowledgments We are very grateful of the editors of JSES specially of Timothy Horscroft for his invitation to publish this paper. Many thanks to Jocelyn Navarro who made the line drawings of Atacamasaurus chilensis. Conicyt-Chile funded PhD degree of D. R.-R. and C.S.G. and master degree of R. Y.-Y. We thank Jurassic Foundation for field support. Appendix List of characters codified for A. chilensis based in the matrix from Wilson (2002). 10 A. chilensis

20

30

40

50

?????????? ?????????? ?????????? ?????????? ?????????? 60

70

80

90

100

?????????? ?????????? ??????11?? ?????????? ?????????? 110

120

????11???? ?????????? ?????????? 160

170

130

140

10?1?????? ????????1?

180

190

200

????????11 01???????? ?????????? ?????????? ?????11211 210

220

230

01???????? ?????????? ?????????? ????

References Acosta-Hospitaleche, C., Canto, J., 2005. Primer registro de cráneos asignados a Palaeospheniscus (Aves, Spheniscidae) procedentes de la Formación Bahía Inglesa (Mioceno Medio-Tardío), Chile. Revista Chilena de Historia Natural 78, 489e495. Acosta-Hospitaleche, C., Canto, J., 2007. Comentarios acerca de “Observaciones sobre la presencia de Paraptenodytes y Palaeospheniscus (Aves: Sphenisciformes) en la Formación Bahía Inglesa, Chile”. Revista Chilena de Historia Natural 80, 261e264. Acosta-Hospitaleche, C., Tambussi, C.P., Canto, J., 2005. Pingüinos (Aves, Sphenisciformes) fósiles de la colección del Museo Nacional de Historia Natural de Santiago, Chile. Boletín del Museo Nacional de Historia Natural 54, 141e151. Acosta-Hospitaleche, C., Chávez, M., Fritis, O., 2006a. Pingüinos fósiles (Pygoscelis calderensis sp. nov.) en la Formación Bahía Inglesa (Mioceno Medio-Plioceno), Chile. Revista Geológica de Chile 33 (2), 327e338. Acosta-Hospitaleche, C., Canto, J., Tambussi, C.P., 2006b. Pingüinos (Aves, Spheniscidae) en Coquimbo (Mioceno medio e Plioceno tardío), Chile y su vinculación con las corrientes oceánicas. Revista Española de Paleontología 21 (2), 115e121. Acosta-Hospitaleche, C., Tambussi, C.P., Donato, M., Cozzuol, M., 2007. A new Miocene penguin from Patagonia and its phylogenetic relationships. Acta Paleontologica Polonica 52 (2), 299e314. Acosta-Hospitaleche, C., Reguero, M., 2010. First articulated skeleton of Palaeeudyptes gunnari from the late Eocene of Isla Marambio (Seymour Island), Antarctica. Antarctic Science 22, 289e298. Achurra, L.E., Lacassie, J.P., Le Roux, J.P., Marquardt, C., Belmar, M., Ruiz-del-Solar, J., Ishman, S.E., 2009. Manganese nodules in the Miocene Bahía Inglesa Formation, north-central Chile: petrography, geochemistry, genesis and palaeoceanographic significance. Sedimentary Geology 217, 128e139. Aguirre, L., Egert, E., 1965. Cuadrángulo Quebrada Marquesa, provincia de Coquimbo. Instituto de Investigaciones Geológicas. Carta Geológica de Chile 15. Santiago. Alvarenga, H., 1995. A large and probably flightless Anhinga from the Miocene of Chile. Acta Palaeornithologica e Courier Forschunginstitut Senckenberg 181, 149e161.

