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Links between surface sediment composition, morphometry and hydrodynamics in a large shallow coastal lagoon
Journal Pre-proof Links between surface sediment composition, morphometry and hydrodynamics in a large shallow coastal lagoon
H.M. Vieira, Jair Weschenfelder, Elisa Helena Fernandes, Heline Alves Oliveira, Osmar Olinto Möller, Felipe García-Rodríguez PII:
S0037-0738(20)30003-8
DOI:
https://doi.org/10.1016/j.sedgeo.2020.105591
Reference:
SEDGEO 105591
To appear in:
Sedimentary Geology
Received date:
19 October 2019
Revised date:
6 January 2020
Accepted date:
7 January 2020
Please cite this article as: H.M. Vieira, J. Weschenfelder, E.H. Fernandes, et al., Links between surface sediment composition, morphometry and hydrodynamics in a large shallow coastal lagoon, Sedimentary Geology(2020), https://doi.org/10.1016/ j.sedgeo.2020.105591
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© 2020 Published by Elsevier.
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Links between surface sediment composition, morphometry and
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hydrodynamics in a large shallow coastal lagoon
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H.M. Vieira1†, Jair Weschenfelder2, Elisa Helena Fernandes1, Heline Alves Oliveira1
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Osmar Olinto Möller1, Felipe García-Rodríguez1,3
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† Deceased on September 2nd 1997
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1 Laboratório de Oceanografia Costeira e Estuarina (LOCOSTE), Instituto de
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Oceanografia – Universidade Federal do Rio Grande (FURG), Rio Grande, Brazil
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2 Centro de Estudos de Geologia Costeira e Oceânica (CECO), Instituto de Geociências,
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Universidade Federal do Rio Grande do Sul/UFRGS, Porto Alegre, RS, Brazil
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3 Centro Universitario Regional del Este, Sede CURE-Rocha, Ruta 9 s/n , Rocha
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(27000), Uruguay
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Corresponding author: [email protected]
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Abstract
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This study addresses the surface sediment composition and distribution in Mirim
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Lagoon, a large coastal shallow transboundary system located on the border of South
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Brazil and Uruguay, which is 3749 km2 and maximum depth is around 6 m, in relation
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to the hydrodynamic conditions evolved from predominant winds. Surface water
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currents in the marginal area displayed maximum speed values of 0.25 to 0.3 m s-1
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flowing parallel to the coastline either under NE of SW wind predominance. The
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marginal zone, above the 6 m bathymetric contour comprise sandy sediments, indicating
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that under such a combination of bathymetric and hydrodynamic conditions, the
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resuspension of fine sediments is dominant. Lower surface current velocity observed in
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the central zone of the lagoon located below the 6 m isobath (i.e., 0.05 m s-1), together
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with an increase in the maximum width of the lagoon, promoted conditions for
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deposition of the clay sediment fraction. Therefore, the combined use of
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sedimentological and hydrodynamic data represents a useful tool to infer patterns of
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deposition and resuspension in coastal systems. Given the large size of the Mirim
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Lagoon and associated difficulties in sampling and monitoring the system, the
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information presented here is important for environmental management, and particularly
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for planning future paleolimnological research and set the coring stations on appropriate
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coordinates within the central region, where relatively calm conditions and dominance
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of clay sediments are observed.
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Keywords: deposition, hydrodynamics, morphometry, resuspension,
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Introduction
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The coastal zone contains shallow transitional aquatic environments that are highly
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sensitive to external forcing. Such transitional environments are characterized by
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restricted water circulation where natural events such as sea-level oscillations, abnormal
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river floods, storms and anthropic activities lead to modifications of a number of key
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physical and chemical process, but also morphological and sedimentological features.
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Furthermore, the interaction between marine and terrestrial processes induce high
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variability of both physical and sedimentological properties (Spagnoli and Andresini,
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2018), which are mainly modulated by water circulation evolved from wind intensity
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and direction (Costi et al., 2018; Oliveira et al., 2019). In this sense, water circulation of
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lenthic systems is important in explaining the composition and distribution of the
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sediment bed (Ulmann et al., 2003).
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Knowledge of the surface sediment compositon and distribution of aquatic systems is
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important prior to the implementation of human activities but also for conservation and
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envirommental management purposes. The formation of sedimentary facies in large
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coastal shallow lagoons depends on the supply of suspended solids from river networks,
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which is then either deposited or resuspended within the lenthic domain (Afri et al.,
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1994; Petti et al., 2018). Thus, surface sediment distribution is a consequence of
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morphodynamic processes involving water circulation and bottom morphometry (Toldo,
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1991; Arfi et al., 1994; Naya et al., 2004; Gardner et al, 2018). The study of surface
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sediments is particularly interesting in large coastal shallow systems, because the
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interaction between aquatic and sedimentary processes is highly dynamic, given the
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large contact surface area succeptible to resuspension and deposition (Gardner and
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Journal Pre-proof Doyle, 2018). The east coast of South America holds the world’s largest coastal shallow
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lagoonal system of the world, the Patos-Mirim System, with an area of 13,749 km2,
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where the Patos Lagoon comprises 10,000 km2 and Mirim Lagoon 3749 km2 (Toldo,
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1994; Friedrich et al., 2006). As the system is connected to the Atlantic Ocean through a
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single microtidal inlet, the dynamics of the both lagoons is driven by freshwater
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discharge contributions and wind effects. Thus, this system represents an excellent
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study case for assessing trends in the distribution and composition of surface sediments
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in relation to dominant winds and wind-driven hydrodynamics. Given that several
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studies on the sedminent bed composition have been published for Patos Lagoon
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(Toldo, 1991; 1994; Toldo et al., 2000; Calliari et al., 2009), it is important to study the
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surface sediment of Mirim Lagoon for providing a more precise sedimentological
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understanding of the Patos-Mirim System as a whole (Fig. 1).
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Vieira (1995) presented a thorough review of the geological setting of the watershed,
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formation of the lagoon, Quaternary evolution, and surface sediment properties and
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origin. More recent studies foccused on understanding the hydrodynamic response of
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the Mirim Lagoon to the wind effect and water circulation. Hirata et al. (2010) observed
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that the long-term water level oscillations in the lagoon were strongly linked to the El
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Nino-South Oscillation (ENSO). Oliveira et al. (2015) characterized the hydrological
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regime of the main water inputs to the Mirim lagoon and constructed a stage-discharge
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rating curve. Costi et al. (2018) used a combination of 2D numerical simulations, gauge
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station data, and Synthetic Aperture RADAR imaging to evaluate the influence of
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incident winds and main tributaries discharge on the system water level and the
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establishment of barotropic gradients between the Mirim lagoon and São Gonçalo
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channel. Oliveira et al. (2019) presented a novel integrated approach between the Patos
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and Mirim lagoons and the adjacent coastal region, thus generating a realistic prediction
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of the Mirim Lagoon hydrodynamic response. The authors suggested that the lagoon
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can be divided in three regions where currents have a distinct behaviour.
