Abstracts

INTRODUCTION

The complex relationships between physical, chemical and biological processes make reef environments especially interesting (Tucker and Wright 1990Tucker ME and Wright VP. 1990. Carbonate Sedimentology. Oxford, Blackwell, 482 p.). Such environments constitute some of the most studied in geobiology, linking biological activity and geological formations via the formation of carbonate, built by a huge diversity of reef organisms, such as corals, coralline algae and foraminifera.

The generation of sediments in reef environment is extremely complex, involving several processes that result from a physical, chemical and biological interaction, interfering directly with the deposition of biogenic and non-biogenic sediments.

The most important reef organisms that contribute to the generation of biogenic particles at shallow tropical reef systems are halimeda, corals, molluscs, foraminifera and coralline algae (Weber and Woodhead 1972Weber JN and Woodhead PMJ. 1972. Carbonate lagoon and beach sediments of Tarawa Atoll, Gilbert Islands. Atoll Research Bulletin n°. 157, National Museum of Natural History, Smithsonian Institute, Washington, D. C., USA.). Sediments deposited in the interior of atoll reefs consist almost entirely of skeletal carbonate, and the development of sedimentary facies inside the atoll is mediated by the interplay between the sediment source supply, its physical properties and several processes that redistribute and settle the sediments (Maxwell et al. 1964Maxwell WGH, Jell JS and McKellar RG. 1964. Differentiation of carbonate sediments in the Heron Island Reef. Tulsa, USA. J Sed Petrol 34: 294-308. Milliman 1974Milliman JD. 1974. Marine carbonates. Recent sedimentary carbonates part 1. Springer-Verlag, New York, Heidelberg & Berlin, 375 p.).

Extensive sedimentological studies have been undertaken in recent deposits aiming to identify particular parameters that come to distinguish different types of sedimentary environment (Folk and Ward 1957Folk RL and Ward WC. 1957. Brazos river bar: a study in the significance of grain size parameters. Tulsa, USA. J Sed Petrol 27(1): 3-26., Mason and Folk 1958Mason CC and Folk RL. 1958. Differentiation of beach, dune and aeolian flat environment by size analysis Mustang Island, Texas. Tulsa, USA. J Sed Petrol 28(2): 211 -226., Friedman 1961Friedman G. 1961. Distinction between dune, beach and river sands from their textural characteristics. Journal of Sedimentary Petrology 31(2): 514-529. Tulsa. USA.). Mean size, sorting, skewness and kurtosis are all common parameters in these studies. Thus, the present research aims to identify patterns in the distribution of the detrital carbonate sediments using these proxies as tools for specific assessing the generation and deposition at this very particular carbonate sedimentary environment.

STUDY AREA

The Rocas Atoll is located in the western part of the South Atlantic (3°51′S, 33°49′W), 266 km from the coastal city of Natal, Northeast Brazil (Fig. 01).

The climate is equatorial with direction and velocity of trade winds varying seasonally. During the summer 50% are from the southeasterly and 35% easterly. During winter the frequency of SE winds increases to 70%, whereas E winds decrease to 25%. The maximum wind speed is 11 m.s⁻¹ (Hoflich 1984Hoflich O. 1984. Climate of the South Atlantic Ocean. In: Van Loon H (Ed), Climates of the oceans. Elsevier, Amsterdam, p. 1-192.).

Rocas is located within the South Equatorial Current (SEC), which has a consistent westerly direction (JOP'S II 1996JOP'S II - Joint Oceanographic Projects II (Cruise report and first results). 1996. Sedimentation processes and productivity in the continental shelf waters off East and Northeast Brazil, 151 p. Werner Ekau e Bastiaan Knoppers (Eds), Bremen: Center for Tropical Marine Ecology., Goes 2005Goes CA. 2005. Correntes superficiais no Atlântico Tropical, obtidas por dados orbitais, e sua influência na dispersão de larvas de lagosta. Dissertação (Mestrado) Sensoriamento Remoto. São José dos Campos: INPE, 35 p. - (INPE-1111-TDI/111).). The mean speed in the 4° parallel (which cross the Rocas Atoll) is 30 cm.s⁻¹ (Richardson and Walsh 1986Richardson PL and Walsh D. 1986. Mapping climatological seasonal variations of surface currents in the tropical Atlantic using ship drifts, J Geophys Res 91: 10537-10550. (doi:10.1029/JC091iC09p10537)
https://doi.org/10.1029/JC091iC09p10537... ).

The mean temperature of the sea water varies from 26°C in September to 28.3°C in April (Hoflich 1984Hoflich O. 1984. Climate of the South Atlantic Ocean. In: Van Loon H (Ed), Climates of the oceans. Elsevier, Amsterdam, p. 1-192., Servain at al. 1987), increasing to 42°C in the atoll's inner rock-pools (Soares et al. 2009Soares MO, Lemos VB and Kikuchi RKP. 2009. Atol das Rocas, Atlântico Sul Equatorial: considerações sobre a classificação do recife biogênico. Rev Bras Geociênc 39(2): 238-243.). The sea surface salinity varies from 36 to 37‰ (Gherardi and Bosence 1999Gherardi DFM and Bosence DWJ. 1999. Modeling of the ecological succession of encrusting organisms in recent coralline-algal frameworks from Atol das Rocas, Brazil. Palaios 14(2): 145-158.).