253

Baeza, L., 1979. Distribución de facies sedimentarias marinas en el Jurásico de Cerritos Bayos y zonas adyacentes, norte de Chile. In: Actas Congreso Geológico Chileno, Arica, 3, 2, pp. 45e61. Bell, M., Suárez, M., 1989. Vertebrate fossils and trace fossils in Upper Jurassic-Lower Cretaceous red beds in Atacama Región, Chile. Journal of South American Earth Sciences 2, 351e357. Biese, W., 1961. El Jurásico de Cerritos Bayos. Instituto de Geología, Publicación 19. Universidad de Chile. Biró-Bagóczky, L., 1982. Revisión y redefinición de los ‘Estratos de Quiriquina’, Campaniano-Maastrichtiano, en su localidad tipo, en la Isla Quiriquina, 36 37’ Lat. Sur, Chile, Sudamérica, con un perfil complementario en Cocholgüe. In: Actas III Congreso Geológico Chileno, Concepción, vol. 1, pp. 29e64. Blanco, N., Tomlinson, A., Moreno, K., Rubilar, D., 2000. Importancia estratigráfica de las icnitas de dinosaurios presentes en la Formación Chacarilla (Jurásico-Cretácico Inferior), Región de Tarapacá, Chile. In: Actas IX Congreso Geológico Chileno, pp. 441e445. Brüggen, J., 1915. El Cretáceo de Algarrobo. Sociedad Imprenta Litográfica Barcelona, SantiagoeValparaíso, 15 pp. Brüggen, J., 1942. Geología de la Puna de San Pedro de Atacama y sus formaciones de areniscas y arcillas rojas. Congreso Panamericano de Ingeniería de Minas y Geología, Primera parte, Santiago, vol. 2, pp. 342e367. Carrillo-Briceño, J., Nielsen, S.N., Landaeta, M.F., Soto, E.H., Andrade, V., 2011. Vertebrados marinos del Plioceno de la Formación Horcón, región de Valparaíso, Chile Central: análisis preliminar. In: IV Congreso Latinoamericano de Paleontología de Vertebrados, San Juan, CD Abstracts, p. 77. Casamiquela, R., 1970. Los vertebrados fósiles de Tagua Tagua. Primer informe, Museo Nacional de Historia Natural (inédito). Casamiquela, R., 1976. Los vertebrados de Tagua Tagua. In: Actas del Primer Congreso Geológico Chileno, Facultad de Ciencias Físicas y Matemáticas, Universidad de Chile. Casamiquela, R.M., 1980. Nota sobre restos de un reptil aetosauroideo (Thecodontia, Aetosauria) de Quimal, Cordillera de Domeyko, Antofagasta. Prueba de la existencia del Neotriásico continental en los Andes del norte de Chile. In: Actas II Congreso Argentino de Paleontología y Bioestratigrafía, y I Congreso Latinoamericano de Paleontología, vol. 1, pp. 135e142. Casamiquela, R.M., Fasola, A., 1968. Sobre pisadas de dinosaurios del Cretácico inferior de Colchagua (Chile). Universidad de Chile, Departamento de Geología y Geofísica, 164 pp. Casamiquela, R.M., Corvalán, J., Franquesa, F., 1969. Hallazgo de dinosaurios en el Cretácico Superior de Chile. Su importancia cronológica-estratigráfica. Instituto de Investigaciones Geológicas, Boletín 25, 31. Cecioni, G., 1956. Distribuzione verticale di alcune Kossmaticeratidae della Patagonia cilena. Bolettino Societa Geológica Italiana 74, 