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In this paper, we have re-visited the grain size distribution/composition database from
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Vieira (1995), and related them to the dominant hydrodynamic conditions to infer the
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processes modulating sediment deposition and resuspension in this large shallow coastal
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system.
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Study area
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The Patos and Mirim lagoons are connected through the 76 km long São Gonçalo
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Channel, forming the so-called Patos-Mirim System (Fig. 1). This transboundary
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lagoonal system is located in the coastal plain of the State of Rio Grande do Sul (RS,
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Brazil) and eastern Uruguay (Fig. 1). This system integrates the Pelotas basin, which is
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one of several sedimentary basins occurring along the Brazilian and Uruguayan
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continental margin. The onset of the Pelotas basin occurred in the early Cretaceous and
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it evolved as a passive marginal basin (Dias et al., 1994), with itlandward limit being
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with Precambrian and Paleozoic highlands, and coastal limits at Santa Marta Cape
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(Santa Catarina State, Brazil) and La Coronilla (Rocha State, Uruguay) (Fig. 1). Both
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allogenic and autogenic forcing factors influenced the depositional sequence framework
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of the coastal zone (Bortolin et al., 2018), where sea-level changes play the allogenic
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control responsible for the regional geologic evolution (Tomazelli and Villwock, 2000;
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Bortolin et al., 2019).
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Journal Pre-proof The rivers of the Mirim Lagoon watershed (i.e., Cebolatti, Taquari, Jaguarão and
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Piratini) drain landward bedrock highlands of the Precambrian basement (Rio Grande
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do Sul and Uruguay Shield), whose eroded sediments are fluvially transported and
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deposited off the coastal zone sedimentary system. A fringe of coarser sediment (mainly
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gravel, coarse sand, and mud) of the alluvial fan system (up to 50 km wide) makes the
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transition between the highlands (up to 500 m altitude) and the low-lying coastal plain.
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The sedimentary deposits around the Mirim Lagoon (Dillenburg et al., 2017) alternate
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mainly fine sands of coastal barriers and lagoon muds of the various lagoon-barrier
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depositional systems deposited there during the Quaternary (Fig. 1; bottom right panel).
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The coastal plain was subaerially exposed and deeply fluvially incised during numerous
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sea-level rise and fall events of the Quaternary period (Weschenfelder et al., 2008,
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2010, 2014, 2016), and more clearly after the last interglacial maximum of 120 ky BP
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(Cooper et al., 2018; Bortolin et al., 2018, 2019). Fluvial dissection of the coastal relief
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during forced regression events led to the formation of a series of adjacent incised
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valleys, accommodating base-level fall and long lowstand periods (Weschenfelder and
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Corrêa, 2018), which were flooded during subsequent transgressive events
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(Weschenfelder et al., 2014; Santos-Fischer et al., 2016, 2018; Bortolin et al., 2019;
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Scottá et al., 2019). The regional low-relief coastal plain is one of the widest in the
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world, in which its width reaches up to 80 km. Sandy barriers and several lagoons with
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“restinga” vegetation characterize this coastal plain. The shelf exhibits a smooth
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morphology, very gentle slope (~1.4 m/km) and it is 125 km wide. It shows several
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marine terraces inherited as a morphological testimony of periods of sea-level
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stabilization during the Holocene transgression (Corrêa, 1996). The regional coastal
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plain sedimentary deposits alternate coastal-barrier sands and lagoonal muds by the
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juxtaposition of four barrier/lagoon depositional systems designated I to IV (oldest to
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youngest) by Villwock et al. (1986). They have been correlated with distinct Pleistocene
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and Holocene highstands (Tomazelli and Villwock, 2000), corresponding to high-
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frequency depositional sequences (Fisher and McGowen, 1967; Villwock and
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Tomazelli, 1995; Rosa et al., 2011, 2017), which in turn should confirm the correlation
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between sea-level variation and climate changes occurring during the Quaternary
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period.
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The Patos and Mirim system is warm-temperate and covers around 14,000 km2,
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extending up to 500 km in the broad NE-SW direction and averaging 40 km wide and 6
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m depth. Local waves up to 1.6 m high influence the bottom and margins of the lagoon
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(Toldo et al., 2000). The bottom sediments comprise a fringe of marginal sands (~ 60%
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in area) and internal muds, where water depths around 5 and 6 m separate both areas.
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The Mirim Lagoon covers 3749 km2 and has a maximum depth of around 6 m. The
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Mirim Lagoon´s main flow is into the Patos Lagoon (Oliveira et al., 2015), as there is a
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dam preventing brackish waters entering from the Patos Lagoon (Vieira and Rangle,
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1988; Gouvêa et al., 2010). Besides its importance for the quality of life of approximate
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1 million people who live within its catchment basin, the Mirim Lagoon plays an
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important role as a reservouir of freshwater (Oliveira et al., 2015). It is essential for the
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maintenance of humidity in Taim's wetlands, recognized as a Biosphere Reserve by
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UNESCO and feeding and breeding grounds for migrant birds. Furthermore, rice culture
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is the main economic activity in its catchment area, using lagoon waters for irrigation
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(Olivera et al., 2019).
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The hydrodynamics of the lagoon are modulated by the local wind acting on time scales
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of 2-12 days to establish water slopes of up to 3 m between extremities and promote
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water level increase (decrease) at the north during winds from the SW (NE) (Oliveira et
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al., 2015). Current velocities are stronger and recirculation cells are more evident during
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SW winds, with maximum current velocities at the surface of the Mirim Lagoon
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occurring around São Gonçalo Channel (Fig. 1) during periods of high discharge
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(Oliveira et al., 2019).