The tidal regime in Rocas is a semi-diurnal and mesotidal, with a maximum height of 3.8 m (Gherardi and Bosence 2001Gherardi DFM and Bosence DWJ. 2001. Composition and community structure the coralline alga reefs from Atol das Rocas, South Atlantic, Brazil. Coral Reefs 19: 205-219. (DOI: 10.1007/s003380000100).
https://doi.org/10.1007/s003380000100... ). Wave action is concentrated in the SE portion of the atoll although the refraction of waves caused by the sea mountain that supports Rocas produce braking waves that also act in the W and SW portions (Gherardi and Bosence 2001Gherardi DFM and Bosence DWJ. 2001. Composition and community structure the coralline alga reefs from Atol das Rocas, South Atlantic, Brazil. Coral Reefs 19: 205-219. (DOI: 10.1007/s003380000100).
https://doi.org/10.1007/s003380000100... ). The mean waves heights measured in Fernando de Noronha, the closest island from the Rocas Atoll vary from 1.1 m in February and 1.6 m in June (Hoflich 1984Hoflich O. 1984. Climate of the South Atlantic Ocean. In: Van Loon H (Ed), Climates of the oceans. Elsevier, Amsterdam, p. 1-192.).

Geology of the Area

The reef grows in the W portion of a submarine volcanic mountain with a flattened top (Fig. 02), (a Guyot) rising up from depths of 4,000 m (Ottman 1963Ottman F. 1963. “L'atol das Rocas” dans l'Atlantique sud tropical. Revue de Géographie Physique et de Géologie Dynamique 2: 101-107., Kikuchi and Leão 1997Kikuchi RKP and Leão ZMAN. 1997. Rocas (Southwestern Equatorial Atlantic, Brazil): an atoll built primarily by coralline algae. in: INT. CORAL REEF SYM, 8th, Panama 1: 731-736.). This Guyot constitutes part of the submarine mountain chain located on the Fernando de Noronha Fracture Zone.

Samples from this Guyot have never been obtained and its composition is still unknown. However, it is possible to correlate the volcanic basement of Rocas to other sea mountains, such as samples obtained from Fernando de Noronha, which belongs to the same fracture zone.

The archipelago of Fernando de Noronha is the only part of the chain where the mineralogical composition is known. Almeida (1955)Almeida FFM. 1955. Geologia e Petrologia do Arquipélago de Fernando de Noronha. Rio de Janeiro, NPM/DGM, 181 p. carried out a thorough geological study in Fernando de Noronha and reported three formations on the island: Remédios Formation (pyroclastic rocks, crossed by several dykes and other types of intrusive bodies); Quixaba Formation (eroded rocks from Remédios Formation, which were posteriorly buried by ankaratritc lava flow); and São José Formation (nepheline basanite spills).

Radiometric ages from the volcanic rocks in Fernando de Noronha vary from 1.7 to 12.3 Myr (Almeida 1955Almeida FFM. 1955. Geologia e Petrologia do Arquipélago de Fernando de Noronha. Rio de Janeiro, NPM/DGM, 181 p.). It is expected that the volcanic basement upon which Rocas is located is similar in nature to those at Fernando de Noronha. That said, they would probably be older, due to the larger distance from the Atlantic's mid-oceanic ridge.

Evolution of the Atoll

Over time coralline algae, coral reefs, molluscs, and crustaceans colonized the guyot. The accretion of carbonate to form skeletal material provided the basis for the ring ellipsoid reef (Soares-Gomes et al. 2001Soares-Gomes A, Villaça RC, and Pezzella CAC. 2001. Atol das Rocas ecossistema único no Atlântico Sul. Ciência Hoje 29(172): 32-39., Gherardi and Bosence 2001Gherardi DFM and Bosence DWJ. 2001. Composition and community structure the coralline alga reefs from Atol das Rocas, South Atlantic, Brazil. Coral Reefs 19: 205-219. (DOI: 10.1007/s003380000100).
https://doi.org/10.1007/s003380000100... ). The reef almost attained sea-level, forming an atoll with a shallow lagoon and two islands; Farol Island and Cemitério Island (Gherardi and Bosence 2005Gherardi DFM and Bosence DWJ. 2005. Late Holocene reef growth and relative sea level changes in Atol das Rocas, equatorial South Atlantic. Coral Reefs 24: 264-272. (DOI: 10.1007/s00338-005-0475-5)
https://doi.org/10.1007/s00338-005-0475-... ).