141e148. Charrier, R., Pinto, L., Rodríguez, M.P., 2007. Tectonostratigraphic evolution of the Andean Orogen in Chile. In: Moreno, T., Gibbons, W. (Eds.), The Geology of Chile. The Geological Society of London, London, pp. 21e114. Chávez, M., 2005. Una nueva localidad con aves fósiles en la región de Atacama, Chile. In: Actas VIII Congreso Chileno de Ornitología, Chillán, p. 47. Chávez, M., 2006. Presencia de Spheniscus urbinai (Aves: Sphenisciformes) en la Formación Bahía Inglesa: nueva evidencia. In: Actas IX Congreso Argentino de Paleontología y Bioestratigrafía, Córdoba, vol. 103. Chávez, M., 2007a. Fossil Birds of Chile and Antarctic Peninsula, 65(4). Arquivos do Museu Nacional, Rio de Janeiro, pp. 551e572. Chávez, M., 2007b. Observaciones sobre la presencia de Paraptenodytes y Palaeospheniscus (Aves: Sphenisciformes) en la Formación Bahía Inglesa, Chile. Revista Chilena de Historia Natural 80, 255e259. Chávez, M., Stucchi, M., 2006 Los piqueros fósiles (Aves: Sulidae) del Neógeno en el Pacífico sudeste. In: Actas IX Congreso Argentino de Paleontología y Bioestratigrafía, Córdoba, vol. 104. Chávez, M., Stucchi, M., Urbina, M., 2007. El registro de Pelagornithidae (Aves: Pelecaniformes) y la avifauna neógena del Pacífico Sudeste. Bulletin de l’Institut Français d’Études Andines 36, 175e197. Chávez, M., 2007c. Presencia de Spheniscus megaramphus Stucchi et al. 2003 (Aves: Sphenisciformes) en la Formación Bahía Inglesa, Chile. Boletín de la Sociedad Geológica del Perú 102, 101e107. Chong, G., 1985. Hallazgo de restos óseos de dinosaurios en la Formación Hornitos, Tercera Región (Atacama, Chile). In: Actas IV Congreso Geológico Chileno, vol. 1, pp. 152e159. Chong, G., Gasparini, Z., 1976. Los vertebrados Mesozoicos de Chile y su aporte geopaleontológico. In: Actas VI Congreso Geológico Argentino, vol. 1, pp. 45e67. Clarke, J.A., Olivero, E.B., Puerta, P., 2003. Description of the earliest fossil penguin from South America and first Paleogene vertebrate locality of Tierra del Fuego, Argentina. American Museum Novitates 3423, 18. Clarke, J.A., Ksepka, D., Stucchi, M., Urbina, M., Giannini, N., Bertelli, S., Narváez, Y., Boyd, C.A., 2007. Paleogene equatorial penguins challenge the proposed relationship between biogeography, diversity, and Cenozoic climate change. Proceedings of the National Academy of Sciences 104 (28), 11545e11550. Clarke, J.A., Ksepka, D.T., Salas-Gismondi, R., Altamirano, A.J., Shawkey, M.D., D’Alba, L., Vinther, J., DeVries, T.J., Baby, P., 2010. Fossil evidence for evolution of the shape and color of penguin feathers. Science 330, 954e995. Cortés, J., Marquardt, C., González, G., Wilke, H.-G., Marinovic, N., 2007. Cartas Mejillones y Península de Mejillones, Región de Antofagasta. Servicio Nacional de Geología y Minería. Carta Geológica de Chile, Serie Geológica Básica, Santiago 103 y 104, 58. 1 mapa escala 1:100.000.