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Materials and methods
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Grain size data of 142 surface sediment samples of the Mirim Lagoon (Fig. 2a) obtained
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from Vieira (1995) were used to plot the sediment distribution and infer sedimentary
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facies (Fig. 2c). Samples were treated with hydrogen peroxide and hydrchloric acid to
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remove organic matter and carbonate respectively. The samples were then rinsed and
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dried in the oven. Samples were sieved with a rotup using sive intervals of 0.25ɸ, and
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the silt-clay fraction was assessed by pipetting (Krumbein and Pettijohn, 1938). Surface
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sediments were classified according to Wentworth (1922), Shepard (1954) textural
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classification and Folk and Ward (1957) statistical parameters. Data were expressed as
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percentage of sand, silt and clay, as well as the statistical parameters of arithmetic mean
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(Mz) (Fig. 3). The bathymetric map of Mirim Lagoon (Fig. 2b) is slightly modified
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from the original presented by Vieira (1995), at a scale of 1:260,000, by adding a depth
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gradient in shade of gray scale to improve the graphical quality and visual perception of
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the bottom morphometry.
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Journal Pre-proof Because of the large area covered by the Patos-Mirim system, the high variability in
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physical forcing and the limited field data available, numerical modelling is a
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recommended tool, as it allows high spatio-temporal resolution. From model results, it
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is possible to accomplish a detailed study of the system, and infer its response to
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physical forcing. Hydrodynamic information was generated by the numerical model
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TELEMAC-3D (www.opentelemac.org), developed by the Laboratoire National
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d´Hydraulique et Environment, of Companhie Electricité de France (©EDF). This
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model has been extensively applied to the Patos Lagoon (Fernandes et al., 2001, 2002,
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2004, 2005; Marques et al. 2009, 2010a ,2010b), and more recently to the Mirim
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Lagoon by Costi et al. (2018, 2019) and Oliveira et al. (2019).
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The TELEMAC-3D hydrodynamic model solves the Navier-Stokes equations
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considering the local variation in the fluid free surface, ignoring the density variations
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in the mass conservation equation and applying the Boussinesq approximation to solve
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momentum equations (Hervouet, 2007). The resulting partial differential equations,
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combined with initial and boundary conditions, were discretized in the model by a finite
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element, triangular, non-structured mesh (see Supplementary material). This approach
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makes it possible to set spatially varying mesh resolutions, with increased resolution for
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regions with large velocity gradients and/or complex bottom topography. The correct
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representation of these features increase model efficiency in predicting the
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environmental behaviour and also provides a more stable numerical solution.
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Oliveira et al. (2019) describes in detail the TELEMAC-3D model calibration,
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validation and application to the Patos-Mirim System for a three-dimensional 1-year
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long simulation, and their hydrodynamic results will be used in this study.
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Results
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Sediment distribution and morphometry
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The Mirim Lagoon is a large shallow system, whose deepest section has in the same
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orientation as the maximum-length axis (Fig. 2b). The maximum depth in such areas
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reaches 6 m and the sediment composition is dominated by the fine fraction (i.e., 30-
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40% silt and 20-30% clay, Fig. 3). Three main regions can be identified. The extreme
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northeastern region, being the largest section and displaying the maximum width of the
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lagoon, shows the highest relative percentages of fine sediment (Fig. 3), which accounts
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together for almost 100% of the relative sediment composition. The central region,
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where the transversal axis is narrower than that of the northeastern section, has a
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sediment composition consist of 30-40% silt, 20-30% clay, and the remaining fraction
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contains at most 30% of sand (Fig. 3). Finally, the extreme southwestern region, which
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is similar in both sediment composition and dimensions to those of central region.
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According to the above mentioned grain size distributions, the main sedimentary facies
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consist of a peripheric region, which encompasses the whole lagoon littoral contour
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zone down to the 3-4 m isobath (Fig. 2). Such a sedimentary facies corresponds
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basically to sand and to a lesser extent silty-sand and sandy-silt. Below the 4-5 m
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isobath (Fig. 2), there is a shift in the sedimentary facies classification, where the facies
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are dominated by clayey-silt in both the northern and southern extremes. In the central
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region below the 4-5 m isobath, sedimentary facies consists of silty-sand and sandy-silt
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(Fig. 2).
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Current velocity and direction
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Fig. 4 shows the calculated surface current velocity vectors at different regions of the
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Mirim Lagoon under the maximum SW and NE winds observed during a one-year long
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simulation period (Oliveira et al., 2019). Results indicate that during such maximum
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events the water flow displays a clear pattern in relation to the wind direction (Olivera
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et al. 2019), being transported towards the Patos Lagoon during SW winds, and towards
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Uruguay during NE winds (Fig. 4). Recirculation cells are evident throughout the
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lagoon mainly during NE wind, which is actually the predominant wind direction over
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the region. In addition, the relative distribution of current direction and intensity over
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one year is shown in the directional roses, which were derived from three transects
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depicted on the maps (Fig. 4). According to the annual mean current velocity/direction
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frequency distribution, it was possible to divide the lagoon into three main
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hydrodynamic areas (Fig. 4): the extreme north, where northeastern current velocities
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reaching 0.35-0,40 m s-1 are predominant, flowing towards the Patos Lagoon; the
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central area, where current velocities between 0.05-0.1 m s-1 are predominant, and
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although the mean flux is towards the Patos Lagoon, a broad direction spectrum was
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observed; and the extreme south, where the number of recirculation cells is more
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significant, resulting in high current direction variability, mainly ranging from 0.1–0.15
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m s-1. Although the wind action promotes water level slopes between the lagoon
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extremities (Olivera et al., 2015; Costi et al., 2018; Olivera et al., 2019), and creates and
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shapes recirculation cells, it does not change the orientation of the flow direction
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towards the Patos Lagoon, even under northern wind conditions (Costi et al., 2018;
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Oliveira et al., 2019, Vieira da Silva et al., 2019) (Fig. 4). In this context, the flow
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orientation can be only reversed during extremely low water level inside the Mirim
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Lagoon, but even under such conditions, the Patos Lagoon salt wedge does not intrude
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Journal Pre-proof into the Mirim Lagoon due to the presence of the São Gonçalo Channel dam (Gouvea et
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al., 2010) (Fig. 1). Historical data and associated modelling results indicate that the
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Mirim Lagoon maximum surface current velocity is attained at the São Gonçalo
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Channel, usually ranging from 0.2 to 0.5 m s-1 under high water discharge conditions
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(Fig. 4). Under the dominance of strong SW winds, the highest surface current velocity
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within the system can achieve values of 0.6 m s-1 (Comissão da Lagoa Mirim - CLM,
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1970). Such wind conditions and current velocity, combined with the occurrence of
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shallow water areas, promote the occurrence of sand spits and the relatively flat bottom
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topography (Oliveira et al., 2015).