Using a seismic survey and core drilling Kikuchi and Leão (1997)Kikuchi RKP and Leão ZMAN. 1997. Rocas (Southwestern Equatorial Atlantic, Brazil): an atoll built primarily by coralline algae. in: INT. CORAL REEF SYM, 8th, Panama 1: 731-736. identified three strata at the Rocas site. The first was 12 m thick Holocene layer with seismic velocity of 0.33 m x m.s⁻¹. The composition of this layer is mainly composed of by encrusting coralline algae, vermetid gastropods, encrusting foraminifera (Homotrema rubrum), and corals. The second and third beds had seismic wave velocities of 2.50 m x m.s⁻¹, 4.70 m x m.s⁻¹ respectively, the latter corresponding to velocities typical of basaltic rocks.

The oldest radiometric ages derived from coral skeletons was 4.86 Kyr. Nevertheless, this age may not correspond to the beginning of the reef development. Thus, it is assumed that the initiation of reef growth began before 4.86 Ka, with an accretion ratio ranging from 1.5 to 3.2 m/Kyr (Kikuchi 1999Kikuchi RKP. 1999. Atol das Rocas, Atlântico sul equatorial ocidental, Brasil. In: Schobbenhaus C, Campos DA, Queiroz ET, Winge M and Berbert-Born M (Eds), Sítios Geológicos e Paleontológicos do Brasil. (Disponível em: http://www.unb.br/ig/sigep/sitio033/sitio033.htm).
http://www.unb.br/ig/sigep/sitio033/siti... ).

Structure of the Reef

Gherardi and Bosence (2001)Gherardi DFM and Bosence DWJ. 2001. Composition and community structure the coralline alga reefs from Atol das Rocas, South Atlantic, Brazil. Coral Reefs 19: 205-219. (DOI: 10.1007/s003380000100).
https://doi.org/10.1007/s003380000100... described the reef structure of Rocas. According to the authors, the atoll is composed by the following groups of encrusting organisms: Coralline algae, vermetid gastropods, Homotrema rubrum (encrusting foraminifera), acervulinids (encrusting foraminifera), polychaetes worm tubes, corals, molluscs, sponges, cemented sediments and growth cavities.

The coralline algae constitute the primary framework builders with Porolithon cf. pachydermum being the most significant coralline algae genus. Secondary framework builders consisted of the following five classes: vermetid gastropods, H. Rubrum, Acervulinids, Polychaete worm tubes and unidentified corals (Gherardi and Bosence 2001Gherardi DFM and Bosence DWJ. 2001. Composition and community structure the coralline alga reefs from Atol das Rocas, South Atlantic, Brazil. Coral Reefs 19: 205-219. (DOI: 10.1007/s003380000100).
https://doi.org/10.1007/s003380000100... ).

Reef Geomorphology

Geomorphological features of Rocas Atoll were previously studied by Andrade (1959)Andrade GO. 1959. O recife anular das Rocas (Um registro das recentes variações eustáticas no Atlântico equatorial). An Assoc Geógr Bras 12: 29-61., Ottman (1963)Ottman F. 1963. “L'atol das Rocas” dans l'Atlantique sud tropical. Revue de Géographie Physique et de Géologie Dynamique 2: 101-107. and Kikuchi and Leão (1997)Kikuchi RKP and Leão ZMAN. 1997. Rocas (Southwestern Equatorial Atlantic, Brazil): an atoll built primarily by coralline algae. in: INT. CORAL REEF SYM, 8th, Panama 1: 731-736.. The classification of the reef as an atoll has been widely debated (Vallaux 1940Vallaux C. 1940. La formation atollienne de Rocas (Brésil). Bull Inst Oceanograph 37:1-8., Andrade 1959Andrade GO. 1959. O recife anular das Rocas (Um registro das recentes variações eustáticas no Atlântico equatorial). An Assoc Geógr Bras 12: 29-61., Ottman 1963Ottman F. 1963. “L'atol das Rocas” dans l'Atlantique sud tropical. Revue de Géographie Physique et de Géologie Dynamique 2: 101-107., Kikuchi 1994Kikuchi RKP. 1994. Geomorfologia, Estratigrafia e Sedimentologia do Atol das Rocas (Rebio-IBAMA/RN), 144 p. Dissertação (Mestrado) Pós-Graduação em Geologia, Universidade Federal da Bahia. Salvador, Bahia, Brasil. (não publicado)., Kikuchi and Leão 1997Kikuchi RKP and Leão ZMAN. 1997. Rocas (Southwestern Equatorial Atlantic, Brazil): an atoll built primarily by coralline algae. in: INT. CORAL REEF SYM, 8th, Panama 1: 731-736., Gherardi and Bosence 1999Gherardi DFM and Bosence DWJ. 1999. Modeling of the ecological succession of encrusting organisms in recent coralline-algal frameworks from Atol das Rocas, Brazil. Palaios 14(2): 145-158., Soares et al. 2009Soares MO, Lemos VB and Kikuchi RKP. 2009. Atol das Rocas, Atlântico Sul Equatorial: considerações sobre a classificação do recife biogênico. Rev Bras Geociênc 39(2): 238-243.). Several disagreements arose from this debate. For example, Davis (1928)Davis WM. 1928. The coral reef problem. American Geographical Society, Special Paper 9:1-596. described Rocas as an emerged bank atoll, whereas Vallaux (1940)Vallaux C. 1940. La formation atollienne de Rocas (Brésil). Bull Inst Oceanograph 37:1-8. depicted the reef as an almost-atoll. Nevertheless, others (Kikuchi and Leão 1997Kikuchi RKP and Leão ZMAN. 1997. Rocas (Southwestern Equatorial Atlantic, Brazil): an atoll built primarily by coralline algae. in: INT. CORAL REEF SYM, 8th, Panama 1: 731-736., Gherardi and Bosence 2005Gherardi DFM and Bosence DWJ. 2005. Late Holocene reef growth and relative sea level changes in Atol das Rocas, equatorial South Atlantic. Coral Reefs 24: 264-272. (DOI: 10.1007/s00338-005-0475-5)
https://doi.org/10.1007/s00338-005-0475-... ) have reported Rocas as the only atoll in the southwestern Atlantic.

