Hostname: page-component-586b7cd67f-t7fkt Total loading time: 0 Render date: 2024-11-22T04:26:45.281Z Has data issue: false hasContentIssue false

Late Holocene coastal dynamics south of the Chanthaburi estuary, eastern Gulf of Thailand

Published online by Cambridge University Press:  27 July 2023

Armelle Ballian
Affiliation:
Institute of Earth and Environmental Sciences, University of Freiburg, 79104 Freiburg, Germany Senckenberg Biodiversity and Climate Research Centre, 60325 Frankfurt am Main, Germany
Sakonvan Chawchai*
Affiliation:
Past and Present Climate Towards the Future (PPCTF) Research Unit, Department of Geology, The Faculty of Science, Chulalongkorn University, Bangkok, 10330 Thailand
Johannes M. Miocic*
Affiliation:
Institute of Earth and Environmental Sciences, University of Freiburg, 79104 Freiburg, Germany Energy and Sustainability Research Institute Groningen, University of Groningen, 9747 AG Groningen, The Netherlands
Warinyupa Charoenchatree
Affiliation:
Past and Present Climate Towards the Future (PPCTF) Research Unit, Department of Geology, The Faculty of Science, Chulalongkorn University, Bangkok, 10330 Thailand
Raphael Bissen
Affiliation:
Department of Mining and Petroleum Engineering, Faculty of Engineering, Chulalongkorn University, Bangkok, 10330 Thailand
Frank Preusser
Affiliation:
Institute of Earth and Environmental Sciences, University of Freiburg, 79104 Freiburg, Germany
*
Corresponding authors: S. Chawchai; Email: [email protected]; J.M. Miocic; Email: [email protected]
Corresponding authors: S. Chawchai; Email: [email protected]; J.M. Miocic; Email: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Beach ridges are depositional features that allow reconstruction of past sea-level variations, sediment dynamics, and storm activity. However, there are still very few systematic studies focusing on beach ridges available from the Gulf of Thailand. Along the east coast, satellite images provide evidence of beach ridges in the Chanthaburi Province, extending as far as 6 km inland, oriented parallel to the current coastline. These can be divided into a set of landward ridges (5.3–6.0 km inland) and seaward ridges (0.4–1.8 km inland) that are separated by an arm of the Chanthaburi estuary. Optically stimulated luminescence dating of 26 sand samples from 12 pits of ridge profiles suggests that the landward set of beach ridges formed ca. 3500 yr ago, while the seaward set of ridges formed between ca. 2100–1200 years ago, which also includes the modern active beach. It appears that the landward set of beach ridges developed during a period of relatively stable sea level followed by a rapid regression presently occupied by the arm of the Chanthaburi estuary. The seaward set of beach ridges apparently reflects a millennium of slowly retreating coastline until the modern beach ridge formed.

Type
Thematic Set: Asian Climate
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © The Author(s), 2023. Published by Cambridge University Press

INTRODUCTION

Deciphering the response of coastal clastic sedimentary systems to past sea-level changes is important to understanding the potential impact of future developments on these often densely populated areas (e.g., FitzGerald et al., Reference FitzGerald, Fenster, Argow and Buynevich2008). Sea-level history in coastal settings can be deciphered using a number of proxies (e.g., Lewis et al., Reference Lewis, Sloss, Murray-Wallace, Woodroofe and Smithers2013), with beach ridge sequences enabling the tracking of sea-level change during post–highstand regression (e.g., Otvos, Reference Otvos2000; Tamura et al., Reference Tamura, Saito, Bateman, Nguyen, Ta and Matsumoto2012). Hence, beach ridge systems, characterised by parallel to subparallel ridges and swale topography, are prominent features reflecting longer periods of costal development. While there has been discussion since Davies (Reference Davies1957) regarding the exact processes that lead to the formation of beach ridges (cf. Tamura, Reference Tamura2012; Kelsey, Reference Kelsey, Shennan, Long and Horton2015; Oliver et al., Reference Oliver, Thom and Woodroffe2017), it is agreed that ridge formation is mainly influenced by changes in sea level, local wave/tide conditions, storminess, gradient, and the degree of sediment supply. Commonly, it is expected that relative sea level (RSL) rise will erode and move beach ridges towards a more landward equilibrium position, whereas beach ridge plains prograde seaward during sea-level fall (Hansom, Reference Hansom2001; Plater and Kirby, Reference Plater, Kirby, Flemming and Hansom2011). However, the exact controlling factors, mechanisms, and timing remain poorly understood (e.g., Tamura, Reference Tamura2012).

A key method to quantify process rates is determining the age of coastal features, using radiocarbon dating and/or optically stimulated luminescence (OSL) dating (e.g., Jacobs, Reference Jacobs2008). Applying different combinations of geomorphic analyses, geophysical surveying, sedimentary investigations, and geochronological approaches and identifying sea-level indicators have been used to reconstruct long-term coastal dynamics in numerous case studies. However, these concentrate on the midlatitudes, in particular along the sandy coasts of Australia (e.g., Short and Hesp, Reference Short and Hesp1982; Oliver et al., Reference Oliver, Dougherty, Gliganic and Woodroffe2015), North America (e.g., Mallinson et al., Reference Mallinson, Burdette, Mahan and Brook2008; Shawler et al., Reference Shawler, Hein, Obara, Robbins, Huot and Fenster2021), and Europe (e.g., Faye et al. Reference Faye, Eynaud, Bosq, Lambert, Verdin, Vequaud and Lodyga2019; Nielsen et al. Reference Nielsen, Murray, Pejrup and Elberling2006). In contrast, the number of comprehensive and systematic studies using a combination of at least several of the abovementioned methods in Southeast (SE) Asia is still rather low (e.g., Hanebuth et al., Reference Hanebuth, Voris, Yokoyama, Saito and Okuno2011; Mallinson et al., Reference Mallinson, Culver, Reide Corbett, Parham, Shazili and Yaaco2014; Brill et al., Reference Brill, Jankaew and Brückner2015; Gouramanis et al., Reference Gouramanis, Switzer, Bristow, Pham, Mauz, Hoang and Lam2020; Kongsen et al., Reference Kongsen, Phantuwongraj, Choowong, Chawchai, Udomsak, Chansom, Ketthon, Surakiatchai, Miocic and Preusser2022). In particular, age control of deposition is often limited to a rather low number of radiocarbon and/or OSL samples.

Presented here is a study of coastal features along the southern edge of the Chanthaburi estuary, located ca. 245 km southeast of Bangkok (Fig. 1), aimed at identifying the timing and discussing potential processes that shaped the present coastal landscape. To do so, we first apply a combination of geomorphologic mapping of ridges found parallel to the coast and then investigate sedimentary features in trenches hand-dug into the ridges to identify the local facies. A major focus is on establishing reliable age constraints of coastal evolution by using OSL dating on samples taken from the trenches. The results will be used to reconstruct the Late Holocene history of the coast strip and discuss it in a regional context.

Figure 1. (A) Geomorphologic and geologic map of the Chanthaburi area, eastern Gulf of Thailand (study area indicated by the red rectangle). Inset: location of the study area in the Gulf of Thailand (DMR, 2007, 2001). (B) Satellite imagery of the study area and (C) beach ridges studied indicated on the TanDEM-X digital surface model.

REGIONAL SETTING

Past and modern sea-level change in SE Asia

The Gulf of Thailand is located on the continental shelf of the South China Sea and is divided into eastern, upper, and western parts (Fig. 1). In this region, sea level may rise as much as 60 cm until the end of the twenty-first century (Oppenheimer et al., Reference Oppenheimer, Glavovic, Hinkel, van de Wal, Magnan, Abd-Elgawad, Cai, Pörtner, Roberts, Masson-Delmotte, Zhai, Tignor, Poloczanska and Mintenbeck2019), depending on the global warming scenario used for simulations (Jaroenongard et al., Reference Jaroenongard, Babel, Shrestha, Weesakul, Nitivattananon and Khadka2021). Such predictions are supported by tide gauge data (Sojisuporn et al., Reference Sojisuporn, Sangmanee and Wattayakorn2013) revealing a sea-level increase of about 5 mm/yr for the period AD 1985–AD 2009, in a similar range as altimetry measurements (Trisirisatayawong et al., Reference Trisirisatayawong, Naeije, Simons and Fenoglio-Marc2011). For the Sunda Shelf somewhat farther south, Culver et al. (Reference Culver, Leorri, Mallinson, Reide Corbett and Shazili2015) reconstruct an increase in the rate of sea-level rise from 1.26 mm/yr for the period AD 1820–AD 1900 using radiocarbon dates of peat to about of 3.2 ± 0.6 mm/yr for the last 120 yr based on foraminiferal data. This highlights the need to understand the timing of coastal sedimentary processes in the region in the light of future sea-level rise.