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Discussion
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The Patos-Mirim system is a highly turbid environment fed by several turbid large
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rivers, which total supply of fine suspended sediments is 5.1 x 106 ton yr-1 to the Patos
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Lagoon (Jung et al., submitted) from which the Mirim Lagoon accounts for 1.8 x 106
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ton yr -1 (Jung et al., submitted). The final fate of the fine suspended material is the
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lagoon system in the first place, and the inner continental shelf secondarily (Calliari et
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al., 2009, Marques et al., 2009; Vinzon et al., 2009). In the case of the Patos Lagoon
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there is evidence from the morphodynamics, composition and distribution of the surface
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sediment bed (Toldo, 1991, 1994; Toldo et al., 2000; Calliari et al., 2009; Lisboa et al.,
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2015) but in the case of the Mirim Lagoon, there is comparatively an important lack of
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information.
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The surface sediment composition and distribution of Mirim Lagoon consists of
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an outer littoral zone dominated by sandy sediments. However, the composition and
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origin of such sandy facies within the west and east littoral, is different. The sand-
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during the Pleistocene and consists, therefore, of well sorted sand with very reduced silt
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content (Vieira, 1995). The sand on the west littoral is supplied by large turbid rivers
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(i.e., Jaguarão, Taquarí and Cebollatí Rivers) and inundated areas (Oliveira et al., 2015:
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Costi et al., 2018) and therefore, such sandy facies is poorly selected as it contains silt
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and clay fractions (Vieira, 1995). The perimeter boundary of this external sandy facies
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can be set on the 5 to 6 m isobath (see comparison between morphometry and
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sedimentary facies, Fig. 2) and it is distributed parallel to the maximum-length axis of
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the system. The surface current velocity at the marginal areas displays medium/low
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values (i.e., 0.25 m s-1) at both margins of the lagoon, flowing parallel to the coast either
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under NE or SW wind dominance.
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The combination of such morphometric and hydrodynamic conditions within the
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west margin is likely to promote fine sediment resuspension rather than deposition. On
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the east margin, however, this superficial facies exhibits the lowest relative abundance
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of fine sediment particles (i.e., clayey) as the dominant fraction is well sorted sand.
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Thus, in this region currents are likely to resuspend sand. In this sense, the littoral
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surface sediment composition is modulated by the relationship between depth and
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current velocity/direction, mainly parallel to the maximum length axis, under either NE
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or SW wind directions (Fig. 4). Similar environmental conditions for resuspension have
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been observed in this shallow system (Toldo, 1994; Cózar et al., 2005) and in other
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regions of the world (Naya et al., 2004).
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The sedimentary facies lying below the 6 m isobath, is mostly dominated by
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clayey-silty sediments, except for the constricted narrowest part of the central section
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(as depicted in Fig. 4), where the maximum current velocity (under SW winds) is
Journal Pre-proof observed (i.e., 0.35 to 0.4 m s -1). Hence, under such conditions of wind dominance and
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high surface current velocities, resuspension is expected to be dominant, as inferred
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from the dominance of sandy sediments. Therefore, the most abundant sediment
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fraction is fine sand, and the associated inferred sedimentary facies is silty-sand and
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sandy-silt (see Figs. 2 and 3). A similar distribution pattern has been inferred for the
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Patos Lagoon by Toldo (1994), who identified a littoral zone dominated by sandy
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sediments, and an internal central zone dominated by fine sediments. The surface
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current velocity sharply decreases towards the thickened section of the central zone
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(Fig. 4), as the lagoon width increases from about 20 km to 40 km. Because of such an
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increase in lagoon width, together with the decreased current velocity, calm water
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conditions are promoted in this region, and thus, the finest sediment fraction is
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deposited below the 6 m isobath. Likewise, the extreme south region (as shown in Fig,
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4) also displays relatively low surface water velocity, and for the same reason as
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explained above, the finest sediment fraction is deposited below the 6 m isobath and the
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associated inferred sedimentary facies is silty-sand and sandy-silt.
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the river discharge presents an intra-seasonal to annual timescales variability
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(Costi et al., 2018; Vieira da Silva et al., 2019), and the associated mean residence time
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is 180 days, although the northern (350 days) and southern (100 days) section exhibit
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remarkably different residence times (Vieira da Silva et al., 2019). Such a residence
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time is important in regulating the source-to-sink process is very involved in the
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formation of the recent sedimentary bed containing a high-resolution record of the
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contemporary human impacts from river dams, agriculture, milk industry, mining and
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forestry activities. Therefore, this sedimentary facies, distributed in the central region of
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the lagoon below the 6 m isobath appears to represent an excellent source of
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paleolimnological information.
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Concluding remarks
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The sediment bed composition of Mirim Lagoon is a consequence of the water
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circulation regime evolved from predominant wind exposure, which generates a littoral
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resuspension zone dominated by sand, and a central deposition zone dominated by silt.
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The inferred sedimentary facies from both resuspension and deposition zones are set
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parallel to the maximum length axis of the lagoon and they are distributed in relation to
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the bathymetric features.
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Acknowledgements
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This paper is dedicated to the memory of H.M. Vieira who devoted her
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professional life to sedimentological research in Rio Grande, Brazil. Thanks to FINEP
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for
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01.11.0141.01) and REHMANSA (grant 01.12.0064.00), and to CNPq for the research
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grants 551436/2011-5 (EHF), 308274/2011-3 (EHF), and 302231/2010–2 (OOM).
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Jasper Knight and an anonymous reviewer provided helpful comments that improved
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this paper.
sponsoring
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Figure captions
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Fig. 1. Upper left panel: regional extension of the Patos-Mirim system. Central panel:
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The Mirim Lagoon catchment area and main large inflowing rivers. Lower left panel:
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general geological setting according to Dillemburg et al. (2017).
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Fig. 2. Surface sediment sampling stations, morphometry and surface sedimentary
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facies of Mirim Lagoon.
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Fig. 3. Surface sediment composition expressed as Mz Wenworth size classes sand
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percentage of sand, silt and clay. The associated sedimentary facies are shown in Fig. 2.
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Fig. 4. Calculated surface current velocity vectors at different Mirim Lagoon regions
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for the maximum southwestern wind (left panels) and maximum northeastern wind
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(right panels) observed during a one year simulation period. Center panels: monthly
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frequency distribution of surface currents for extreme north (transect T1), central
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(transect T2), and extreme south (transect T3) regions.Modified from Oliveira et al.
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(2019).
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Journal Pre-proof Highlights Large shallow coastal turbid system driven by wind. Current direction and speed modulate resuspension and deposition processes. Below/above the 6 m isobath, sediment deposition/resuspension were inferred. Deposition/resuspension zone dominated by clay/sand.