Soares et al. (2009)Soares MO, Lemos VB and Kikuchi RKP. 2009. Atol das Rocas, Atlântico Sul Equatorial: considerações sobre a classificação do recife biogênico. Rev Bras Geociênc 39(2): 238-243. discussed several issues that complicate the classification of Rocas, the main issue being a dispute between genesis and morphological criteria. However, the authors argue that morphological features are sufficient to assure Rocas is a truly atoll.

Pereira et al. (2010)Pereira NS, Manso VAV, Silva AMC, Silva MB. 2010. Mapeamento Geomorfológico e Morfodinâmica do Atol das Rocas, Atlântico Sul. Revista de Gestão Costeira Integrada 10(3): 331-345. presented a geomorphological map of Rocas (Fig. 04) and described the atoll as one of the smallest of the world, with an axis of 3.35 km by 2.49 km, a reef area of 6.56 km², and a perimeter of 11 km. Compared to other atolls such as the Kwajalein Atoll (120 x 32 km), Marshall Islands, and Rangiroa Atoll (72 x 36 km), French Polynesia (Guilcher, 1988Guilcher A. 1988. Coral reef geomorphology. J Wiley & Sons Ltd. 228 p.), Rocas has the smallest dimensions (Fig. 03)

In their work, Pereira et al. (2010)Pereira NS, Manso VAV, Silva AMC, Silva MB. 2010. Mapeamento Geomorfológico e Morfodinâmica do Atol das Rocas, Atlântico Sul. Revista de Gestão Costeira Integrada 10(3): 331-345. described the following features: reef front, algal ridge, reef proper, sedimentary deposit, tidepools, lagoon, and sedimentary cays. The presence of beachrocks in the Cemitério Island were also reported (Fig. 05).

Methodology

41 sediment samples (Fig. 05) were obtained during reef top exposure at low tide. Samples came from the features including sedimentary deposits, sedimentary cays and tidepools at the reef complex in January and July of 2009. Cumulative frequency curves were constructed from the sieving data, and mean size, sorting, skewness and kurtosis values computed. The values of the sedimentological parameters were calculated by the software Sysgran 3.0 (Camargo 2006Camargo MG. 2006. SYSGRAN: um sistema de código aberto para análises granulométricas do sedimento. Rev Bras Geociênc 36(2): 371-378.), and plotted on facies maps.

In order to deduce organism biodiversity, analysis of the biogenic components was undertaken in each sedimentary environment. Organisms were observed using a binocular microscope.

RESULTS AND DISCUSSION

The sedimentary environmental of the Rocas Atoll is composed entirely of carbonate skeleton derived from the reef structure, which goes through continuous degradation by physical process, such as wave action, and by the production from living carbonate secreting organisms.

Carbonate sedimentary environment composed exclusively by skeleton are greatly influenced by the local biodiversity. Differences on the biota are reflected directly on the sedimentary textures and parameters.

Textural Classes

Using the Shepard diagram (1954) four textural classes (Fig. 06) were identified in Rocas' carbonate sediments: Sand (78%), Gravelly sand (15%), Sandy gravel (2%), and Gravel (5%).

Although the classification of Shepard is merely descriptive, it is be possible to deduce, using textural maps, information on the local hydrodynamics, mirroring the energetic level according to the distribution of fine and coarse particles (Dias 2004Dias JA. 2004. A análise sedimentar e o conhecimento dos sistemas marinhos: Uma Introdução à Oceanografia Geológica II – Análise Textural. Disponível em http://w3.ualg.pt/jdias/JAD/ebooks/Sedim/SedimA_AT.pdf
http://w3.ualg.pt/jdias/JAD/ebooks/Sedim... ). In this way the environmental energy level reflects the sediment mobilization capability of the environment. Coarse particles are thereby associated to highenergy environments, that decrease proportionally with decreasing mean size (Folk and Ward 1957Folk RL and Ward WC. 1957. Brazos river bar: a study in the significance of grain size parameters. Tulsa, USA. J Sed Petrol 27(1): 3-26.).

Sandy deposits dominate the Rocas textural map. Others textures were distributed on the areas surrounding cays (Fig. 07).