On Holocene time scales, RSL changes in SE Asia resulted from a combination of eustatic, isostatic, and local factors such as human-induced subsidence and sediment supply (e.g., Kengkoom, Reference Kengkoom1992; Sinsakul, Reference Sinsakul1992; Tjia, Reference Tjia1996; Scoffin and Le Tissier, Reference Scoffin and Le Tissier1998; Horton et al., Reference Horton, Gibbard, Mine, Morley, Purintavaragul and Stargardt2005; Oliver and Terry, Reference Oliver and Terry2019; Durand et al., Reference Durand, van den Broeke, Le Cozannet, Edwards, Holland, Jourdain and Marzeion2022). For example, a Holocene maximum of +2.6 m at ca. 5.7 ka was inferred based on oyster and coral data from Phang-nga Bay and Phuket, whereas ridge crests and swale bases in the northwest of the Andaman Sea coast (Phuket) point to maximum heights of +1.5–2.0 m above present sea level around 5.3 ka (Scheffers et al., Reference Scheffers, Brill, Kelletat, Brückner, Scheffers and Fox2012). According to this study, RSL in the region did not exceed +1.5 m during the last 3000 yr. Mann et al. (Reference Mann, Bender, Lorscheid, Stocchi, Vacchi, Switzer and Rovere2019) provide a standardized Holocene RSL database for SE Asia, the Maldives, India, and Sri Lanka. Overall, geomorphic evidence reveals a rise of RSL from below −30 m during the Early Holocene (12–8 ka) reaching a higher than present RSL between 6 ka and 4 ka, with amplitudes between 2 and 5 m above mean sea level. After 4 ka, RSL has been falling and likely reached the present height during the past two millennia (Mann et al., Reference Mann, Bender, Lorscheid, Stocchi, Vacchi, Switzer and Rovere2019). Interestingly, Mann et al. (Reference Mann, Bender, Lorscheid, Stocchi, Vacchi, Switzer and Rovere2019) combine evidence from the northern Gulf of Thailand with the South China Sea, in particular the Mekong Delta, and observe an ambiguous age-elevation of RSL change in the available data. It should be noted that Mann et al. (Reference Mann, Bender, Lorscheid, Stocchi, Vacchi, Switzer and Rovere2019) rely on and critically access rather old data from the northern Gulf of Thailand (Somboon, Reference Somboon1988; Somboon and Thiramongkol, Reference Somboon and Thiramongkol1992) that were published with very limited information with regard to exact sample location and no information regarding dating procedures. Nimnate et al. (Reference Nimnate, Chutakositkanon, Choowong, Pailoplee and Phantuwongraj2015) discuss several sea-level reconstruction curves stretching from Singapore to the northern Gulf of Thailand, revealing large differences in the peak and shape of Holocene sea-level rise and fall (Sinsakul et al., Reference Sinsakul, Sonsuk and Hasting1985; Hesp et al., Reference Hesp, Hung, Hilton, Ming and Turner1998; Choowong Reference Choowong2002a; Horton et al., Reference Horton, Gibbard, Mine, Morley, Purintavaragul and Stargardt2005). These authors also present a revised sea-level curve based on OSL data from beach ridges at Chumphon, Gulf of Thailand that implies a maximum RSL of more than 4 m around 7–6 ka, followed by a gradual decrease and reaching the present level after 2 ka. However, the elevation data of Nimnate et al. (Reference Nimnate, Chutakositkanon, Choowong, Pailoplee and Phantuwongraj2015) might be inaccurate and overestimated (Choowong, M., personal communication, 2023). Surakiatchai et al. (Reference Surakiatchai, Songsangworn, Pailoplee, Choowong, Phantuwongraj, Chabangborn and Charusiri2019) revise the sea-level curve from the Prachuap Khiri Khan beach ridge plain and find good agreement with the ICE-5 G sea-level model (Peltier, Reference Peltier2004), with a peak sea-level elevation of ca. +3 m between ca. 8 and 7 ka.

Study area

The study area is located within the Laem Sing District, Chanthaburi Province, in the coastal area south of the Chanthaburi estuary (Fig. 1). A similar setting is found ca. 30 km southeast, along the Welu estuary (Chataro et al., Reference Chataro, Choowong and Phantuwongraj2022). Based on the geomorphologic and geologic maps from the Department of Mineral Resources of Thailand (DMR 2001, 2007), the research area features beach ridges, tidal flats, fluvial deposits, terrace deposits, colluvial deposits, sedimentary rocks, plutonic rocks, and volcanic rocks (Fig. 1). Granitic rocks are widely distributed in Thailand and occur in eastern, central, and western granite belts (Charusiri et al., Reference Charusiri, Clark, Farrar, Archibald and Charusiri1993), with the Chanthaburi granitic rock being a coarse-grained biotite granite (Uchida et al., Reference Uchida, Nagano, Niki, Yonezu, Saitoh, Shin and Hirata2022). Along with the granitic rocks, Carboniferous–Triassic shallow- to deep-marine sedimentary rocks and Quaternary alluvium are widely dispersed in the study area (Sone et al., Reference Sone, Metcalfe and Chaodumrong2012). Neogene to Quaternary intraplate basalt occurs locally (Fig.1).

The geologic setting results from the fact that Thailand underwent extensive deformation during the late Mesozoic/early Cenozoic due to the collision of the Indian and Eurasian terranes. This was associated with sinistral strike-slip faults also common within the Sa Kaeo–Chanthaburi Zone, representing the likely origin of NW-SE trending geologic structures (Sone et al., Reference Sone, Metcalfe and Chaodumrong2012; Hara et al., Reference Hara, Tokiwa, Kurihara, Charoentitirat, Ngamnithiporn, Visetnat, Tominaga, Kamata and Ueno2018). In the eastern Gulf of Thailand, rifting began in the Eocene and ended at the Oligocene–Miocene boundary (Phoosongsee and Morely, Reference Phoosongsee and Morely2019). Since the late Miocene, the coastal area of the eastern Gulf of Thailand is considered tectonically stable (Choowong, Reference Choowong2002a), and no seismic risk is expected for this region (Pailoplee and Choowong, Reference Pailoplee and Choowong2013; Pailoplee and Charusiri, Reference Pailoplee and Charusiri2017), indicating the lack of active tectonics.

The coastal regions of the northern Gulf of Thailand have kept a record of their evolution, particularly in relation to how they responded to the sea-level changes during the Holocene. A first framework combining geomorphic evidence and sedimentary facies evolution was presented by Choowong (Reference Choowong2002b) and later refined using both radiocarbon and OSL dating (e.g., Nimnate et al., Reference Nimnate, Chutakositkanon, Choowong, Pailoplee and Phantuwongraj2015; Surakiatchai et al., Reference Surakiatchai, Choowong, Charusiri, Charoentitirat, Chawchai, Pailoplee and Chabangborn2018, 2019; Chataro et al., Reference Chataro, Choowong and Phantuwongraj2022; Miocic et al., Reference Miocic, Sah, Chawchai, Surakiatchai, Choowong and Preusser2022). In the eastern Gulf of Thailand, several tide-dominated estuaries populate the coastline; they are located in sheltered areas between protruding headlands, protected from high wave energy (Choowong, Reference Choowong2002a). Minor sea-level fluctuations during the postglacial marine transgression that caused the rapid flooding of the Sunda Shelf (Hanebuth et al., Reference Hanebuth, Stattegger and Grootes2000) affected the evolution of the sedimentary sequences (transgressive, aggregational, and progradational or regressive facies) and continued to develop until the Late Holocene (Choowong, Reference Choowong2002a, Reference Choowong2002b).

The lower part of Laem Sing District is characterized by coastal plains interspersed with hills and tidal flats. Chanthaburi Province has the largest mangrove areas in eastern Thailand, occupying ca. 60% of the coastal plain. Mangrove forests are located in sheltered coastline and inland areas, along the banks of rivers and streams (Suk-ueng et al., Reference Suk-ueng, Buranapratheprat, Gunbua and Leadprathom2013). The Chanthaburi and Welu are the two major rivers in the Chanthaburi and Trat Provinces, respectively.