254

D. Rubilar-Rogers et al. / Journal of South American Earth Sciences 37 (2012) 242e255

Covacevich, V., Frassinetti, D., 1990. La Fauna de Lo Abarca: Hito biocronoestratigráfico y paleoclimático en el Terciario Superior marino de Chile Central. In: Actas II Simposio sobre el Terciario de Chile, Concepción, pp. 51e71. Croft, D.A., Charrier, R., Flynn, J.J., Wyss, A.R., 2008. Recent additions to knowledge of Tertiary mammals from the Chilean Andes. In: Actas I Simposio-Paleontología en Chile, Santiago, pp. 91e96. Cruz, I., 2007. Avian taphonomy: observations at two Magellanic penguin (Spheniscus magellanicus) breeding colonies at their implications for the fossil record. Journal of Archaeological Science 34, 1252e1261. Curry-Rogers, K.A., 2005. Titanosauria: a phylogenetic overview. In: Curry Rogers, K.A., Wilson, J. (Eds.), The Sauropods: Evolution and Paleobiology, pp. 50e103. Desojo, J.B., 2003. Redescripción del aetosaurio Chilenosuchus forttae Casamiquela (Diapsida: Arcosauria): presencia de Triásico continental en el norte de Chile. Revista Geológica de Chile 30 (1), 53e63. De la Cruz, R., Suárez, M., 2006. Geología del Área Puerto Guadal-Puerto Sánchez scale 1:1.000.000. Carta Geológica de Chile 95. Servicio Nacional de Geología y Minería, Santiago, Chile. DeVries, T.J., Vermeij, G.J., 1997. Herminespina: new genus of Neogene muricid gastropod from Peru and Chile. Journal of Paleontology 71, 610e615. Emslie, S.D., Guerra-Correa, C., 2003. A new species of penguin (Spheniscidae: Spheniscus) and other birds from the late Pliocene of Chile. Proceedings of the Biological Society of Washington 116 (2), 308e316. Fanti, F., Therrien, F., 2007. Theropod tooth assemblages from the Late Cretaceous Maevarano Formation and the possible presence of dromaeosaurids in Madagascar. Acta Palaeontologica Polonica 52 (1), 155e166. Ferraris, F., Di Biase, F., 1978. Hoja de Antofagasta, Región de Antofagasta, scala 1:250.000. Instituto de Investigaciones Geológicas. Carta Geológica de Chile 30, 48. Feruglio, E., 1938. El Cretácico Superior de1 Lago San Martín (Patagonia) y de las regiones adyacentes. Physis 12, 293e342. Finger, K.L., Nielsen, S.N., DeVries, T.J., Encinas, A., Peterson, D.E., 2007. Paleontologic evidence for sedimentary displacement in Neogene forearc basins of central Chile. Palaios 22, 3e16. Foster, J.B., 1964. The evolution of mammals on islands. Nature 202 (4929), 234e235. Galli, C., Dingman, R., 1962. Cuadrángulos Pica, Alca, Matilla y Chacarilla, con un estudio sobre recursos de agua subterránea, provincia de Tarapacá. Carta Geológica de Chile 7e10, 123. escala 1:50.000. Gana, P., Wall, R., Gutiérrez, R., 1996. Mapa Geológico del área Valparaíso-Curacaví, Región de Valparaíso y Región Metropolitana, scala 1:100.000. Servicio Nacional de Geología y Minería Santiago. Garcia, F., 1967. Geología del Norte Grande de Chile. Sociedad Geológica de Chile 3, 1e138. Santiago. García, K.A., 1968. Estratigrafía del Terciario de Chile Central. In: Cecioni, G. (Ed.), Simposio sobre el Terciario de Chile, Zona Central. Andres Bello, Santiago, pp. 25e57. Gasparini, Z., 1979. Comentarios críticos sobre los vertebrados mesozoicos de Chile. In: Actas II Congreso Geológico Chileno, Arica, pp. 15e32. González, O., Vergara, M., 1962. Reconocimiento geológico de la Cordillera de los Andes entre los paralelos 35 y 38 latitud sur. Universidad de Chile. Instituto de Geología, Publicación 24, 121. González-Guarda, E., Pino, M., Prevosti, F., 2008. Primer registro en Chile de Mephitidae (Mammalia: Carnivora) en el sitio Pilauco bajo (Pleistoceno tardío), centro-sur de Chile. In: Actas III Congreso Latinoamericano de Paleontología de Vertebrados, Neuquén. Göhlich, U., 2007. The oldest fossil record of the extant penguin genus Spheniscus ea new species from the Miocene of Peru. Acta Palaeontologica Polonica 52 (2), 285e298. Gutstein, C.S., Cozzuol, M.A., Vargas, A.O., Suárez, M.E., Schultz, C.L., RubilarRogers, D., 2009. Patterns of skull variation of Brachydelphis (Cetacea, Odontoceti) from south-eastern Pacific Neogene. Journal of Mammalogy 90 (2), 215e230. Harrington, H., 1961. Geology of parts of Antofagasta and Atacama provinces of northern Chile. American Association of Petroleum Geologists, Bulletin 45 (2), 169e197. Hoffstetter, R., Fuenzalida, H., Cecioni, G., 1957. Lexique Stratigraphique International. Amérique Latine V (Fascicule 7). Chili. Centre National de la Recherche Scientifique. 13, quai Anatole-France, París-VII. Hünicken, M., 1955. Depósitos neocretácicos y terciarios del extremo SSW de Santa Cruz. Cuenca carbonífera de Rio Turbio. Revista del Instituto Nacional de Investigaciones de las Ciencias Naturales y Museo Argentino de Ciencias Naturales “Bernardino Rivadavia”, Ciencias Geológicas 4 (l), 1e164. Jadwiszczak, P., 2006a. Eocene penguins of Seymour Island, Antarctica: taxonomy. Polish Polar Research 27 (1), 3e62. Jadwiszczak, P., 2006b. Eocene penguins of Seymour Island, Antarctica: the earliest record, taxonomic problems and some evolutionary considerations. Polish Polar Research 27 (4), 287e302. Jadwiszczak, P., 2011. New data on morphology of late Eocene penguins and implications for their geographic distribution. Antarctic Science 23, 605e606. Jadwiszczak, P., Mörs, T., 2011. Aspects of diversity in early Antarctic penguins. Acta Palaeontologica Polonica 56 (2), 269e277. Jiménez – Huidobro, P., Gutstein, C.S., Sallaberry, M., Rubilar-Rogers, D., 2009. Anuros del Pleistoceno de Chile Central. Resúmenes XXIV Jornadas Argentinas de Paleontología de Vertebrados: 39, San Rafael de Mendoza, Argentina.