The lack of fine particles is probably related to low production of fine fraction and/or hydrodynamics process. The latter may be depositing the fine sediment on the outer atoll, which could be investigated by direct sampling in this area. Weber and Woodhead (1972)Weber JN and Woodhead PMJ. 1972. Carbonate lagoon and beach sediments of Tarawa Atoll, Gilbert Islands. Atoll Research Bulletin n°. 157, National Museum of Natural History, Smithsonian Institute, Washington, D. C., USA. pointed out that inner reef environments are much richer in carbonate sands than carbonate muds. Mud rarely yielded percentage above 2% at Capricorn reef complex, Australia (Maiklem 1970Maiklem WR. 1970. Carbonate sediments in the Capricorn Reef complex, Great Barrier Reef, Australia. Tulsa, USA. J Sed Petrol 40(1): 55-80.), which correspond to the results published by Maxwell et al. (1961)Maxwell WGH, Day RW and Fleming PJG. 1961. Carbonate sedimentation on the Heron Island Reef, Great Barrier Reef. Tulsa, USA. J Sed Petrol 31: 215-230. in the Great Barrier of Australia. The mud present in that system had a terrigenous origin. The explanation frequently pointed out by researchers to explain the lack of fine inner-reef material is its hydrodynamic removal through suspension (Thorp 1936Thorp EM. 1936. The sediments of the Pearl and Hermes Reef. Tulsa, USA. J Sed Petrol 6: 109-118.), or its deposition in a deeper area of the reef, like a lagoon, as was found at Kure and Midway Atoll (Gross et al. 1969Gross MG, Millman JD, Tracey JI and Ladd HS. 1969. Marine geology of Kure and Midway Atolls, Hawaii: a preliminary report. Pac Sci 23: 17-25.).

In Rocas, the sedimentary deposits are constantly influence by the tide, and this seems to be the most determinant factor on the distribution of the textural classes of this feature, where the hydrodynamism of the tidal currents shifted sediments during high tide, removing finer sediment from the inner part of the atoll.

Mean Size

The mean size reflects one of the most important parameters in sedimentological studies. In a geological view, the mean size represents the mean kinetic energy of the transport agent, although it is also dependent on the size distribution of the available source (Sahu 1964Sahu BK. 1964. Depositional mechanism from size analysis of clastic sediments. Tulsa, USA. J Sed Petrol 34: 73-83.).

Mean size phi values ranged from -1.23 to 2.34ø, straddling five classifications: fine sand, medium sand, coarse sand, very coarse sand and granule. Constituting 37% of samples, coarse sand was the most dominant, followed by medium sand and very coarse sand, yielding 32% and 22%, respectively. Fine sand and granule represented only 7% and 2%, respectively.

It is possible to analyse the sedimentary environment of Rocas in two ways. As a whole, including samples from sedimentary deposits, sedimentary cays and tidepools. Alternatively, each of these features can be assessed separately. Verifying all samples together, the mean grain size value is 0.69ø (coarse sand), suggesting that geological agents are acting favourably to deposit coarser particles. In other words, the local hydrodynamic situation can be considered high. The few samples that presented finer particles are associated with specific features of the reef that might diminish the hydrodynamic action, such as the fine sand next to the algal ridge and in the Eastern part of the sedimentary deposit, which seems to be protected by the reef proper (Fig. 08).

Analyzed separately, the sedimentary cays showed a predominance of coarse sand. The Farol Island samples ranged from -0.96 to 1.37ø, with an average of 0.44ø (coarse sand), as did the Cemitério Island (average, 0.70ø). The Zulú Island exhibited a diameter size varying from coarse sand to gravel (average, 0.31ø).

The sedimentary deposit presented extreme values ranging from 2.34 and -0.29ø (average 1.16ø, medium sand). The tidepools ranged from coarse sand to very coarse sand with a mean value of 0.008ø (coarse sand).

The wide range of the phi values in the Rocas sediments may be explained by the influence of the different geomorphological features on the distribution of the particles size. This can be observed on the beach face of the cays, where combined wave action and tidal currents remove fine sediments and the deposition of finer particles are found next to the algal rigde, caused by the low hydrodynamics in this area. Even so, coarse sand samples in the middle part of the sedimentary deposit might reflect the tidal current during high tide.

Sorting

Sedimentological parameters such as mean size and sorting are not normally used in carbonate sediments. However, Gerhard and Cross (2005)Gerhard LC and Cross TA. 2005. Measurements of the generation and distribution of carbonate sediments of buck island channel, St. Croix, U. S. Virgin Islands, with observations about sediments in fringing lagoons. Atoll Research Bulletin n°. 536, National Museum of Natural History, Smithsonian Institute, Washington, D. C., USA. assert that these statistical measurements have shown reliability in describing carbonate sedimentary environments, which are subject to mechanical transportation through extensive bioturbation, waves, and currents.

At Rocas, sorting (σI) ranged from 0.23 to 1.72ø; 48% of samples were clustered in the interval of 1.0 - 2.0ø, classifying them as poorly sorted; 41% were grouped fairly tightly between 0.5 - 1.0ø, equivalent to being moderately sorted. The average sorting was 0.97ø (moderately sorted).