The Chanthaburi River (approximately 120 km long) originates in the northern mountains (Khao Ploi Waen, basalt, granitic basement), flows through Chanthaburi city, and finally empties into the Gulf of Thailand in the Laem Sing District. For the research area, there are no statistics on annual runoff or sediment discharge available. However, the runoff of the Chanthaburi River is substantially less than that of the Welu River (Chen et al., Reference Chen, Qi, Intasen, Kanchanapant, Wang and Zhang2020). Because of its narrower channel, the Chanthaburi estuary is less vulnerable to seawater intrusion than the Welu estuary, which is invaded by salt water during high tide (Chen et al., Reference Chen, Qi, Intasen, Kanchanapant, Wang and Zhang2020).

Sediments at the mouths of the Chanthaburi estuary and the Welu estuary fluctuate under the influence of tidal currents and are considered strongly hydrodynamic (Wang et al., Reference Wang, Chen, Qi, Intasen and Kanchanapant2020), with the areas of highest sand content found in the southwestern Chanthaburi estuary. The Chanthaburi estuary also has a more complicated sand volume fraction than the Welu estuary, as the sand content at the mouth is higher and shows an outward extension with a gradual reduction in sand content (Wang et al., Reference Wang, Chen, Qi, Intasen and Kanchanapant2020). The sand volume fraction gradually decreases with distance offshore under the influence of the tidal current. The tides in the study area are diurnal, with an average tidal range of 0.8–1.2 m (Chen et al., Reference Chen, Qi, Intasen, Kanchanapant, Wang and Zhang2020; Trisirisatayawong et al., Reference Trisirisatayawong, Naeije, Simons and Fenoglio-Marc2011).

The Indian summer monsoon (SW monsoon) and the northeast winter monsoon (NE monsoon) define the present-day climate in the region. Thus, seasonal variations in the dominant wind directions have a significant impact on wind-driven currents in the Gulf of Thailand. In the summer, during the SW monsoon, currents flow in a clockwise direction (Fig. 1). While the currents remain generally clockwise during the NE monsoon, they are counterclockwise in the eastern part of the gulf (Chen et al., Reference Chen, Qi, Intasen, Kanchanapant, Wang and Zhang2020; Liu et al., Reference Liu, Shi, Yang, Khokiattiwong and Kornkanitnan2016; Wang et al., Reference Wang, Chen, Qi, Intasen and Kanchanapant2020). During the winter, a westward-directed current flows along the coast of the study area; tides are diurnal, with an average tidal range of 0.8–1.2 m (Chen et al., Reference Chen, Qi, Intasen, Kanchanapant, Wang and Zhang2020; Trisirisatayawong et al., Reference Trisirisatayawong, Naeije, Simons and Fenoglio-Marc2011).

During the summer season, as a result of overheating, low-pressure weather systems form in the tropics; these cyclones generally move from east to west. Due to its location, the Gulf of Thailand is exposed to such tropical storms, but the most and the strongest of those hit the eastern coast of the Thai-Malay Peninsula, mainly between 8°N and 12°N (Terry et al., Reference Terry, Goff and Jankaew2018). During the period 1952–2020, a total of 36 tropical cyclones passing the Gulf of Thailand also affected eastern Thailand, mainly during September and October (Thai Meteorological Department, 2020; Supplementary Table S1). However, only nine of those had a substantial impact on the Chanthaburi coast, namely those occurring in July 1951 and in the October of the years 1952 (twice), 1957, 1959, 1960, 1974, 1985, and 1992 (Thai Meteorological Department, 2020).

METHODS

Geomorphology

Satellite images, digital elevation models (DEMs; TanDEM-X with 12 m horizontal and <1 m vertical resolution), and a geomorphologic map (DMR, 2001) were used to classify landforms in the study area and identify suitable sampling locations. Twelve locations along two transects perpendicular to the recent shoreline were selected for field observations (Fig. 2). During site selection, special focus was put on areas with limited or no visible human impact. Following hand auger probing, small trenches with a depth of 1.0–1.5 m were excavated at each location, with the groundwater table limiting the depth of the trenches. Pürckhauer probing allowed for sedimentologic observations beneath the ground water table. The clean trench walls were photographed and logged, and the exact location of each trench was determined using differential GPS (dGPS; ±5 cm in height). To confirm field estimates, 22 samples were taken from areas of interest for sedimentologic analyses (grain-size analysis, organic and carbonate content). The profile illustrated in Figure 2 is based on a combination of remote sensing data and field data (TanDEM-X, dGPS, geomorphologic observations).

Figure 2. (A) Cross section through the studied beach ridges along the line indicated in B. (B) Simplified geomorphologic map of the study area showing the sampling locations.

Sedimentology

Sedimentologic samples were homogenized and dried at 105°C for 24 h. Organic matter and carbonate content of the samples were analysed by loss on ignition (LOI; Heiri et al., Reference Heiri, Lotter and Lemcke2001; Santisteban et al., Reference Santisteban, Mediavilla, López-Pamo, Dabrio, Blanca Ruiz Zapata, José Gil García, Castaño and Martínez-Alfaro2004) using a muffle furnace with temperatures of 550°C for 3 h for organic matter and 950°C for 2 h for carbonate content. For laser-optical grain-size analysis, the fraction >2 mm (if present) was removed by sieving, and the remaining material was pretreated with 20% H2O2 at 70°C for organic matter degradation. As the detrital grains partly consist of carbonate fragments, the samples were not treated with HCl before grain-size analysis. The samples were then treated with a dispersant (Calgon, a solution of 33 g sodium-hexametaphosphate, and 7 g sodium carbonate) for 24 h (Abdulkarim et al., Reference Abdulkarim, Grema, Adamu, Mueller, Schulz, Ulbrich, Miocic and Preusser2021) before grain-size distribution was analysed with a Malvern Mastersizer 3000. Grain-size data were analysed using GRADISTAT (Blott and Pye, Reference Blott and Pye2001) (Supplementary Table S2).

Luminescence dating

For OSL dating, 26 samples were collected by forcing a 10-cm-diameter iron cylinder horizontally into the cleaned section at depths of more than 40 cm to avoid potential bioturbation. To avoid depleting the OSL signal, samples were taken without exposure to daylight. Samples were therefore immediately packed from the cylinder into opaque plastic bags. Thereafter, additional sediment was collected in a 30 cm radius around the OSL sample for dose-rate determination. The initial part of the sample preparation work was done at the red-light laboratory at Chulalongkorn University, Bangkok. First, the water content was measured, and samples were subsequently dry sieved (105–177 μm); this was followed by removal of carbonate and organic material using HCl and H2O2, respectively. Heavy minerals were removed using a magnetic separator. The samples were then transferred to the University of Freiburg, where they were etched using 40% hydrofluoric acid for 1 h to remove the outer layer of the mineral surface that is affected by alpha radiation. Dried grains were mounted on stainless steel discs using a 2 mm stamp of silicon oil (ca. 50 grains per aliquot).

Luminescence measurements were performed on an automated TL/OSL-DA-15 Risø reader fitted with a bialkali EMI photomultiplier. The 90Sr/90Y beta source of the reader was calibrated using LexCal2014 calibration quartz (90–160 μm; 3 Gy administered dose) to ca. 0.11 Gy/s. Equivalent dose (De) measurements were carried out using a modified version of the single-aliquot regenerative-dose protocol (SAR) of Murray and Wintle (Reference Murray and Wintle2000), with preheating at 230°C for 10 s before all optical stimulation, as identified appropriate in performance tests (dose recovery, thermal transfer, preheat plateau). Most of the samples show bright OSL signals and an excellent response during the SAR protocol (Supplementary Fig. S1). Twenty-four replicate measurements were considered sufficient for most samples. However, for six of the very young samples (less than 100 yr old) the number of replicate measurements was increased to 30. For several samples, some aliquots had to be rejected due to poor quartz luminescence sensitivity or not passing the SAR quality criteria (recycling ratio within 10% of unity, test dose error <10%). De calculation was conducted based on either the central age model (CAM) or the minimum age model (logged MAM-3; Galbraith et al., Reference Galbraith, Roberts, Laslett, Yoshida and Olley1999). The determination of the appropriate age model was based on the shape of the De distribution and the observed overdispersion. A sigma_b value of 0.10 was used in the MAM calculations.

The determination of the concentration dose-rate relevant elements (K, Th, U) was carried out at VKTA (Radiation Protection, Analytics & Disposal Rossendorf Inc.) in Dresden, using high-resolution gamma spectrometry (cf. Preusser and Kasper, Reference Preusser and Kasper2001). No evidence for radioactive disequilibrium in the uranium decay chain was observed. Dose rates and ages were calculated using the software ADELE v. 2017 (Degering and Degering, Reference Degering and Degering2020; www.add-ideas.de). Cosmic-ray dose rates were corrected for geographic position and burial depth after Prescott and Hutton (Reference Prescott and Hutton1994). All luminescence data are summarised in Supplementary Table S3. Mean ages used in the discussion are based on the CAM of OSL individual ages, as this approach represents a geometric mean and includes the individual uncertainties in the calculations.