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Hydrodynamics + morphometry = sediment composition/distribution
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Figure 1
Figure 2
Figure 3
Figure 4
H.M. Vieira, Jair Weschenfelder, Elisa Helena Fernandes, Heline Alves Oliveira, Osmar Olinto Möller, Felipe García-Rodríguez PII:
S0037-0738(20)30003-8
DOI:
https://doi.org/10.1016/j.sedgeo.2020.105591
Reference:
SEDGEO 105591
To appear in:
Sedimentary Geology
Received date:
19 October 2019
Revised date:
6 January 2020
Accepted date:
7 January 2020
Please cite this article as: H.M. Vieira, J. Weschenfelder, E.H. Fernandes, et al., Links between surface sediment composition, morphometry and hydrodynamics in a large shallow coastal lagoon, Sedimentary Geology(2020), https://doi.org/10.1016/ j.sedgeo.2020.105591
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Journal Pre-proof 1
Links between surface sediment composition, morphometry and
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hydrodynamics in a large shallow coastal lagoon
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H.M. Vieira1†, Jair Weschenfelder2, Elisa Helena Fernandes1, Heline Alves Oliveira1
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Osmar Olinto Möller1, Felipe García-Rodríguez1,3
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† Deceased on September 2nd 1997
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1 Laboratório de Oceanografia Costeira e Estuarina (LOCOSTE), Instituto de
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Oceanografia – Universidade Federal do Rio Grande (FURG), Rio Grande, Brazil
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2 Centro de Estudos de Geologia Costeira e Oceânica (CECO), Instituto de Geociências,
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Universidade Federal do Rio Grande do Sul/UFRGS, Porto Alegre, RS, Brazil
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3 Centro Universitario Regional del Este, Sede CURE-Rocha, Ruta 9 s/n , Rocha
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(27000), Uruguay
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Corresponding author: [email protected]
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Abstract
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This study addresses the surface sediment composition and distribution in Mirim
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Lagoon, a large coastal shallow transboundary system located on the border of South
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Brazil and Uruguay, which is 3749 km2 and maximum depth is around 6 m, in relation
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to the hydrodynamic conditions evolved from predominant winds. Surface water
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currents in the marginal area displayed maximum speed values of 0.25 to 0.3 m s-1
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flowing parallel to the coastline either under NE of SW wind predominance. The
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marginal zone, above the 6 m bathymetric contour comprise sandy sediments, indicating
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that under such a combination of bathymetric and hydrodynamic conditions, the
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resuspension of fine sediments is dominant. Lower surface current velocity observed in
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the central zone of the lagoon located below the 6 m isobath (i.e., 0.05 m s-1), together
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with an increase in the maximum width of the lagoon, promoted conditions for
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deposition of the clay sediment fraction. Therefore, the combined use of
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sedimentological and hydrodynamic data represents a useful tool to infer patterns of
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deposition and resuspension in coastal systems. Given the large size of the Mirim
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Lagoon and associated difficulties in sampling and monitoring the system, the
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information presented here is important for environmental management, and particularly
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for planning future paleolimnological research and set the coring stations on appropriate
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coordinates within the central region, where relatively calm conditions and dominance
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of clay sediments are observed.
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Keywords: deposition, hydrodynamics, morphometry, resuspension,
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Introduction
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The coastal zone contains shallow transitional aquatic environments that are highly
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sensitive to external forcing. Such transitional environments are characterized by
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restricted water circulation where natural events such as sea-level oscillations, abnormal
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river floods, storms and anthropic activities lead to modifications of a number of key
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physical and chemical process, but also morphological and sedimentological features.
54
Furthermore, the interaction between marine and terrestrial processes induce high
55
variability of both physical and sedimentological properties (Spagnoli and Andresini,
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2018), which are mainly modulated by water circulation evolved from wind intensity
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and direction (Costi et al., 2018; Oliveira et al., 2019). In this sense, water circulation of
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lenthic systems is important in explaining the composition and distribution of the
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sediment bed (Ulmann et al., 2003).
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Knowledge of the surface sediment compositon and distribution of aquatic systems is
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important prior to the implementation of human activities but also for conservation and
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envirommental management purposes. The formation of sedimentary facies in large
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coastal shallow lagoons depends on the supply of suspended solids from river networks,
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which is then either deposited or resuspended within the lenthic domain (Afri et al.,
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1994; Petti et al., 2018). Thus, surface sediment distribution is a consequence of
66
morphodynamic processes involving water circulation and bottom morphometry (Toldo,
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1991; Arfi et al., 1994; Naya et al., 2004; Gardner et al, 2018). The study of surface
68
sediments is particularly interesting in large coastal shallow systems, because the
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interaction between aquatic and sedimentary processes is highly dynamic, given the
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large contact surface area succeptible to resuspension and deposition (Gardner and
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Journal Pre-proof Doyle, 2018). The east coast of South America holds the world’s largest coastal shallow
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lagoonal system of the world, the Patos-Mirim System, with an area of 13,749 km2,
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where the Patos Lagoon comprises 10,000 km2 and Mirim Lagoon 3749 km2 (Toldo,
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1994; Friedrich et al., 2006). As the system is connected to the Atlantic Ocean through a
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single microtidal inlet, the dynamics of the both lagoons is driven by freshwater
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discharge contributions and wind effects. Thus, this system represents an excellent
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study case for assessing trends in the distribution and composition of surface sediments
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in relation to dominant winds and wind-driven hydrodynamics. Given that several
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studies on the sedminent bed composition have been published for Patos Lagoon
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(Toldo, 1991; 1994; Toldo et al., 2000; Calliari et al., 2009), it is important to study the
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surface sediment of Mirim Lagoon for providing a more precise sedimentological
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understanding of the Patos-Mirim System as a whole (Fig. 1).
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Vieira (1995) presented a thorough review of the geological setting of the watershed,
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formation of the lagoon, Quaternary evolution, and surface sediment properties and
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origin. More recent studies foccused on understanding the hydrodynamic response of
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the Mirim Lagoon to the wind effect and water circulation. Hirata et al. (2010) observed
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that the long-term water level oscillations in the lagoon were strongly linked to the El
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Nino-South Oscillation (ENSO). Oliveira et al. (2015) characterized the hydrological
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regime of the main water inputs to the Mirim lagoon and constructed a stage-discharge
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rating curve. Costi et al. (2018) used a combination of 2D numerical simulations, gauge
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station data, and Synthetic Aperture RADAR imaging to evaluate the influence of
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incident winds and main tributaries discharge on the system water level and the
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establishment of barotropic gradients between the Mirim lagoon and São Gonçalo
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channel. Oliveira et al. (2019) presented a novel integrated approach between the Patos
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and Mirim lagoons and the adjacent coastal region, thus generating a realistic prediction
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of the Mirim Lagoon hydrodynamic response. The authors suggested that the lagoon
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can be divided in three regions where currents have a distinct behaviour.