The sorting map (Fig. 09) shows clearly the predominance of poorly sorted sediments. Sorting increases on the central and eastern part of the sedimentary deposit, on Farol and Cemitério islands, and on the leeward tidepool.

Two conditions might be influencing sorting values: first, wave and tidal current action, working mainly on the beach face and areas subject to these processes (for example the central part of Rocas, which may be providing a better sorting); second, the effect of the biogenic source has a direct influence on the sedimentological measurements, where dominance of a single source can lead to improved sorting and thus, a noticeable enrichment biogenic carbonate sediments (Folk et al. 1962Folk RL, Haynes MO and Shoji R. 1962. Carbonate sediments of Isla Mujeres, Quintana Roo, Mexico, and Vicinity. New Orleans Geological Society, Yucatan Peninsula Field Trip Guidebook, p. 85-100., Folk and Robles 1964Folk RL and Robles R. 1964. Carbonate sands of Isla Perez, Alacran Reef, Yucatan. J Geol 72(3): 255-292., Stoddart 1964Stoddart DR. 1964. Carbonate sediments of Half Moon Cay, British Honduras. Atoll Research Bulletin n°. 104, National Museum of Natural History, Smithsonian Institute, Washington, D. C., USA., Gerhard and Cross 2005Gerhard LC and Cross TA. 2005. Measurements of the generation and distribution of carbonate sediments of buck island channel, St. Croix, U. S. Virgin Islands, with observations about sediments in fringing lagoons. Atoll Research Bulletin n°. 536, National Museum of Natural History, Smithsonian Institute, Washington, D. C., USA.).

Pereira et al. (2008)Pereira NS, Marins YO, Silva AMC, Oliveira PGV. Silva MB. 2008. Influência Do Ambiente Sedimentar Na Distribuição Dos Organismos Meiobentônicos do Atol Das Rocas. Estudos Geológicos (UFPE) 18(2): 67-80. (Disponível em http://www.ufpe.br/estudosgeologicos/).
http://www.ufpe.br/estudosgeologicos/... described ten major groups of organisms that contribute to the sedimentation of the reef complex. Although coralline red algae dominates the reef structure (Gherard and Bosence 2001, Kikuchi and Leão 1997Kikuchi RKP and Leão ZMAN. 1997. Rocas (Southwestern Equatorial Atlantic, Brazil): an atoll built primarily by coralline algae. in: INT. CORAL REEF SYM, 8th, Panama 1: 731-736.), this fact is clearly insufficient to create sediment homogenity given that most sediments are poorly sorted, and better sorting samples seems to occur due to wave and current action. Poorly sorted carbonate sediments are frequently reported and their cause is usually attributed to the high biodiversity of organisms that release their carbonate skeletons into the system (Folk et al. 1962Folk RL, Haynes MO and Shoji R. 1962. Carbonate sediments of Isla Mujeres, Quintana Roo, Mexico, and Vicinity. New Orleans Geological Society, Yucatan Peninsula Field Trip Guidebook, p. 85-100., Folk and Robles 1964Folk RL and Robles R. 1964. Carbonate sands of Isla Perez, Alacran Reef, Yucatan. J Geol 72(3): 255-292., Stoddart 1964Stoddart DR. 1964. Carbonate sediments of Half Moon Cay, British Honduras. Atoll Research Bulletin n°. 104, National Museum of Natural History, Smithsonian Institute, Washington, D. C., USA.).

Mean Size x Sorting

The geological significance of sedimentological measurements can be easily perceived by plotting mean size versus sorting (Folk and Cotera 1971Folk RL and Cotera AS. 1971. Carbonate sand cays of Alacran reef, Yucatan, Mexico: sediments. Atoll Research Bulletin n°. 137. National Museum of Natural History, Smithsonian Institute, Washington, D. C., USA.). In Rocas, we noted that coarse sand tends to be better sorted (mean size = -1.2ø, sorting σ_I = 0.2). Stoddart (1964)Stoddart DR. 1964. Carbonate sediments of Half Moon Cay, British Honduras. Atoll Research Bulletin n°. 104, National Museum of Natural History, Smithsonian Institute, Washington, D. C., USA. at Half Moon Cay, Belize, described the same correlation. However, Folk and Cotera (1971)Folk RL and Cotera AS. 1971. Carbonate sand cays of Alacran reef, Yucatan, Mexico: sediments. Atoll Research Bulletin n°. 137. National Museum of Natural History, Smithsonian Institute, Washington, D. C., USA., studying carbonate sediments in Alacran Reef at Yucatán, Mexico, showed the opposite trend, with better sorting attributed to finer sediment.

In Rocas, there is a slightly tendency for better sorting with increasing grain size (Fig. 10). Stoddart (1964)Stoddart DR. 1964. Carbonate sediments of Half Moon Cay, British Honduras. Atoll Research Bulletin n°. 104, National Museum of Natural History, Smithsonian Institute, Washington, D. C., USA. explain that this trend is partly due to the narrowing in range of organisms that contribute to the sedimentary environment as size increases.