Kellner, A.W.A., Rubilar-Rogers, D., Vargas, A., Suárez, M., 2011. A new titanosaur sauropod from the Cretaceous of Atacama Desert, Chile. Anais da Academia Brasileira de Ciencias 83 (1), 211e219. Klohn, C., 1960. Geología de la Cordillera de los Andes de Chile Central, Provincia de Santiago, O’Higgins, Colchagua y Curicó. Instituto de Investigaciones Geológicas (Chile), Boletín 8, 95. Ladino, M., Tomlinson, A.J., Blanco, N., 1999. New constraints for the age of Cretaceous compressional deformation in the Andes of northern Chile (Sierra de Moreno, 21 e22 10’S). In: 4th International Symposium of Andean Geodynamics, Göttingen, pp. 407e410. Lambrecht, K., 1929. Neogaeornis wetzeli n. g. n. sp., der erste Kreidevogel der südlichen Hemisphäre. Paläont. Zeit., 11. Le Roux, J.P., Gómez, C., Venegas, C., Fenner, J., Middleton, H., Marchant, M., Buchbinder, B., Frassinetti, D., Marquardt, C., Gregory-Wodzicki, K.M., Lavenu, A., 2005. Neogene-Quaternary coastal and offshore sedimentation in north central Chile: record of sea-level changes and implications for Andean tectonism. Journal of South American Earth Sciences 19, 83e98. Lio, G., Novas, F., Salgado, L., Suárez, M., De la Cruz, R., 2011. First record of a nonmarine crocodylomorph (Archosauria) from the Upper Jurassic of Chile. In: IV Congreso Latinoamericano de Paleontología de Vertebrados, San Juan, Argentina. CD Abstracts 335. Lira, G., 1989. Geología del área Preandina de Calama, con énfasis en la estratigrafía y paleogeografía del mesozoico, 22 a 22 400 latitud sur, Región de Antofagasta, Chile, Ph.D. Thesis, Departamento de Geología, Universidad de Chile, 211 pp. Long, D., 1993. Late Miocene and Early Pliocene fish assemblages from the north central coast of Chile. Tertiary Research 14, 117e126. Maksaev, V., 1978. Cuadrángulo Chitigua y sector occidental del cuadrángulo Cerro Palpana. Instituto de Investigaciones Geológicas (Chile). Carta Geológica de Chile 31, 55. Malumián, N., Caramés, A., 1997. Upper Campanian-Paleogene from the Río Turbio coal measures in southern Argentina: micropaleontology and the Paleocene/Eocene boundary. Journal of South American Earth Sciences 10 (2), 187e201. Marquardt, C., Blanco, N., Godoy, E., Lavenu, A., Ortlieb, L., Marchant, M., Guzmán, N., 2000. Estratigrafía del Cenozoico Superior en el área de Caldera (26 45’e28 S). Actas IX Congreso Geológico Chileno, Puerto Varas, vol. 1, pp. 504e508. Marquardt, C.M., Fornari, A., Lavenu, G., Vargas, L., Ortlieb, J.F., Ritz, H., Philip, H., Marinovic, N., 2005. Volcanic ash dating from the Mejillones Peninsula (23 S): implications for the Neogene outer fore-arc stratigraphy, tectonics and volcanic relationships. In: Actas International Symposium on Andean Geodynamics (ISAG), Barcelona, vol. 6, 447 pp. Martill, D., Frey, E., Chong, G., Bell, M., 2000. Reinterpretation of a Chilean pterosaur and the occurrence of Dsungaripteridae in South America. Geological Magazine 137, 19e25. Martill, D., Frey, E., Bell, M., Chong, G., 2006. Ctenochasmatid pterosaurs from Early cretaceous deposits in Chile. Cretaceous Research 27 (5), 603e610. Mayr, G., Rubilar-Rogers, D., 2010. Osteology of a giant bony-toothed bird from the Miocene of Chile, with a revision of the taxonomy of Neogene Pelagornithidae. Journal of Vertebrate Paleontology 30 (5), 1313e1330. Mercado, M., 1982. Hoja Laguna del Negro Francisco. Servicio Nacional de Geología y Minería. Carta Geológica de Chile 56, 73. Montané, J., 1968. Paleo-Indian Remains from Laguna de Tagua Tagua, Central Chile. Science 161 (3846), 1137e1138. Montero, I., Recabarren, O., Moreno, K., Chávez, M., Salvadores-Cerda, L., Navarro, R.X., Pino, M., 2008. El sitio de Pilauco Bajo, Pleistoceno Superior, Centro-Sur de Chile. In: Actas III Congreso Latinoamericano de Paleontología de Vertebrados, Neuquén, vol. 162. Moreno, K., Benton, M.J., 2005. Occurrence of sauropod dinosaur tracks in the Upper Jurassic of Chile (redescription of Iguanodonichnus frenki). Journal of South American Earth Sciences 20 (3), 253e257. Moreno, K., Blanco, N., Tomlinson, A., 2004. New dinosaur footprints from the Upper Jurassic of northern Chile. Ameghiniana 41 (4), 535e544. Moreno, K., Pino, M., 2002. Huellas de dinosaurios (Theropoda-Ornitopoda-Sauropoda) de la Formación Baños del Flaco, VI Región, Chile: paleoambiente y paleoetología. Revista Geológica de Chile 29, 191e206. Moscoso, R., Nasi, C., Salinas, P., 1982. Hoja Vallenar y parte norte de La Serena. Carta Geológica de Chile 55. Servicio Nacional de Geología y Minería. Muzzio, G., 1980. Geología de la región comprendida entre el Cordón de Varillar y la Sierra de Vizcachas, Precordillera de Atacama, Thesis, Departamento de Geología, Universidad de Chile. Myrcha, A., Jadwiszczak, P., Tambussi, C.P., Noriega, J.I., Gazdzicki, A., Tatur, A., del Valle, R.A., 2002. Taxonomic revision of Eocene Antarctic penguins based on tarsometatarsal morphology. Polish Polar Research 23 (1), 5e46. Nielsen, S.N., Frassinetti, D., 1964. The Neogene Volutidae (Gastropoda: Neogastropoda) from the Pacific coast of Chile. Journal of Paleontology 81 (1), 82e102. Niemeyer, H., Muñoz, J., 1983. Hoja de La Laja, Región del Biobío. Carta Geológica de Chile 57, 52. scale 1:250.000, Servicio Nacional de Geología y Minería, Santiago. Nunn, G.B., Cooper, J., Jouventin, P., Robertson, C.J.R., Robertson, G.G., 1996. Evolutionary relationships among extant albatrosses (Procellariiformes: Diomedeidae) established from complete cytochrome-b gene sequences. Auk 113 (4), 784e801. Oliver Schneider, C., 1940. La fauna fósil de Gualpén. Revista Chilena de Historia Natural Pura. Aplicada, 49e54.