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In this paper, we have re-visited the grain size distribution/composition database from
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Vieira (1995), and related them to the dominant hydrodynamic conditions to infer the
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processes modulating sediment deposition and resuspension in this large shallow coastal
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system.
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Study area
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The Patos and Mirim lagoons are connected through the 76 km long São Gonçalo
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Channel, forming the so-called Patos-Mirim System (Fig. 1). This transboundary
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lagoonal system is located in the coastal plain of the State of Rio Grande do Sul (RS,
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Brazil) and eastern Uruguay (Fig. 1). This system integrates the Pelotas basin, which is
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one of several sedimentary basins occurring along the Brazilian and Uruguayan
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continental margin. The onset of the Pelotas basin occurred in the early Cretaceous and
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it evolved as a passive marginal basin (Dias et al., 1994), with itlandward limit being
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with Precambrian and Paleozoic highlands, and coastal limits at Santa Marta Cape
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(Santa Catarina State, Brazil) and La Coronilla (Rocha State, Uruguay) (Fig. 1). Both
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allogenic and autogenic forcing factors influenced the depositional sequence framework
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of the coastal zone (Bortolin et al., 2018), where sea-level changes play the allogenic
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control responsible for the regional geologic evolution (Tomazelli and Villwock, 2000;
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Bortolin et al., 2019).
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Journal Pre-proof The rivers of the Mirim Lagoon watershed (i.e., Cebolatti, Taquari, Jaguarão and
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Piratini) drain landward bedrock highlands of the Precambrian basement (Rio Grande
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do Sul and Uruguay Shield), whose eroded sediments are fluvially transported and
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deposited off the coastal zone sedimentary system. A fringe of coarser sediment (mainly
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gravel, coarse sand, and mud) of the alluvial fan system (up to 50 km wide) makes the
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transition between the highlands (up to 500 m altitude) and the low-lying coastal plain.
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The sedimentary deposits around the Mirim Lagoon (Dillenburg et al., 2017) alternate
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mainly fine sands of coastal barriers and lagoon muds of the various lagoon-barrier
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depositional systems deposited there during the Quaternary (Fig. 1; bottom right panel).
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The coastal plain was subaerially exposed and deeply fluvially incised during numerous
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sea-level rise and fall events of the Quaternary period (Weschenfelder et al., 2008,
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2010, 2014, 2016), and more clearly after the last interglacial maximum of 120 ky BP
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(Cooper et al., 2018; Bortolin et al., 2018, 2019). Fluvial dissection of the coastal relief
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during forced regression events led to the formation of a series of adjacent incised
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valleys, accommodating base-level fall and long lowstand periods (Weschenfelder and
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Corrêa, 2018), which were flooded during subsequent transgressive events
137
(Weschenfelder et al., 2014; Santos-Fischer et al., 2016, 2018; Bortolin et al., 2019;
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Scottá et al., 2019). The regional low-relief coastal plain is one of the widest in the
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world, in which its width reaches up to 80 km. Sandy barriers and several lagoons with
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“restinga” vegetation characterize this coastal plain. The shelf exhibits a smooth
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morphology, very gentle slope (~1.4 m/km) and it is 125 km wide. It shows several
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marine terraces inherited as a morphological testimony of periods of sea-level
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stabilization during the Holocene transgression (Corrêa, 1996). The regional coastal
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plain sedimentary deposits alternate coastal-barrier sands and lagoonal muds by the
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juxtaposition of four barrier/lagoon depositional systems designated I to IV (oldest to
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youngest) by Villwock et al. (1986). They have been correlated with distinct Pleistocene
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and Holocene highstands (Tomazelli and Villwock, 2000), corresponding to high-
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frequency depositional sequences (Fisher and McGowen, 1967; Villwock and
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Tomazelli, 1995; Rosa et al., 2011, 2017), which in turn should confirm the correlation
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between sea-level variation and climate changes occurring during the Quaternary
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period.
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The Patos and Mirim system is warm-temperate and covers around 14,000 km2,
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extending up to 500 km in the broad NE-SW direction and averaging 40 km wide and 6
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m depth. Local waves up to 1.6 m high influence the bottom and margins of the lagoon
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(Toldo et al., 2000). The bottom sediments comprise a fringe of marginal sands (~ 60%
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in area) and internal muds, where water depths around 5 and 6 m separate both areas.
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The Mirim Lagoon covers 3749 km2 and has a maximum depth of around 6 m. The
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Mirim Lagoon´s main flow is into the Patos Lagoon (Oliveira et al., 2015), as there is a
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dam preventing brackish waters entering from the Patos Lagoon (Vieira and Rangle,
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1988; Gouvêa et al., 2010). Besides its importance for the quality of life of approximate
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1 million people who live within its catchment basin, the Mirim Lagoon plays an
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important role as a reservouir of freshwater (Oliveira et al., 2015). It is essential for the
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maintenance of humidity in Taim's wetlands, recognized as a Biosphere Reserve by
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UNESCO and feeding and breeding grounds for migrant birds. Furthermore, rice culture
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is the main economic activity in its catchment area, using lagoon waters for irrigation
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(Olivera et al., 2019).
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The hydrodynamics of the lagoon are modulated by the local wind acting on time scales
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of 2-12 days to establish water slopes of up to 3 m between extremities and promote
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water level increase (decrease) at the north during winds from the SW (NE) (Oliveira et
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al., 2015). Current velocities are stronger and recirculation cells are more evident during
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SW winds, with maximum current velocities at the surface of the Mirim Lagoon
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occurring around São Gonçalo Channel (Fig. 1) during periods of high discharge
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(Oliveira et al., 2019).
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Materials and methods
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Grain size data of 142 surface sediment samples of the Mirim Lagoon (Fig. 2a) obtained
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from Vieira (1995) were used to plot the sediment distribution and infer sedimentary
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facies (Fig. 2c). Samples were treated with hydrogen peroxide and hydrchloric acid to
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remove organic matter and carbonate respectively. The samples were then rinsed and
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dried in the oven. Samples were sieved with a rotup using sive intervals of 0.25ɸ, and
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the silt-clay fraction was assessed by pipetting (Krumbein and Pettijohn, 1938). Surface
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sediments were classified according to Wentworth (1922), Shepard (1954) textural
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classification and Folk and Ward (1957) statistical parameters. Data were expressed as
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percentage of sand, silt and clay, as well as the statistical parameters of arithmetic mean
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(Mz) (Fig. 3). The bathymetric map of Mirim Lagoon (Fig. 2b) is slightly modified
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from the original presented by Vieira (1995), at a scale of 1:260,000, by adding a depth
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gradient in shade of gray scale to improve the graphical quality and visual perception of
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the bottom morphometry.