RESULTS

Geomorphology

Based on geomorphologic analysis of remote sensing data, two series of former beach ridges were recognized in the study area (Fig. 2). This comprises a series of four closely spaced ridges (A–D) near the shore of Leam Sing beach, and a second set including two main ridges (E and F) and a nonprominent subridge, also closely spaced, several kilometres farther inland. All ridges reach a height of about 1–2 m above the neighbouring plain, which is about 0.5 m above present-day sea level. While ridges were to some extent modified by human activity, their individual overall morphology and dimension are still clearly identifiable on satellite images. Furthermore, from field observations, it is concluded that human modifications appear rather limited and will not have significantly disturbed the overall geomorphic setting.

Beach ridge A, located at the shore of the Gulf of Thailand, is the longest, with a length of about 7 km and a width ranging from 115 to 280 m. Farther inland, the widest ridge, B (5.1 km long and up to 350 m wide), is easily identified by a road being constructed on its crest. The following ridge, C, is less elongated (2.4 km long) but has about the same width. Ridge D is slightly longer (2.8 km) but with a smaller width (175 m) and a more convex shape. The second set of ridges is separated from the first by a 3.5-km-wide estuary channel system and contiguous low-lying areas. The seaward-facing ridge of this set, ridge E, has a length of 3 km and a width of 195 m. The most landward ridge of the study area (ridge F) has a length of 1.9 km and width of up to 190 m.

Sedimentology

The ridges are composed of sand beds with the thicknesses of individual beds ranging from 5 to 70 cm, which overlie finer-grained sediments (Fig. 2). The overall thickness of the individual sand ridges ranges from 0.75 m to more than 2 m. The sand beds contain predominantly fine to medium, poorly to moderately sorted sand with a low organic content (<1.6%). Carbonate content is generally low (< 2%); however, coarse, bioclast-rich layers are common. Bedding structures are generally only visible due to grain-size changes, while internal structures in individual sand beds are usually not visible in the pits. Detailed sedimentologic descriptions of all pits, as well as images, are found in the Supplementary Material. Generally, the topmost 10–20 cm of each sedimentary sequence is organic rich and shows clear signs of soil formation. The underlying sands are featureless, grey to dark grey. In all locations, the colour changes to orange reddish with depth, indicating an oxidizing environment.

The following summary of sedimentologic observations will concentrate on the main transect of the study. At the recent beach ridge, A, the foreshore (A1; Supplementary Fig. S3) shows structureless sands with a thickness of at least 1.1 m. At the backshore (A2; Supplementary Fig. S4), sedimentary structures are well preserved, featuring erosional unconformities at the base of cross-bedded, poorly to moderately sorted, bioclast-rich, medium to coarse sand beds. Interbedded with these beds are moderately to well-sorted, laminated fine sands. At ridge B (Supplementary Fig. S5), poorly sorted sands have a thickness of at least 0.6 m, while the seaward side of ridge C (C2; Supplementary Fig. S6) consists of poorly to moderately sorted, featureless, fine to medium sands with an overall thickness of at least 1.35 m. At the base of the pit, one bioclast-rich layer occurs. Landward (C3; Supplementary Fig. S7), the sands have an overall thickness of ~0.8 m, and the underlying clayey silts and clays feature interbedded coarser, bioclast-rich layers. On the seaward side, Ridge D (D2; Supplementary Fig. S8) consists of fine to medium sands that are moderately to poorly sorted and are at least 1.3 m thick. One bioclast-rich layer is present and fining upward trends within laminae are observed. On the landward side (D3; Supplementary Fig. S9), stacked fine to medium sands up to 1.15 m depth are present, with dark grey clays beneath, with several interbedded, poorly sorted, bioclast-rich sandy layers.

The upper ca. 1 m of the inland ridges (E and F) are composed of fine to medium, moderately to poorly sorted, partly silty sand. On the seaward side of ridge E (E2; Supplementary Fig. S10) the sands are at least 2.2 m thick, commonly poorly sorted, and silty, with some coarsening upward trends within laminae being visible. No bioclast-rich layers are observed. On the landward side of ridge E (E1; Supplementary Fig. S11), the sand beds have an overall thickness of 1.9 m, and there are at least three ca. 10-cm-thick, poorly sorted, bioclast-rich beds. Below 1.9 m depth, greyish clays dominate, with one poorly sorted, bioclast-rich sandy silt layer occurring at 2.8 m depth. The fine to medium, moderately to poorly sorted sands of ridge F have an overall thickness of at least 0.8 m (F1; Supplementary Fig. S12) and 0.55 m (F2; Supplementary Fig. S13) on the sea- and landward sides, respectively. No bioclast-rich layers are observed in ridge F; however, this could be due to the shallow depth of the pit on the landward side.

LOI-based organic matter content (0.13–1.53%) and carbonate content (0.05–1.89%) of the analysed samples show no consistent trends with respect to sample location (landward vs. seaward side of the ridges) or depth (Supplementary Table S2). Samples with a high organic matter content tend to be shallow and are interpreted to have been subject to soil formation processes, while samples with a high carbonate content visibly contain shell fragments.

Results from the grain-size analysis indicate no obvious trend in the overall distribution of the sediments from ridges A to F. Most of the sediments are moderately to poorly sorted, with sorting ranging mostly from near symmetrical to fine-skewed, as well as ranging widely between mesokurtic and very leptokurtic. However, the distribution of sediments from the most landward ridge (F) differs significantly from the others regarding kurtosis and skewness value variations (Supplementary Fig. S2).

Deposition chronology

OSL ages of samples from the present beach ridge were taken from a structureless forebeach setting (A1) and a well-stratified backshore (A2) section. For both settings, OSL ages in the order of decades have been determined (from bottom to top: A1, 32 ± 3 yr, 43 ± 5 yr, 32 ± 3 yr; A2, 23 ± 2 yr, 31 ± 3 yr, 37 ± 3 yr). While the ages are not strictly consistent within the given 1-sigma uncertainties, it is interesting to note that the De values are similar (Supplementary Table S3). Hence, the slight inconsistencies might rather be related to dose-rate issues, a problem already highlighted and discussed in a similar setting by Miocic et al. (Reference Miocic, Sah, Chawchai, Surakiatchai, Choowong and Preusser2022). Nevertheless, it appears justifiable to infer an age of some 30 yr for the deposits.

The OSL ages determined for the seaward beach ridge complex (B–D) increase landward with no systematic increase of age with depth in the individual profiles. For the most seaward position (B1: ages of 1130 ± 90 yr and 1330 ± 120 yr), this represents a mean age of ca. 1210 ± 70 yr. The next landward position gave ages (C2: 1230 ± 80 yr, 1240 ± 60 yr) very consistent with this estimate, with a mean of 1240 ± 40 yr. However, the landward side of this beach ridge shows higher ages of 1910 ± 160 yr (C1) as well as 1910 ± 120 yr and 1670 ± 120 yr (C3) (mean = 1800 ± 90 yr). This trend continues on the seaward side of the next beach ridge (D2: 2030 ± 100 yr, 2240 ± 160 yr), with a mean of 2100 ± 80 yr. Interestingly, the landward side of this ridge (D3: 1590 ± 70 yr, 1670 ± 120 yr) shows a significantly lower mean age of 1610 ± 60 yr. Striking for this beach ridge is the difference in dose rate, which is just above 0.5 Gy/ka on the seaward side, but around 1 Gy/ka on the landward side. This is caused by a higher concentration of all dose rate– relevant elements (K, U, Th). We speculate that the sediment on the landward side might be less weathered and hence represents a more prominent contribution of fresh material provided by the Chanthaburi River. Therefore, it appears possible that this side of the beach ridge was not overprinted by direct marine processes, but by fluvio-estuarine influence. It might indeed represent a young aggradation of sediment, for example, a reworking by tidal processes on the landward compared with the seaward side. OSL ages determined for D1 (370 ± 60 yr, 1020 ± 120 yr) are inconsistent with all other ages. We later learned that this area might have been subject to land fill operations and hence excluded the results in the “Discussion.”