Sedimentary deposit can easily be distinguished from the other facies types in figure 10. The former is characterized by smaller diameters and poorer sorting. This may be explained by the major influence of organism source on the deposit, whereas, the others present coarser sediments and better sorting, which could be ascribed to wave and tidal action, during high tide.

Studies on carbonate sediments in the Caribbean (Folk and Robles 1964Folk RL and Robles R. 1964. Carbonate sands of Isla Perez, Alacran Reef, Yucatan. J Geol 72(3): 255-292. in Alacran and Isla Mujeres; Stoddart 1964Stoddart DR. 1964. Carbonate sediments of Half Moon Cay, British Honduras. Atoll Research Bulletin n°. 104, National Museum of Natural History, Smithsonian Institute, Washington, D. C., USA. at Half Moon Cay, Belize) concluded that mean size and sorting are more dependent on the type of biogenic source than the wave energy. The latter effectively controls the mean size and the former has major influence on the sorting.

Skewness

Several investigations have applied skewness sedimentological measurements, although the geological meaning of this parameter is almost never mentioned (Martins 1965Martins LR. 1965. Significance of skewness and kurtosis in environmental interpretation. Tulsa, USA. J Sed Petrol 35(3): 768-770.). This parameter is controlled more by depositional processes than transport pattern (Suguio 1973Suguio K. 1973. Introdução à sedimentologia. Edgar Blucher, São Paulo, 317 p.).

In Rocas, the samples yielded skewness values ranging from -0.581 to 0.764, (strongly negatively to strongly positively skewed) in the atoll; 46% of samples fell into the range of negative skewness, whereas, positive skewness was represented by 34% of the samples. Symmetrically skewed samples made up 20% of the whole.

Negative values of skewness dominate the sedimentary deposit, with some restricted samples of positive and nearly symmetrical skewness (Fig. 11). Folk and Robles (1964)Folk RL and Robles R. 1964. Carbonate sands of Isla Perez, Alacran Reef, Yucatan. J Geol 72(3): 255-292. showed that carbonate sediments of the Isla Perez in Alacran Reef Complex are predominantly negatively skewed, hinting that this was probably caused by the addition of coarse sand, provided by corals and coralline algae.

Positive skewness prevail on the cays (Farol and Zulú Islands). Duane (1964)Duane D. 1964. Significance of skewness in recent sediments, Western Pamlico sound, North Carolina. Tulsa, USA. J Sed Petrol 34(4): 864-874. explained that positively skewed signatures could be related to the influx of particles. Pereira et al. (2010)Pereira NS, Manso VAV, Silva AMC, Silva MB. 2010. Mapeamento Geomorfológico e Morfodinâmica do Atol das Rocas, Atlântico Sul. Revista de Gestão Costeira Integrada 10(3): 331-345. noticed an increase in the volume of sediments on the Farol and Zulú Islands. Thus, we conclude that the positively skewed signature probably indicates a tendency towards the deposition of biogenic carbonate in the reef system.

The dominance of negatively skewed values on the sedimentary deposit can be explained in two ways: one, intense action of depositional agents, sparked by the tidal regime, could be removing finer particles; or two, by the addition of coarse sand, mainly by the fragmentation of coralline algae, corals and molluscs created in the reef complex.

In Rocas, medium and finer sand show tendency to be negatively skewed and vice versa (Fig. 12). Folk and Ward (1957)Folk RL and Ward WC. 1957. Brazos river bar: a study in the significance of grain size parameters. Tulsa, USA. J Sed Petrol 27(1): 3-26. found a similar pattern in Brazos River, Texas.

This observation leads to another correlation; the comparison between the texture of the sediments of some areas of the atoll to the skewness. Areas with gravel, sandy gravel and gravelly sand textures are overwhelmingly positively skewed. Cronan (1972)Cronan DS. 1972. Skewness and kurtosis in polymodal sediments from the Irish Sea. Tulsa, USA. J Sed Petrol 42(1): 102-106. found similar trends in Irish Sea sediments, where gravelly sand texture was strongly linked to positive values of skewness due to depositional process.

Skewness signatures are sensitive to environmental parameters crucial in distinguishing sedimentary environments such as beaches, dunes, estuaries and tidal deltas (Mason and Folk 1958Mason CC and Folk RL. 1958. Differentiation of beach, dune and aeolian flat environment by size analysis Mustang Island, Texas. Tulsa, USA. J Sed Petrol 28(2): 211 -226., Friedman 1961Friedman G. 1961. Distinction between dune, beach and river sands from their textural characteristics. Journal of Sedimentary Petrology 31(2): 514-529. Tulsa. USA., Duane 1964Duane D. 1964. Significance of skewness in recent sediments, Western Pamlico sound, North Carolina. Tulsa, USA. J Sed Petrol 34(4): 864-874.). At Rocas Atoll, skewness values effectively separated out depositional environments, as was seen in the case of the cays (Farol and Zulú Islands), which exhibited positively skewed values relative to the sedimentary deposit, that presented negatively skewed values.