D. Rubilar-Rogers et al. / Journal of South American Earth Sciences 37 (2012) 242e255 Otero, R.A., Torres, T., Le Roux, J.P., Hervé, F., Fanning, C.M., Yury-Yáñez, R.E., RubilarRogers, D., 2012. A Late Eocene age proposal for the Loreto Formation (Brunswick Peninsula, southernmost Chile), based on fossil cartilaginous fishes, paleobotany and radiometric evidence. Andean Geology 39 (1), 180e197. Pineda, G., Emparán, C., 2006. Geología del Área Andacollo-Puerto Aldea. Carta Geológica de Chile 96, 85. scale 1:1.000.000. Servicio Nacional de Geología y Minería. Pino, H., Fuenzalida, G., 1988. Algunos rasgos geológicos de las sierras de Almeyda, San Juan y Guanaqueros, Región de Antofagasta, Unpublished, internal report ENAP (National Petroleum Company, Chile), n 280. 35 pp. Powell, J.E., 1986. Revisisón de los titanosáuridos de America del Sur, Ph. D. Thesis, Universidad Nacional de Tucumán, 340 pp. Tucumán. Rojo, M., 1985. Un aporte al conocimiento del Terciario marino: Formación Bahía Inglesa. Actas IV Congreso Geológico Chileno, Antofagasta, vol. 1, pp. 514e532. Rubilar-Rogers, D., 2003. Registro de dinosaurios en Chile. Boletín del Museo Nacional de Historia Natural 52, 137e150. Rubilar-Rogers, D., 2005. Titanosauriformes remains from Quebrada Cortadera (Tolar Formation, Upper Cretaceous), Atacama Desert, Chile. In: Actas XXI Jornadas Argentinas de Paleontología de Vertebrados, vol. 38. Rubilar-Rogers, D., 2006. Icnitas de terópodos de la Formación Baños del Flaco (Jurásico Superior), Chile central. In: Actas XI Congreso Geológico Chileno, vol. 2, pp. 117e120. Rubilar-Rogers, D., 2008. Filogenia y relaciones biogeográficas de los titanosaurios de Chile, Ph.D. Thesis, Universidad de Chile, Santiago, 187 pp. Rubilar-Rogers, D., Otero, R., 2008. Reporte de un nuevo yacimiento con icnitas de dinosaurios (Theropoda-Sauropoda) en el Desierto de Atacama. In: Actas I Simposio Paleontología en Chile, Santiago, pp. 87e90. Rubilar-Rogers, D., Moreno, K., Blanco, N., 2000. Grandes huellas de dinosaurios ornitópodos en la Formación Chacarilla (Jurásico Superior-Cretácico Inferior), I Región de Tarapacá, Chile. In: Actas IX Congreso Geológico Chileno, vol. 1, pp. 550e554. Rubilar-Rogers, D., Moreno, K., Blanco, N., Calvo, J., 2008. Theropod dinosaur trackways from the Lower Cretaceous of the Chacarilla Formation, Chile. Revista Geológica de Chile 35 (1), 175e184. Rubilar-Rogers, D., Vargas, A., Iriarte, J., Arévalo, C., Gutstein, C. A new Lithostrotia from the Atacama Region, northern Chile, in prep. Salazar, C., Stinnesbeck, W., Quinzio, L., 2010. Ammonites from the Maastrichtian (Upper Cretaceous) Quiriquina Formation in central Chile. Neues Jahrbuch für Geologie und Paläontologie Abhandlungen 257 (2), 