The OSL ages determined for the landward beach ridge complex (E and F) all overlap within uncertainties, with the exception of sample CHA12Q (4140 ± 210 yr). The results show no correlation with older ages being more landward (Fig. 2) and represent a mean of 3530 ± 70 yr.

DISCUSSION

While the Chanthaburi coastal plain is topographically flat, ridges are clearly visible, with elevations up to 4 m above present mean sea level in the DEM. However, due to limitations in the vertical resolution, the DEM data cannot be used to create a reliable detailed elevation profile across the transect. Note that the ridges have been altered by human activity, as they serve as urban areas, whereas the area between the ridges is commonly used for fish farming. Compared with an earlier mapping of barriers and ridges by Choowong (Reference Choowong2002b), our results seem to be more accurate and detailed, while the general setting and locations are similar. The higher level of detail is explained by the increased quality of the remote sensing data being used. The ridges are interpreted to be beach ridges outlining past shorelines, indicating that five palaeo-shorelines are recorded (ridges B–F) in addition to the recent shoreline (ridge A). Noteworthy is the gap between the two sets of beach ridges, which is currently occupied by one arm of the Chanthaburi estuary.

The analysis of the grain-size distribution parameters and their correlations does not allow identification of any depositional process of the different units (Supplementary Fig. S2). However, grain-size parameters of ridge F, which is located most landward, differ significantly from the other ridges and the sediments are very coarse skewed and very leptokurtic. This implies that sediments of ridge F were deposited under different hydrodynamic conditions than the rest of the ridges.

A general lack of sedimentary structures does not allow for a detailed interpretation of depositional processes; however, the sand beds at the tops of the ridges are interpreted to be the result of wave and aeolian deposition in a beach environment as observed at the currently active beach ridge. The nature of the backshore environment is well documented in the recent beach site, where bioclast-free laminated sands are interbedded with cross-bedded bioclast-rich coarse sands. The laminated sands represent the normal deposition due to wave action in the swash zone and reworking of these deposits by aeolian processes. The poorly sorted bioclast-rich layers in A2 are interpreted to represent a storm event, where material from below the mean fair-weather wave base has been transported to the beach and deposited there. Considering that the coast of Chanthaburi is quite infrequently hit by major storms and given the OSL age of ca. 30 yr, Typhoons Gay (AD 1989) and Linda (AD 1997) are the most plausible candidates. Regarding the latter, a possible slight overestimation of the age due to potential partial bleaching should be considered. The average wave height during Typhoon Linda along the eastern coast of Thailand was about 2.5 m, with a maximum storm surge height of 0.6–1.0 m generated in the upper Gulf of Thailand (Vongvisessomjai, Reference Vongvisessomjai2009). Typhoon Gay, approaching from the South China Sea, generated a maximum wave height of 6–11 m, with storm surge heights that might have reached 2 m height. In the past, storm events with such intensity are evident on the landward side of the ridges, where bioclast-rich, poorly sorted layers are commonly found (ridges C–E). The storms must have had such an intensity that waves swept over the crests of the ridges.

The seaward-facing sections of ridges B–E likely represent the aeolian-wave interaction occurring on the foreshore, as the clear laminations and cross stratifications observed in the recent swash zone deposits are missing. The moderate to poor sorting of these sands excludes pure aeolian processes; however, the lack of frequent storm indicators may highlight that they were deposited higher than the mean storm level on the ridge.

The silty and clayey sediments occurring beneath the sands (ridges C–E) are interpreted to represent tidal flat deposits. Their fine-grained nature is likely linked to the proximity of the Chanthaburi estuary, which delivers fine-grained sediments into the Gulf of Thailand. Coarse-grained, bioclast-rich layers within these sediments are interpreted to be the result of strong storm events.

According to OSL dating, the landward set of beach ridges (E and F) was formed ca. 3500 yr ago, some 6 km inland from the current shoreline at the Chanthaburi estuary. Coastal landforms several kilometres inland with similar OSL ages have been reported from the western Gulf of Thailand, at Sam Roi Yot National Park (ca. 200 km W of the study area; Surakiatchai et al., Reference Surakiatchai, Songsangworn, Pailoplee, Choowong, Phantuwongraj, Chabangborn and Charusiri2019), as well as from the eastern Gulf of Thailand, from sand spits at the Weru estuary (ca. 25 km SE of the study area; Surakiatchai et al., Reference Surakiatchai, Songsangworn, Pailoplee, Choowong, Phantuwongraj, Chabangborn and Charusiri2019), and from the Trat Province (ca. 70 km SE of the study area; Chataro et al., Reference Chataro, Choowong and Phantuwongraj2022). In summary, there is clear evidence for a coastline retreat in several parts of the northern Gulf of Thailand in the past 3500 yr that reaches a distance of several kilometres (Fig. 3A).

Figure 3. Schematic model of the coastal depositional environment evolution of Chanthaburi. (A) Around 3500 yr ago, a high sea-level position causes the development of beach ridges along the shoreline. (B) A substantial drop in sea level between 3500 and 2100 yr ago might be responsible for the lack of beach ridge formation during this time. (C) The seaward set of beach ridges establishes with falling sea level between ca. 2100 and 1200 yr ago and forms the bar-built Chanthaburi estuary. (D) Present-day coastal setting at Chanthaburi.

The most common explanation of widespread coastline retreat is the lowering of the regional sea level. Indeed, sea-level data from SE Asia point towards about 1.5–2.5 m sea-level lowering during this time (Scheffers et al., Reference Scheffers, Brill, Kelletat, Brückner, Scheffers and Fox2012; Stattegger et al., Reference Stattegger, Tjallingii, Saito, Michelli, Thanh and Wetzel2013; Oliver and Terry, Reference Oliver and Terry2019; Surakiatchai et al., Reference Surakiatchai, Songsangworn, Pailoplee, Choowong, Phantuwongraj, Chabangborn and Charusiri2019). However, the question remains whether other factors contributed to this relocation of the coastline. Increased storminess would likely have led to erosion of the beach ridges and a rather transgressive trend of the coastline. An increase in sediment supply and/or decreased storminess would likely have caused a continuous aggradation of beach ridges, as observed by, for example, Oliver et al. (Reference Oliver, Murray-Wallace and Woodroffe2020) in southern Australia and Rodrigues et al. (Reference Rodrigues, Stapor, Rink, Dunbar and Doran2022) in Florida. The fact that the next set of beach ridges is located some 3 km seaward speaks against continuous aggradation. However, a lack of deposition could also be related to a decrease in sediment supply, so beach ridges might never have formed in this zone, or previously existing beach ridges might have later eroded. Interestingly, Chataro et al. (Reference Chataro, Choowong and Phantuwongraj2022) also recognised a gap in beach ridge formation at Pailin Beach (70 km SE of Chanthaburi) between ca. 3000 and 1800 yr in a spatially close setting. While the amount of data is very limited, the coincidence may rather point towards a lack of beach ridge preservation during this time. Such a lack could either be explained by a lack of sediment supply, a significant drop of sea level (at least some decimetres), or a time of highly fluctuating sea level. As there is no indication for a change in sediment supply or a reason to expect one, we favour sea-level drop as the controlling factor for the gap observed between the two sets of beach ridges.

The set of ridges located seaward (D, C, B) at the Chanthaburi estuary were deposited between ca. 2100 and 1200 yr ago, and coastal landforms with similar age have been documented in the vicinity of the study area (Chataro et al., Reference Chataro, Choowong and Phantuwongraj2022). While the information about the development of RSL change in the Gulf of Thailand and the neighbouring Sunda Shelf during this time is controversial (cf. Englong et al., Reference Englong, Punwong, Selby, Marchant, Traiperm and Pumijumnong2019; Wan et al., Reference Wan, Meltzner, Switzer, Lin, Wang, Bradley, Natawidjaja, Suwargadi and Horton2020), some studies suggest it may have dropped by almost 1 m during this time (Tjia, Reference Tjia1996; Oliver and Terry, Reference Oliver and Terry2019). If these reconstructions are correct, a strong regression tendency may likely have caused the seaward migration of the beach ridges (Fig. 3B and C). With the formation of the beach ridges, the Chanthaburi River as well as the nearby Welu River developed estuaries that are to be classified as barrier(-enclosed) or bar-built estuaries (cf., Roy et al., Reference Roy, Thom and Wright1980; Hume and Herdendorf, Reference Hume and Herdendorf1988). Since the formation of ridge B some 1200 yr ago, the coastline position has apparently been rather stable, as this ridge is only some 100 m from the present beach ridge on the active coast (ridge A).