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Journal Pre-proof Because of the large area covered by the Patos-Mirim system, the high variability in
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physical forcing and the limited field data available, numerical modelling is a
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recommended tool, as it allows high spatio-temporal resolution. From model results, it
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is possible to accomplish a detailed study of the system, and infer its response to
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physical forcing. Hydrodynamic information was generated by the numerical model
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TELEMAC-3D (www.opentelemac.org), developed by the Laboratoire National
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d´Hydraulique et Environment, of Companhie Electricité de France (©EDF). This
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model has been extensively applied to the Patos Lagoon (Fernandes et al., 2001, 2002,
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2004, 2005; Marques et al. 2009, 2010a ,2010b), and more recently to the Mirim
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Lagoon by Costi et al. (2018, 2019) and Oliveira et al. (2019).
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The TELEMAC-3D hydrodynamic model solves the Navier-Stokes equations
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considering the local variation in the fluid free surface, ignoring the density variations
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in the mass conservation equation and applying the Boussinesq approximation to solve
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momentum equations (Hervouet, 2007). The resulting partial differential equations,
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combined with initial and boundary conditions, were discretized in the model by a finite
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element, triangular, non-structured mesh (see Supplementary material). This approach
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makes it possible to set spatially varying mesh resolutions, with increased resolution for
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regions with large velocity gradients and/or complex bottom topography. The correct
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representation of these features increase model efficiency in predicting the
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environmental behaviour and also provides a more stable numerical solution.
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Oliveira et al. (2019) describes in detail the TELEMAC-3D model calibration,
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validation and application to the Patos-Mirim System for a three-dimensional 1-year
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long simulation, and their hydrodynamic results will be used in this study.
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Results
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Sediment distribution and morphometry
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The Mirim Lagoon is a large shallow system, whose deepest section has in the same
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orientation as the maximum-length axis (Fig. 2b). The maximum depth in such areas
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reaches 6 m and the sediment composition is dominated by the fine fraction (i.e., 30-
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40% silt and 20-30% clay, Fig. 3). Three main regions can be identified. The extreme
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northeastern region, being the largest section and displaying the maximum width of the
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lagoon, shows the highest relative percentages of fine sediment (Fig. 3), which accounts
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together for almost 100% of the relative sediment composition. The central region,
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where the transversal axis is narrower than that of the northeastern section, has a
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sediment composition consist of 30-40% silt, 20-30% clay, and the remaining fraction
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contains at most 30% of sand (Fig. 3). Finally, the extreme southwestern region, which
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is similar in both sediment composition and dimensions to those of central region.
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According to the above mentioned grain size distributions, the main sedimentary facies
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consist of a peripheric region, which encompasses the whole lagoon littoral contour
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zone down to the 3-4 m isobath (Fig. 2). Such a sedimentary facies corresponds
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basically to sand and to a lesser extent silty-sand and sandy-silt. Below the 4-5 m
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isobath (Fig. 2), there is a shift in the sedimentary facies classification, where the facies
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are dominated by clayey-silt in both the northern and southern extremes. In the central
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region below the 4-5 m isobath, sedimentary facies consists of silty-sand and sandy-silt
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(Fig. 2).
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Current velocity and direction
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Fig. 4 shows the calculated surface current velocity vectors at different regions of the
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Mirim Lagoon under the maximum SW and NE winds observed during a one-year long
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simulation period (Oliveira et al., 2019). Results indicate that during such maximum
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events the water flow displays a clear pattern in relation to the wind direction (Olivera
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et al. 2019), being transported towards the Patos Lagoon during SW winds, and towards
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Uruguay during NE winds (Fig. 4). Recirculation cells are evident throughout the
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lagoon mainly during NE wind, which is actually the predominant wind direction over
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the region. In addition, the relative distribution of current direction and intensity over
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one year is shown in the directional roses, which were derived from three transects
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depicted on the maps (Fig. 4). According to the annual mean current velocity/direction
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frequency distribution, it was possible to divide the lagoon into three main
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hydrodynamic areas (Fig. 4): the extreme north, where northeastern current velocities
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reaching 0.35-0,40 m s-1 are predominant, flowing towards the Patos Lagoon; the
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central area, where current velocities between 0.05-0.1 m s-1 are predominant, and
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although the mean flux is towards the Patos Lagoon, a broad direction spectrum was
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observed; and the extreme south, where the number of recirculation cells is more
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significant, resulting in high current direction variability, mainly ranging from 0.1–0.15
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m s-1. Although the wind action promotes water level slopes between the lagoon
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extremities (Olivera et al., 2015; Costi et al., 2018; Olivera et al., 2019), and creates and
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shapes recirculation cells, it does not change the orientation of the flow direction
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towards the Patos Lagoon, even under northern wind conditions (Costi et al., 2018;
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Oliveira et al., 2019, Vieira da Silva et al., 2019) (Fig. 4). In this context, the flow
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orientation can be only reversed during extremely low water level inside the Mirim
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Lagoon, but even under such conditions, the Patos Lagoon salt wedge does not intrude
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Journal Pre-proof into the Mirim Lagoon due to the presence of the São Gonçalo Channel dam (Gouvea et
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al., 2010) (Fig. 1). Historical data and associated modelling results indicate that the
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Mirim Lagoon maximum surface current velocity is attained at the São Gonçalo
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Channel, usually ranging from 0.2 to 0.5 m s-1 under high water discharge conditions
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(Fig. 4). Under the dominance of strong SW winds, the highest surface current velocity
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within the system can achieve values of 0.6 m s-1 (Comissão da Lagoa Mirim - CLM,
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1970). Such wind conditions and current velocity, combined with the occurrence of
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shallow water areas, promote the occurrence of sand spits and the relatively flat bottom
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topography (Oliveira et al., 2015).