181e236. Salgado, L., de la Cruz, R., Suárez, M., Fernández, M., Gasparini, Z., Palma-Heldt, S., Fanning, M., 2008. First Late Jurassic dinosaur bones from Chile. Journal of Vertebrate Paleontology 28 (2), 529e534. Salinas, P., Marshall, L., 1991. Los primeros dientes de dinosaurios en Chile. Revista Técnica de Yacimientos Petrolíferos Fiscales de Bolivia 12 (2), 235e236. Salinas, P., Marshall, L.G., Sepúlveda, P., 1991a. Vertebrado continentales de Paleozoico y Mesozoico de Chile. In: Actas VI Congreso Geológico Chileno, pp. 310e313. Salinas, P., Sepúlveda, P., Marshall, L.G., 1991b. Hallazgo de restos óseos de dinosaurio (saurópodos), en la Formación Pajonales (Cretácico Superior), Sierra de Almeyda, II Región de Antofagasta, Chile: implicancia cronológica. IN: Actas VI Congreso Geológico Chileno, Santiago, vol. 6, pp. 534e537. Sallaberry, M., Rubilar-Rogers, D., Suárez, M., Gutstein, C., 2007. The skull of a fossil prion (Aves: Procellariiformes) from the Neogene (Late Miocene) of northern Chile. Revista Geológica de Chile 34 (1), 147e154. Sallaberry, M., Yury-Yáñez, R., Soto-Acuña, S., Rubilar-Rogers, D., 2010a. Aves acuáticas fósiles. In: Palma, S., Baez, P., Pequeño, G. (Eds.), En Bibliografía sobre Biodiversidad Acuática de Chile, Valparaíso, pp. 431e433. Sallaberry, M., Yury-Yáñez, R.E., Otero, R., Soto-Acuña, S., Torres, T., 2010b. Eocene birds from the western margin of southernmost South America. Journal of Paleontology 84 (6), 1061e1070. Sallaberry, M., Yury-Yáñez, R., Soto-Acuña, S., Rubilar-Rogers, D., 2008. Las aves fósiles de la Formación Bahía Inglesa: hallazgos y perspectivas. In: Actas I Simposio-Paleontología en Chile, Santiago, pp. 109e115. Segerstrom, K., 1959. Cuadrángulo Los Loros, Provincia de Atacama, escala 1: 50.000. Instituto de Investigaciones Geológicas, Chile 1 (1), 33. Segerstrom, K., 1968. Geología de las Hojas Copiapó y Ojos del Salado, Provincia de Atacama. Instituto de Investigaciones Geológicas, Chile, 58. scale 1: 250, 000. Sepúlveda, P., Naranjo, J.A., 1982. Geología de la Hoja Carrera Pinto, scale 1:100.000. Carta Geológica de Chile 53, 62. Servicio Nacional de Geología y Minería. Skarmeta, J., Marinovic, N., 1981. Hoja Quillagua. (Chile), Carta Geológica 51, scale 1:250.000. 63 pp. Instituto de Investigaciones Geológicas. Soto-Acuña, S., Yury-Yáñez, R., Otero, R., Rubilar-Rogers, D., 2008. Rectificación taxonómica de materiales fósiles de Spheniscidae (Aves: Sphenisciformes) de la colección del Museo Nacional de Historia Natural. In: Actas I Simposio-Paleontología en Chile, Santiago, pp. 122e127. Soto-Acuña, S., Yury-Yáñez, R., Sallaberry, M., Rubilar-Rogers, D., 2009. Nuevos cráneos de Sulidae (Aves: Pelecaniformes) del Neógeno del Desierto de