In contrast to our study, Mallinson et al. (Reference Mallinson, Culver, Reide Corbett, Parham, Shazili and Yaaco2014) observe uniform progradation of a strandplain in the Setiu coastal region of NE Malaysia for the period ca. 3.0 to 1.9 ka and interpret this to reflect either constant slow relative sea-level fall or a still stand. However, Woodroffe and Horton (Reference Woodroffe and Horton2005) and Mann et al. (Reference Mann, Bender, Lorscheid, Stocchi, Vacchi, Switzer and Rovere2019) imply that the exact knowledge of sea-level dynamics is poorly constrained for this period in SE Asia, and Surakiatchai et al. (Reference Surakiatchai, Songsangworn, Pailoplee, Choowong, Phantuwongraj, Chabangborn and Charusiri2019) in fact summarise evidence of a steady sea-level lowering. Nevertheless, while a substantial sea-level drop could explain the observed lack of beach ridges along the Chanthaburi coast, it appears mandatory to collect more data from the wider region to either enforce or reject this hypothesis. One option to do so would be a geophysical survey to decipher the internal structure of beach ridges as well as drilling and investigating sediments in the estuary zone, which is beyond the scope of the present study.

CONCLUSIONS

OSL dating of the landward set of beach ridges south of the Chanthaburi estuary reveals evidence for a higher sea level around 3500 yr ago. Possibly, this was followed by a substantial drop and potential subsequent rise of sea level between ca. 3500 and 2100 yr ago, responsible for the gap between the two sets of beach ridges later occupied by the Chanthaburi estuary tidal zone. The following slow retreat of sea level formed the seaward set of beach ridges between ca. 2100 and 1200 yr ago. Eventually, the modern beach ridge formed after this time.

Supplementary Material

The supplementary material for this article can be found at https://doi.org/10.1017/qua.2023.34

Acknowledgments

Montri Choowong introduced us to the study area, which is gratefully acknowledged. We thank Stapana Kongsen, Ritu Sah, Fa-is Jindewha, Peerasit Surakiatchai, and Lukped for their valuable help during fieldwork, as well as Alexander Fülling and Jennifer Wolff for support of the OSL dating laboratory work. TanDEM-X data sets were provided by the German Aerospace Center (Deutsches Zentrum für Luft- und Raumfahrt; DLR). The authors thank Stephen Chua, Rahul Kumar, and an anonymous referee for critical but constructive reviews that helped to improve the article. This research is funded by Thailand Science research and Innovation Fund Chulalongkorn University CU_FRB65_dis (10)_098_23_28ʺ, as well as by a travel grant from the Wissenschaftliche Gesellschaft Freiburg im Breisgau.