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Discussion
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The Patos-Mirim system is a highly turbid environment fed by several turbid large
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rivers, which total supply of fine suspended sediments is 5.1 x 106 ton yr-1 to the Patos
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Lagoon (Jung et al., submitted) from which the Mirim Lagoon accounts for 1.8 x 106
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ton yr -1 (Jung et al., submitted). The final fate of the fine suspended material is the
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lagoon system in the first place, and the inner continental shelf secondarily (Calliari et
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al., 2009, Marques et al., 2009; Vinzon et al., 2009). In the case of the Patos Lagoon
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there is evidence from the morphodynamics, composition and distribution of the surface
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sediment bed (Toldo, 1991, 1994; Toldo et al., 2000; Calliari et al., 2009; Lisboa et al.,
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2015) but in the case of the Mirim Lagoon, there is comparatively an important lack of
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information.
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The surface sediment composition and distribution of Mirim Lagoon consists of
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an outer littoral zone dominated by sandy sediments. However, the composition and
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origin of such sandy facies within the west and east littoral, is different. The sand-
Journal Pre-proof source of the east littoral comes from reworked material of the sand barrier formed
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during the Pleistocene and consists, therefore, of well sorted sand with very reduced silt
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content (Vieira, 1995). The sand on the west littoral is supplied by large turbid rivers
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(i.e., Jaguarão, Taquarí and Cebollatí Rivers) and inundated areas (Oliveira et al., 2015:
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Costi et al., 2018) and therefore, such sandy facies is poorly selected as it contains silt
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and clay fractions (Vieira, 1995). The perimeter boundary of this external sandy facies
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can be set on the 5 to 6 m isobath (see comparison between morphometry and
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sedimentary facies, Fig. 2) and it is distributed parallel to the maximum-length axis of
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the system. The surface current velocity at the marginal areas displays medium/low
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values (i.e., 0.25 m s-1) at both margins of the lagoon, flowing parallel to the coast either
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under NE or SW wind dominance.
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The combination of such morphometric and hydrodynamic conditions within the
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west margin is likely to promote fine sediment resuspension rather than deposition. On
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the east margin, however, this superficial facies exhibits the lowest relative abundance
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of fine sediment particles (i.e., clayey) as the dominant fraction is well sorted sand.
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Thus, in this region currents are likely to resuspend sand. In this sense, the littoral
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surface sediment composition is modulated by the relationship between depth and
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current velocity/direction, mainly parallel to the maximum length axis, under either NE
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or SW wind directions (Fig. 4). Similar environmental conditions for resuspension have
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been observed in this shallow system (Toldo, 1994; Cózar et al., 2005) and in other
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regions of the world (Naya et al., 2004).
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315 316
The sedimentary facies lying below the 6 m isobath, is mostly dominated by
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clayey-silty sediments, except for the constricted narrowest part of the central section
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(as depicted in Fig. 4), where the maximum current velocity (under SW winds) is
Journal Pre-proof observed (i.e., 0.35 to 0.4 m s -1). Hence, under such conditions of wind dominance and
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high surface current velocities, resuspension is expected to be dominant, as inferred
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from the dominance of sandy sediments. Therefore, the most abundant sediment
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fraction is fine sand, and the associated inferred sedimentary facies is silty-sand and
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sandy-silt (see Figs. 2 and 3). A similar distribution pattern has been inferred for the
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Patos Lagoon by Toldo (1994), who identified a littoral zone dominated by sandy
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sediments, and an internal central zone dominated by fine sediments. The surface
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current velocity sharply decreases towards the thickened section of the central zone
327
(Fig. 4), as the lagoon width increases from about 20 km to 40 km. Because of such an
328
increase in lagoon width, together with the decreased current velocity, calm water
329
conditions are promoted in this region, and thus, the finest sediment fraction is
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deposited below the 6 m isobath. Likewise, the extreme south region (as shown in Fig,
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4) also displays relatively low surface water velocity, and for the same reason as
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explained above, the finest sediment fraction is deposited below the 6 m isobath and the
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associated inferred sedimentary facies is silty-sand and sandy-silt.
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the river discharge presents an intra-seasonal to annual timescales variability
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(Costi et al., 2018; Vieira da Silva et al., 2019), and the associated mean residence time
337
is 180 days, although the northern (350 days) and southern (100 days) section exhibit
338
remarkably different residence times (Vieira da Silva et al., 2019). Such a residence
339
time is important in regulating the source-to-sink process is very involved in the
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formation of the recent sedimentary bed containing a high-resolution record of the
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contemporary human impacts from river dams, agriculture, milk industry, mining and
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forestry activities. Therefore, this sedimentary facies, distributed in the central region of
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the lagoon below the 6 m isobath appears to represent an excellent source of
344
paleolimnological information.
345 346
Concluding remarks
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The sediment bed composition of Mirim Lagoon is a consequence of the water
349
circulation regime evolved from predominant wind exposure, which generates a littoral
350
resuspension zone dominated by sand, and a central deposition zone dominated by silt.
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The inferred sedimentary facies from both resuspension and deposition zones are set
352
parallel to the maximum length axis of the lagoon and they are distributed in relation to
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the bathymetric features.
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Acknowledgements
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This paper is dedicated to the memory of H.M. Vieira who devoted her
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professional life to sedimentological research in Rio Grande, Brazil. Thanks to FINEP
359
for
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01.11.0141.01) and REHMANSA (grant 01.12.0064.00), and to CNPq for the research
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grants 551436/2011-5 (EHF), 308274/2011-3 (EHF), and 302231/2010–2 (OOM).
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Jasper Knight and an anonymous reviewer provided helpful comments that improved
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this paper.
sponsoring
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Figure captions
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Fig. 1. Upper left panel: regional extension of the Patos-Mirim system. Central panel:
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The Mirim Lagoon catchment area and main large inflowing rivers. Lower left panel:
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general geological setting according to Dillemburg et al. (2017).
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Fig. 2. Surface sediment sampling stations, morphometry and surface sedimentary
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facies of Mirim Lagoon.
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Fig. 3. Surface sediment composition expressed as Mz Wenworth size classes sand
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percentage of sand, silt and clay. The associated sedimentary facies are shown in Fig. 2.
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Fig. 4. Calculated surface current velocity vectors at different Mirim Lagoon regions
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for the maximum southwestern wind (left panels) and maximum northeastern wind
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(right panels) observed during a one year simulation period. Center panels: monthly
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frequency distribution of surface currents for extreme north (transect T1), central
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(transect T2), and extreme south (transect T3) regions.Modified from Oliveira et al.
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(2019).
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Journal Pre-proof Highlights Large shallow coastal turbid system driven by wind. Current direction and speed modulate resuspension and deposition processes. Below/above the 6 m isobath, sediment deposition/resuspension were inferred. Deposition/resuspension zone dominated by clay/sand.
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Hydrodynamics + morphometry = sediment composition/distribution
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Figure 1
Figure 2
Figure 3
Figure 4