255

Atacama, Chile. In: Actas XXIV Jornadas Argentinas de Paleontología de Vertebrados, San Rafael, vol. 57. Stinnesbeck, W., 1996. Ammonite extinctions and environmental changes across the Cretaceous-Tertiary boundary in central Chile. In: Macleod, N., Keller, G. (Eds.), The Cretaceous-Tertiary Boundary Mass Extinction: Biotic and Environmental Events. Norton Press, New York, pp. 289e302. Suárez, M., Bell, C.M., 1986. Evidencias de actividad eólica en la Formación Quebrada Monardes (Jurásico-Cretácico Inferior) en la Precordillera de Copiapó, Chile. Revista Geológica de Chile 28e29, 103e107. Suárez, M., De la Cruz, R., 1994. Estratigrafía y paleogeografía mesozoica de Aisén nororiental (45 e46 S), Chile. In: Actas VII Congreso Geológico Chileno, Concepción, vol. 1, pp. 538e542. Suárez, M., Emparan, C., 1995. The stratigraphy, geo-chronology and paleophysiography of a Miocene freshwater interarc basin, southern Chile. Journal of South American Earth Sciences 8 (1), 17e31. Suárez, M.E., Marquardt, C., 2003. Revisión preliminar de las faunas de peces elasmobranquios del Mesozoico y Cenozoico de Chile y comentarios sobre su valor cronoestratigráfico. In: Actas X Congreso Geológico Chileno, Concepción, CD abstracts. Suárez, M.E., Lamilla, J., Marquardt, C., 2004. Peces Chimaeriformes (Chondrichthyes, Holocephali) del Neógeno de la Formación Bahía Inglesa (Región de Atacama, Chile). Revista Geológica de Chile 31 (1), 105e117. Swofford, D.L., 2003. Paup* Phylogenetic Analysis Using Parsimony (*and Other Methods), Version 4.0. Sinauer, Sunderland, Massachusetts. Tambussi, C.P., Acosta-Hospitaleche, C., Reguero, M.A., Marenssi, S.A., 2006. Late Eocene penguins from West Antarctica: systematics and biostratigraphy. In: Francis, J.E., Pirrie, D., Crame, J.A. (Eds.), Cretaceous-tertiary High-latitude Palaeoenvironments, James Ross Bassin, Antarctica. Geological Society, Special Publications, London, pp. 145e161. Tavera, J., 1960. El Plioceno de Bahía Horcón en la Provincia de Valparaíso. Universidad de Chile, Facultad de Ciencias Físicas y Matemáticas. Instituto de Geología, Publicación 18, 319e367. Tavera, J., 1980. Cretáceo y Terciario de la localidad de Algarrobo, Imprentas Gráficas, Santiago, 45 pp. Tavera, l., Veyl, C., 1958. Reconocimiento geológico de la Isla Mocha. Anales de la Facultad de Ciencias Fisicas y Matematicas 14e15, 157e186. Thomas, H., 1958. Geología de la Cordillera de la Costa entre el Valle de La Ligua y la Cuesta Barriga. Boletín No 2. Instituto de Investigaciones Geológicas. Santiago de Chile. Tsuchi, R., Shuto, T., Takayama, T., Fujiyoshi, A., Koizumi, I., Ibaraki, M., Martínez, R.P., 1988. Fundamental data on Cenozoic biostratigraphy of Chile. In: Tsuchi, R. (Ed.) Reports of Andean studies Shizuoka University Trans-Pacific Correlation of Cenozoic Geohistory. Kofune Printing 2, 1–108. Shizuoka. Upchurch, P., Barrett, P.M., Dodson, P., 2004. Sauropoda. In: Weishampel, D.B., Dodson, P. Osmolska, H. (Eds.), The Dinosauria, pp. 259–322. Vargas, A., Suárez, M., Rubilar, D., Moreno, K., 2000. A titanosaurid vertebra from Pichasca, Formación Viñita (Late Cretaceous), IV Región, northern Chile. Ameghiniana, Suplemento 37 (4), 35R. Vicente, J.C., 2006. Dynamic paleogeography of the Jurassic Andean Basin: pattern of regression and general considerations on main features. Revista de la Asociación Geológica Argentina 61 (3), 408e437. Walsh, S.A., Hume, J.P., 2001. A new Neogene marine avian assemblage from northcentral Chile. Journal of Vertebrate Paleontology 21, 484e491. Walsh, S.A., Naish, D., 2002. Fossil seals from late Neogene deposits in South America: a new pinniped (Carnivora, Mammalia) assemblage from Chile. Palaeontology 45 (4), 821e842. Walsh, S., Suárez, M.E., 2006. New penguin remains from the Pliocene of northern Chile. Historical Biology 18, 115e126. Wilson, J.A., 2002. Sauropod dinosaur phylogeny: critique and cladistic analysis. Zoological Journal of the Linnean Society 136, 217e276. Yury-Yáñez, R., Rubilar-Rogers, D., Sallaberry, M., Soto, S., Suárez, M.E., 2008. El cráneo de un Puffinini (aves, Procellariidae) del Mioceno de la Formación Bahía Inglesa, Desierto de Atacama. In: Actas IX Congreso Chileno de Ornitología, Boletín Chileno de Ornitología, El Tabo, vol. 14. Yury-Yáñez, R., Soto-Acuña, S., Gutstein, C., Rubilar-Rogers, D., 2009. A nearly complete skeleton of Spheniscus urbinai Stucchi (Aves, Sphenisciformes) in the Bahía Inglesa Formation (MioceneePliocene) Atacama Desert, Chile. Journal of Vertebrate Paleontology 29 (3), 205A. Yury-Yáñez, R., Gutstein, C.S., Rubilar-Rogers, D., 2010a. . Fossil Procelarids (Aves: Procellariiformes) from the Bahía Inglesa Formation Bonebed (Late Miocene), Atacama Desert, northern Chile. Journal of Vertebrate Paleontology 30, 191A. Yury-Yáñez, R., Soto-Acuña, S., Otero, R.A., Gutstein, C.S., Suárez, M.E., Sallaberry, M., Rubilar-Rogers, D., 2010b. Nuevos registros de aves fósiles en Chile. In: Actas II Simposio de Paleontología en Chile, Concepción, vol. 73. Yury-Yáñez, R., Otero, R.A., Soto-Acuña, S., Suárez, M.E., Rubilar-Rogers, D., Sallaberry, M. First bird remains from the Eocene of Algarrobo, central Chile. Andean Geology, in press.

Get in touch

Social

© Copyright 2013 - 2024 MYDOKUMENT.COM - All rights reserved.