References

REFERENCES

Abdulkarim, M., Grema, H.M., Adamu, I.H., Mueller, D., Schulz, M., Ulbrich, M., Miocic, J., Preusser, F., 2021. Effect of using different chemical dispersing agents in grain size analyses of fluvial sediments via laser diffraction spectrometry. Methods and Protocols 4, 44.CrossRefGoogle ScholarPubMed
Blott, S.J., Pye, K., 2001. GRADISTAT: a grain size distribution and statistics package for the analysis of unconsolidated sediments. Earth Surface Processes and Landforms 26, 12371248.CrossRefGoogle Scholar
Brill, D., Jankaew, K., Brückner, H., 2015. Holocene evolution of Phra Thong's beach-ridge plain (Thailand)—chronology, processes and driving factors. Geomorphology 245, 117134.CrossRefGoogle Scholar
Charusiri, P., Clark, A.H., Farrar, E., Archibald, D., Charusiri, B., 1993. Granite belts in Thailand: evidence from the 40Ar/39Ar geochronological and geologic syntheses. Journal of Asian Earth Sciences 8, 127136CrossRefGoogle Scholar
Chataro, C., Choowong, M., Phantuwongraj, S., 2022. Initial report on OSL dating from Pailin Beach Ridge Plain, Trat Province, eastern Gulf of Thailand with special highlight to record of the Holocene sea level change. Bulletin of Earth Sciences of Thailand 14, 6268.Google Scholar
Chen, M., Qi, H., Intasen, W., Kanchanapant, A., Wang, C., Zhang, A., 2020. Distributions of diatoms in surface sediments from the Chanthaburi coast, Gulf of Thailand, and correlations with environmental factors. Regional Studies in Marine Science 34, 100991.CrossRefGoogle Scholar
Choowong, M., 2002a. The geomorphology and assessment of indicators of sea-level changes to study coastal evolution from the Gulf of Thailand. In: Proceedings of International Symposium on “Geology of Thailand.” Department of Mineral Resources, Thailand, pp. 207220.Google Scholar
Choowong, M., 2002b. Coastal sedimentary lithofacies and episodic evolution from the Eastern part of Thailand. Journal of Scientific Research Chulalongkorn University 27, 111129.Google Scholar
Culver, S.J., Leorri, E., Mallinson, D.J., Reide Corbett, D., Shazili, N.A.M., 2015. Recent coastal evolution and sea-level rise, Setiu wetland, peninsular Malaysia. Palaeogeography, Palaeoclimatology, Palaeoecology 417, 406421.CrossRefGoogle Scholar
Davies, J.L., 1957. The importance of cut and fill in the development of sand beach ridges. Australian Journal of Science 20, 105111.Google Scholar
Degering, D., Degering, A., 2020. Change is the only constant—time-dependent dose rates in luminescence dating. Quaternary Geochronology 58, 101074.CrossRefGoogle Scholar
[DMR] Department of Mineral Resources of Thailand, 2001. Coastal Geomorphic Map of Amphoe Laem Sing-Amphoe Khao Saming, Chanthaburi (5433IV-5433I). 1:150,000. Geological Survey Division, Bangkok.Google Scholar
[DMR] Department of Mineral Resources of Thailand, 2007. Geological Map of Changwat Chanthaburi. 1:250,000. Geological Survey Division, Bangkok.Google Scholar
Durand, Gaël, van den Broeke, M.R., Le Cozannet, G., Edwards, T.L., Holland, P.R., Jourdain, N.C., Marzeion, B., et al., 2022. Sea-level rise: from global perspectives to local services. Frontiers in Marine Science 8, 709595.CrossRefGoogle Scholar
Englong, A., Punwong, P., Selby, K., Marchant, R., Traiperm, P., Pumijumnong., N., 2019. Mangrove dynamics and environmental changes on Koh Chang, Thailand during the last millennium. Quaternary International 500, 128138.CrossRefGoogle Scholar
Faye, S., Eynaud, F., Bosq, M., Lambert, C., Verdin, F., Vequaud, P., Lodyga, O., et al., 2019. Holocene palaeoenvironmental evolution of the Médoc peninsula (SW France): insights from the sedimentological study of the “Lède du Gurp” archaeological site. Quaternaire 30, 3146.CrossRefGoogle Scholar
FitzGerald, D.M., Fenster, M.S., Argow, B.A., Buynevich, I.V., 2008. Coastal impacts due to sea-level rise. Annual Review of Earth and Planetary Sciences 36, 601647.CrossRefGoogle Scholar
Galbraith, R.F., Roberts, R.G., Laslett, G.M., Yoshida, H., Olley, J.M., 1999. Optical dating of single and multiple grains of quartz from Jinmium Rock Shelter, Northern Australia: Part I, Experimental design and statistical models. Archaeometry 41, 339364.CrossRefGoogle Scholar
Gouramanis, C., Switzer, A.D., Bristow, C.S., Pham, D.T., Mauz, B., Hoang, Q.D., Lam, D.D., et al., 2020. Holocene evolution of the Chan May coastal embayment, central Vietnam: changing coastal dynamics associated with decreasing rates of progradation possibly forced by mid- to late-Holocene sea-level changes. Geomorphology 367, 107273.CrossRefGoogle Scholar
Hanebuth, T.J.J., Stattegger, K., Grootes, P.M., 2000. Rapid flooding of the Sunda Shelf: a late-glacial sea-level record. Science 288, 10331035.CrossRefGoogle Scholar
Hanebuth, T.J.J., Voris, H.K., Yokoyama, Y., Saito, Y., Okuno, J., 2011. Formation and fate of depocenters on Southeast Asia's Sunda Shelf over the past sea-level cycle and biogeographic implications. Earth-Science Reviews 104, 92110.CrossRefGoogle Scholar
Hansom, J., 2001. Coastal sensitivity to environmental change: a view from the beach. Catena 42, 291305.CrossRefGoogle Scholar
Hara, H., Tokiwa, T., Kurihara, T., Charoentitirat, T., Ngamnithiporn, A., Visetnat, K., Tominaga, K., Kamata, Y., Ueno, K., 2018. Permian–Triassic back-arc basin development in response to Paleo-Tethys subduction, Sa Kaeo–Chanthaburi area in southeastern Thailand. Gondwana Research 64, 5066.CrossRefGoogle Scholar
Heiri, O., Lotter, A.F., Lemcke, G., 2001. Loss on ignition as a method for estimating organic and carbonate content in sediments: reproducibility and comparability of results. Journal of Paleolimnology 25, 101110.CrossRefGoogle Scholar
Hesp, P.A., Hung, C.C., Hilton, M., Ming, C.L., Turner, I.M., 1998. A first tentative Holocene sea-level curve for Singapore. Journal of Coastal Research 14, 308–14.Google Scholar
Horton, B.P., Gibbard, P.L., Mine, G., Morley, R., Purintavaragul, C., Stargardt, J.M., 2005. Holocene sea levels and palaeoenvironments, Malay-Thai Peninsula, southeast Asia. The Holocene 15, 11991213.CrossRefGoogle Scholar
Hume, T.M., Herdendorf, C.E., 1988. A geomorphic classification of estuaries and its application to coastal resource management: a New Zealand example. Ocean & Shoreline Management 11, 249274.CrossRefGoogle Scholar
Jacobs, Z., 2008. Luminescence chronologies for coastal and marine sediments. Boreas 37, 508535.CrossRefGoogle Scholar
Jaroenongard, C., Babel, M.S., Shrestha, S., Weesakul, S., Nitivattananon, V., Khadka, D., 2021. Projecting relative sea level rise under climate change at the Phrachula Chomklao Fort tide gauge in the Upper Gulf of Thailand. Water 13, 1702.CrossRefGoogle Scholar
Kelsey, H.M., 2015. Geomorphological indicators of past sea levels. In: Shennan, I., Long, A.J., Horton, B.P. (Eds.), Handbook of Sea-Level Research. Wiley, Hoboken, NJ, pp. 6682.CrossRefGoogle Scholar
Kengkoom, S., 1992. Quaternary sea-level fluctuations in the coastal area of eastern Thailand: a synoptic view in relation to mineral resources exploration. Journal of Southeast Asian Earth Sciences 7, 3951.CrossRefGoogle Scholar
Kongsen, S., Phantuwongraj, S., Choowong, M., Chawchai, S., Udomsak, S., Chansom, C., Ketthon, C., Surakiatchai, P., Miocic, J.M., Preusser, F., 2022. Multi-proxy approach to identify the origin of high energy coastal deposits from Laem Son National Park, Andaman Sea of Thailand. Quaternary International 625, 8295.CrossRefGoogle Scholar
Lewis, S.L., Sloss, C.R., Murray-Wallace, C.V., Woodroofe, W.D., Smithers, S.C., 2013. Post-glacial sea-level changes around the Australian margin: a review. Quaternary Science Reviews 74, 115138.CrossRefGoogle Scholar
Liu, S., Shi, X., Yang, G., Khokiattiwong, S., Kornkanitnan, N., 2016. Distribution of major and trace elements in surface sediments of the western Gulf of Thailand: implications to modern sedimentation. Continental Shelf Research 117, 8191.CrossRefGoogle Scholar
Mallinson, D., Burdette, K., Mahan, S., Brook, G., 2008. Optically stimulated luminescence age controls on late Pleistocene and Holocene coastal lithosomes, North Carolina, USA. Quaternary Research 69, 97109.CrossRefGoogle Scholar
Mallinson, D.J., Culver, S.J., Reide Corbett, D., Parham, P.R., Shazili, N.A.M., Yaaco, R., 2014. Holocene coastal response to monsoons and relative sea-level changes in northeast peninsular Malaysia. Journal of Asian Earth Sciences 91, 194205.CrossRefGoogle Scholar
Mann, T., Bender, M., Lorscheid, T., Stocchi, P., Vacchi, M., Switzer, A., Rovere, A., 2019. Holocene sea levels in Southeast Asia, Maldives, India and Sri Lanka: the SEAMIS database. Quaternary Science Reviews 219, 112125.CrossRefGoogle Scholar
Miocic, J.M., Sah, R., Chawchai, S., Surakiatchai, P., Choowong, M., Preusser, F., 2022. High resolution luminescence chronology of coastal dune deposits near Chumphon, western Gulf of Thailand. Aeolian Research 56, 100797.CrossRefGoogle Scholar
Murray, A.S., Wintle, A.G., 2000. Luminescence dating of quartz using an improved single-aliquot regenerative-dose protocol. Radiation Measurements 32, 5773.CrossRefGoogle Scholar
Nielsen, A., Murray, A. S., Pejrup, M., Elberling, B., 2006. Optically stimulated luminescence dating of a Holocene beach ridge plain in northern Jutland, Denmark. Quaternary Geochronology 1, 305312.CrossRefGoogle Scholar
Nimnate, P., Chutakositkanon, V., Choowong, M, Pailoplee, S., Phantuwongraj, S., 2015. Evidence of Holocene sea level regression from Chumphon coast of the Gulf of Thailand. ScienceAsia 41, 5563.CrossRefGoogle Scholar
Oliver, G.J.H., Terry, J.P., 2019. Relative sea-level highstands in Thailand since the Mid-Holocene based on 14C rock oyster chronology. Palaeogeography, Palaeoclimatology, Palaeoecology 517, 3038.CrossRefGoogle Scholar
Oliver, T.S., Murray-Wallace, C.V., Woodroffe, C.D., 2020. Holocene shoreline progradation and coastal evolution at Guichen and Rivoli Bays, southern Australia. The Holocene 30, 106124.CrossRefGoogle Scholar