Kurtosis

Kurtosis parameters show values consistent with leptokurtic and extremely leptokurtic (43.89%), platykurtic and extremely platykurtic (41.45%) and mesokurtic (14.63%). Indeed, kurtosis signatures are complex showing only ambiguous patterns on the sedimentary body of Rocas (Fig. 13). This is with the exception of the dominance of leptokurtic sediments on the Farol and Cemitério islands, which signifies the dominance of one population in determining the total fraction, leading to better sorting, which can be seen on the islands.

Sediments from the beach face of these islands are under breaking wave action during high tide. This phenomenon will likely select a certain type of particle size, leading to predominance of one size population. For reasons not immediately obvious this process favours the prevalence of leptokurtic curves.

Folk and Robles (1964)Folk RL and Robles R. 1964. Carbonate sands of Isla Perez, Alacran Reef, Yucatan. J Geol 72(3): 255-292. pointed out a dominance of leptokurtic values in the carbonate sediments of Isla Perez, Alacran Reef complex, ascribing the main cause as the prevalence of coarse sand. With the exception of Farol and Cemitério islands, the kurtosis signature seems not to carry any significant implications on the carbonate sediments at Rocas.

Biogenic Particles

Biogenic particles of Rocas were previously studied by Soares et al. (2009)Soares MO, Lemos VB and Kikuchi RKP. 2009. Atol das Rocas, Atlântico Sul Equatorial: considerações sobre a classificação do recife biogênico. Rev Bras Geociênc 39(2): 238-243. who shed light on the origin and distribution of the carbonate particles in the atoll's reef complex. Thus, although biogenic composition is of great importance, it is treated briefly here.

A total of 11 major groups are described: coralline algae, foraminifera, bryozoans, sponges, corals, bivalve, gastropod, ostracodes, crustaceans, echinoderms and vertebrates (Fig. 14 and 15).

Coralline algae are a major contributor to the sedimentary body. This was expected due to the reef structure of Rocas, which is primarily composed by these organisms (Kikuchi and Leão 1997Kikuchi RKP and Leão ZMAN. 1997. Rocas (Southwestern Equatorial Atlantic, Brazil): an atoll built primarily by coralline algae. in: INT. CORAL REEF SYM, 8th, Panama 1: 731-736., Gherardi and Bosence 2001Gherardi DFM and Bosence DWJ. 2001. Composition and community structure the coralline alga reefs from Atol das Rocas, South Atlantic, Brazil. Coral Reefs 19: 205-219. (DOI: 10.1007/s003380000100).
https://doi.org/10.1007/s003380000100... ). Foraminifera (Fig. 15), bivalve and gastropods, which comprise the secondary framework builders (Gherardi and Bosence 2001Gherardi DFM and Bosence DWJ. 2001. Composition and community structure the coralline alga reefs from Atol das Rocas, South Atlantic, Brazil. Coral Reefs 19: 205-219. (DOI: 10.1007/s003380000100).
https://doi.org/10.1007/s003380000100... ), were also noteworthy components in the sediments samples.

CONCLUSIONS

Sedimentological signatures have long been applied to diagnose particular environmental conditions in a variety of environments. Such parameters have shown specific values inherent to the sedimentary setting, distinguishing, for example, dune, beach and river systems. The sedimentary body of the Rocas Atoll is characterized by a low percentage of fine particles, which we conclude is due to the high local hydrodynamism and/or the insufficient production of mud (finer material). Mean size varies according to the different geomorphological features of the reef environment, where distributions of coarser sand are primarily located on cays and tidepools, and medium sand on the sedimentary deposit, clearly showing differential hydrodynamic action on the geological agents at Rocas. The environment is characterized by poorly sorted sediments, probably due to the wide variety of biogenic sediment components, typical of a reef system. The few cases where sediment is wellsorted (Farol and Cemitério islands) can be attributed to breaking wave and tidal action. Regarding plotting mean size and sorting values, we notice that sorting is positively correlated with mean grain size. This seems to occur due to decreasing organism diversity as size increases. Positive skewness signatures on the Farol and Zulú islands were strongly associated with the deposition of material, a conclusion corroborated by the growth of these two cays over the past few years. The kurtosis parameter did not yield any significant pattern on Rocas, except for leptokurtic particles on Farol and Cemitério islands, assumed to correspond with breaking wave action on the beach face of these islands. The biogenic composition of the carbonate sediments comprises eleven major groups, coralline algae being the most important. In conclusion, sedimentological signatures (mean size, sorting, skewness and kurtosis) were, to differing degrees, useful in diagnosing the sedimentological features of this biogenic carbonate sedimentary environment. The research presented in this article extends beyond the Rocas Atoll, contributing to a wider understanding of the sedimentary processes and characterizations of reef systems.

ACKNOWLEDGMENTS

We thank the staff from the Instituto Chico Mendes de Conservação e Biodiversidade for the logistical support provided in the scientific expeditions, specially to Maurizélia de Brito Silva, for helping in the fieldwork.

REFERENCES

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