Oliver, T.S.N., Dougherty, A.J., Gliganic, L.A., Woodroffe, C.D., 2015. Towards more robust chronologies of coastal progradation: optically stimulated luminescence ages for the coastal plain at Moruya, south-eastern Australia. Holocene 25, 536546.CrossRefGoogle Scholar
Oliver, T.S.N., Thom, B.G., Woodroffe, C.D., 2017. Formation of beach-ridge plains: an appreciation of the contribution by Jack L. Davies. Geographical Research 55, 305320.CrossRefGoogle Scholar
Oppenheimer, M., Glavovic, B.C., Hinkel, J., van de Wal, R., Magnan, A.K., Abd-Elgawad, A., Cai, R., et al., 2019. Sea level rise and implications for low-lying islands, coasts and communities. In: Pörtner, H.-O., Roberts, D.C., Masson-Delmotte, V., Zhai, P., Tignor, M., Poloczanska, E., Mintenbeck, K., et al. (Eds.), IPCC Special Report on the Ocean and Cryosphere in a Changing Climate. Cambridge University Press, Cambridge, pp. 321445.Google Scholar
Otvos, E.G., 2000. Beach ridges—definitions and significance. Geomorphology 32, 83108.CrossRefGoogle Scholar
Pailoplee, S., Charusiri, P., 2017. Analysis of seismic activities and hazards in Laos: a seismicity approach. Earth Planets and Space 61, 13131325.CrossRefGoogle Scholar
Pailoplee, S., Choowong, M., 2013. Probabilities of earthquake occurrences in mainland Southeast Asia. Arabian Journal of Geosciences 6, 49935006.CrossRefGoogle Scholar
Peltier, W.R., 2004. Global glacial isostasy and the surface of the ice-age Earth: the ICE-5 G (VM2) model and GRACE. Annual Reviews of Earth Planetary Science 32, 111149.CrossRefGoogle Scholar
Phoosongsee, J., Morely, C.K., 2019. Evolution of a major extensional boundary fault system during multi-phase rifting in the Songkhla Basin, Gulf of Thailand. Journal of Asian Earth Sciences 172, 113.CrossRefGoogle Scholar
Plater, A. J., Kirby, J. R., 2011. Sea-level change and coastal geomorphic response. In: Flemming, B.W., Hansom, J.D. (Eds.), Treatise on Estuarine and Coastal Science. Vol. 3. Elsevier, Amsterdam, pp. 3972.CrossRefGoogle Scholar
Prescott, J. R., Hutton, J. T., 1994. Cosmic ray contributions to dose rates for luminescence and ESR dating: large depths and long-term time variations. Radiation Measurements 23, 497500.CrossRefGoogle Scholar
Preusser, F., Kasper, H.U., 2001. Comparison of dose rate determination using high-resolution gamma spectrometry and inductively coupled plasma-mass spectrometry. Ancient TL 19, 1923.Google Scholar
Rodrigues, K., Stapor, F.W., Rink, W.J., Dunbar, J.S., Doran, G., 2022. A 5700-year-old beach-ridge set at Cape Canaveral, Florida, and its implication for Holocene sea-level history in the southeastern USA. The Holocene 32, 4056.CrossRefGoogle Scholar
Roy, P.S., Thom, B.G., Wright, L.D., 1980. Holocene sequences on an embayed high-energy coast: an evolutionary model. Sedimentary Geology 26, 119.CrossRefGoogle Scholar
Santisteban, J.I., Mediavilla, R., López-Pamo, E., Dabrio, C.J., Blanca Ruiz Zapata, M., José Gil García, M., Castaño, S., Martínez-Alfaro, P.E., 2004. Loss on ignition: a qualitative or quantitative method for organic matter and carbonate mineral content in sediments? Journal of Paleolimnology 32, 287299.CrossRefGoogle Scholar
Scheffers, A. Brill, D. Kelletat, D. Brückner, H., Scheffers, S., Fox, K., 2012. Holocene sea levels along the Andaman Sea coast of Thailand. The Holocene 22, 11691180.CrossRefGoogle Scholar
Scoffin, T.P., Le Tissier, M.D.A., 1998. Late Holocene sea level and reef-flat progradation, Phuket, south Thailand. Coral Reefs 17, 273276.CrossRefGoogle Scholar
Shawler, J.L., Hein, C.J., Obara, C.A., Robbins, M.G., Huot, S., Fenster, M.S., 2021. The effect of coastal landform development on decadal-to millennial-scale longshore sediment fluxes: evidence from the Holocene evolution of the central mid-Atlantic coast, USA. Quaternary Science Reviews 267, 107096.CrossRefGoogle Scholar
Short, A.D., Hesp, P.A., 1982. Wave, beach and dune interactions in southeast Australia. Marine Geology 48, 259284.CrossRefGoogle Scholar
Sinsakul, S., 1992. Evidence of Quaternary sea level changes in the coastal areas of Thailand: a review. Journal of Southeast Asian Earth Sciences 7, 2337.CrossRefGoogle Scholar
Sinsakul, S., Sonsuk, M., Hasting, P.J., 1985. Holocene sea levels in Thailand: evidence and basis for interpretation. Journal of the Geological Society of Thailand 8, 112.Google Scholar
Sojisuporn, P., Sangmanee, C., Wattayakorn, G., 2013. Recent estimate of sea-level rise in the Gulf of Thailand. Maejo International Journal of Science and Technology 7, 106113.Google Scholar
Somboon, J.R.P., 1988. Paleontological study of the recent marine sediments in the lower central plain, Thailand. Journal of Southeast Asian Earth Sciences 2, 201210.CrossRefGoogle Scholar
Somboon, J.R.P., Thiramongkol, N., 1992. Holocene highstand shoreline of the Chao Phraya delta, Thailand. Journal of Southeast Asian Earth Sciences 7, 5360.CrossRefGoogle Scholar
Sone, M., Metcalfe, I., Chaodumrong, P., 2012. The Chanthaburi terrane of southeastern Thailand: stratigraphic confirmation as a disrupted segment of the Sukhothai Arc. Journal of Asian Earth Sciences 61, 1632.CrossRefGoogle Scholar
Stattegger, K., Tjallingii, R., Saito, Y., Michelli, M., Thanh, N.T., Wetzel, A., 2013. Mid to late Holocene sea-level reconstruction of southeast Vietnam using beachrock and beach-ridge deposits. Global and Planetary Change 110, 214222.CrossRefGoogle Scholar
Suk-ueng, N., Buranapratheprat, A., Gunbua, V., Leadprathom, N., 2013. Mangrove composition and structure at the Welu Estuary, Khlung District, Chanthaburi Province, Thailand. Journal of Environmental Science, Toxicology and Food Technology 7, 1724.Google Scholar
Surakiatchai, P., Choowong, M., Charusiri, P., Charoentitirat, T., Chawchai, S., Pailoplee, S., Chabangborn, A., et al., 2018. Paleogeographic reconstruction and history of the sea level change at Sam Roi Yot national park, Gulf of Thailand. Tropical Natural History 18, 112134.Google Scholar
Surakiatchai, P., Songsangworn, E., Pailoplee, S., Choowong, M., Phantuwongraj, S., Chabangborn, A., Charusiri, P., 2019. Optically stimulated luminescence dating reveals rate of beach ridge and sand spit depositions from the upper Gulf of Thailand. Songklanakarin Journal of Science and Technology 41, 11361145.Google Scholar
Tamura, T., 2012. Beach ridges and prograded beach deposits as palaeoenvironment records. Earth-Science Reviews 114, 279297.CrossRefGoogle Scholar
Tamura, T., Saito, Y., Bateman, M.D., Nguyen, V.L., Ta, T.K.O., Matsumoto, D., 2012. Luminescence dating of beach ridges for characterizing multi-decadal to centennial deltaic shoreline changes during Late Holocene, Mekong River delta. Marine Geology 326–328, 140153.CrossRefGoogle Scholar
Terry, J. P., Goff, J., Jankaew, K., 2018. Major typhoon phases in the upper Gulf of Thailand over the last 1.5 millennia, determined from coastal deposits on rock islands. Quaternary International 487, 8798.CrossRefGoogle Scholar
Thai Meteorological Department, 2020. Statistical Records of Tropical Cyclones Entering Thailand over 69 Years (1951–2019). Technical Report. [In Thai.] Bangkok.Google Scholar
Tjia, H.D., 1996. Sea-level changes in the tectonically stable Malay-Thai Peninsula. Quaternary International 31, 95101.CrossRefGoogle Scholar
Trisirisatayawong, I., Naeije, M., Simons, W., Fenoglio-Marc, L., 2011. Sea level change in the Gulf of Thailand from GPS-corrected tide gauge data and multi-satellite altimetry. Global and Planetary Change 76, 137151.CrossRefGoogle Scholar
Uchida, E., Nagano, S., Niki, S., Yonezu, K., Saitoh, Y., Shin, K.C., Hirata, T., 2022 Geochemical and radiogenic isotopic signatures of granitic rocks in Chanthaburi and Chachoengsao provinces, southeastern Thailand: implications for origin and evolution. Journal of Asian Earth Sciences : X 8, 100111.Google Scholar
Vongvisessomjai, S., 2009. Tropical cyclone disasters in the Gulf of Thailand. Songklanakarin Journal of Science and Technology 31, 213227.Google Scholar
Wang, C., Chen, M., Qi, H., Intasen, W., Kanchanapant, A., 2020. Grain-size distribution of surface sediments in the Chanthaburi Coast, Thailand and implications for the sedimentary dynamic environment. Journal of Marine Science and Engineering 8, 242.CrossRefGoogle Scholar
Wan, J.X.W., Meltzner, A.J., Switzer, A.D., Lin, K., Wang, X.F., Bradley, S.L., Natawidjaja, D.H., Suwargadi, B.W., Horton, B.P., 2020. Relative sea level stability and the radiocarbon marine reservoir correction at Natuna Island, Indonesia, since 6400 yr BP. Marine Geology 430, 106342.CrossRefGoogle Scholar
Woodroffe, S.A., Horton, B.P., 2005. Holocene sea-level changes in the Indo-Pacific. Journal of Asian Earth Sciences 25, 2943.CrossRefGoogle Scholar
Figure 0

Figure 1. (A) Geomorphologic and geologic map of the Chanthaburi area, eastern Gulf of Thailand (study area indicated by the red rectangle). Inset: location of the study area in the Gulf of Thailand (DMR, 2007, 2001). (B) Satellite imagery of the study area and (C) beach ridges studied indicated on the TanDEM-X digital surface model.

Figure 1

Figure 2. (A) Cross section through the studied beach ridges along the line indicated in B. (B) Simplified geomorphologic map of the study area showing the sampling locations.

Figure 2

Figure 3. Schematic model of the coastal depositional environment evolution of Chanthaburi. (A) Around 3500 yr ago, a high sea-level position causes the development of beach ridges along the shoreline. (B) A substantial drop in sea level between 3500 and 2100 yr ago might be responsible for the lack of beach ridge formation during this time. (C) The seaward set of beach ridges establishes with falling sea level between ca. 2100 and 1200 yr ago and forms the bar-built Chanthaburi estuary. (D) Present-day coastal setting at Chanthaburi.

Supplementary material: File

Ballian et al. supplementary material

Ballian et al. supplementary material
Download Ballian et al. supplementary material(File)
File 19.9 MB