4.1 Chronology

The seven AMS ¹⁴C dates (TPS-1 to −7) and other LSC ¹⁴C dates are listed in Table 1. First of all, we shall compare the dating results between AMS and LSC methods. TPS-UB is the right valve of the giant oyster shell whereas TPS-1 to −7 samples are from the left valve of the same oyster. They should have the same age. The AMS ¹⁴C ages of the shell range from 7260±106 to 7607±95 BP, resulting in a weighted average with standard deviation of 7444±103 BP (n = 7) (Table 1). The calculations of the weighted average and standard deviation are following (Bevington Reference Bevington1969):

(1) $${\rm{Weighted \;average \;of}\,A = \rm \mu = {\Sigma _i}({A_i}/{\sigma _i}^2)/{\Sigma _i}(1/{\sigma _i}^2)}$$

(2) $$\rm \eta \,of\,A = {\rm{Sqrt}}[\{ (1/(n - 1))^*{\Sigma _i}{(({A_I} - \mu )/{\sigma _i})^2}]\} /\{ ({\Sigma _i}(1/{\sigma _i}^2))/n\} ]$$

where μ is the weighted average; σ_i is the uncertainty in A_i; η is the standard deviation of A; n is the number of ages in the calculation. Similarly, for ΔR calculation, the weighted average ΔR value and its standard deviation will be used ΔR to replace A in the above equations.

The 347-yr age range of the AMS ages does not show any trends (Figure 2). According to previous investigations, no C. gigas could live more than 20 years (e.g., Wang et al. Reference Wang, Keppens, Nielsen and van Riet1995). Therefore, the large AMS ¹⁴C age range of the giant oyster might be attributed to laboratory dating uncertainty and/or the natural variation of the marine reservoir effect. The LSC ¹⁴C age of the shell is 7713±40 BP which is very close to the oldest AMS ¹⁴C age (7607±95 BP) of the shell, but 269 years older than the averaged AMS ¹⁴C age (7444±103 BP). Considering the age uncertainties, the LSC ¹⁴C age is slightly older than the average AMS ¹⁴C age.

Second, we shall compare the age of the organic sample with the ages of the oyster shell. Sample TPS-UA is a grass sample taken from the inside of the oyster shell. This grass sample was dated by LSC, yielding a ¹⁴C age of 7260±46 BP (Table 1). This age does not need to make marine reservoir age correction. Using the calibration curve IntCal20 (Reimer et al. Reference Reimer, Austin, Bard, Bayliss, Blackwell, Ramsey, Butzin, Cheng, Edwards and Friedrich2020), the calibrated ¹⁴C age of this grass sample is 8090±90 cal BP. If we compare uncalibrated ¹⁴C ages of the grass sample with the LSC dated right valve and the 7 AMS dates of the left valve from the same oyster shell, the grass ¹⁴C age (7260±46 BP) is apparently younger than the LSC ¹⁴C age (7713±40 BP) and the averaged AMS ¹⁴C age (7444±103 BP) of the shell, it is the same as the shell AMS ¹⁴C ages of TPS-1 and TPS-7 within uncertainties. In principle, the grass sample would get into the shell either when the oyster was alive or after the oyster was dead. If the grass and oyster had the same depositional age, then the older ¹⁴C age of the oyster shell should be caused by the marine reservoir effect. Thus, we should compare the calibrated ¹⁴C ages of the grass sample and the shell samples.

Using http://calib.org/marine/, we have found six nearest points (all within 60 km) to the study site. The six ΔR values range from –105±41 to –23±42 years (Yoneda et al. Reference Yoneda, Uno, Shibata, Suzuki, Kumamoto, Yoshida, Sasaki, Suzuki and Kawahata2007), yielding a weighted average of –66±30 years. Following the equations in Heaton et al. (Reference Heaton, Köhler, Butzin, Bard, Reimer, Austin, Bronk Ramsey, Grootes, Hughen, Kromer, Reimer, Adkins, Burke, Cook, Olsen and Skinner2020), X_i ^Adj and σ_i ^Adj values were calculated (Table 1). These values were used to obtain the calibrated ages by Marine20 calibration curve. The calibrated ages are from 7490±240 to 7805±230 cal BP (2σ), resulting in a weighted age of 7660±96 cal BP (n = 7) (Table 1). Thus, we have three key numbers in comparison: 8090±90 cal BP of the grass sample; 7925±175 cal BP of the LSC dated oyster shell (right valve); and the weighted average (7660±93 cal BP) of the 7 AMS ages from the left valve samples. The comparison indicates that the calibrated ¹⁴C ages of both LSC dated grass and oyster shell agree very well. However, the grass age is close to the old AMS ages (e.g., TPS-3 to TPS-5 in Table 1) within uncertainties but younger than the weighted average age of the AMS dates. Since we do not have AMS dating result on the grass sample, the grass age older than the average AMS age of the oyster shell may be caused by the systematic dating difference between the LSC Lab and the AMS Lab. As mentioned earlier, the LSC age is older than the average AMS age of the oyster shell (Table 1). For safe interpretation, we will use the LSC dated grass age and the weighted AMS age of the oyster shell (8090∼7660 cal BP) for the period of the ancient shoreline. However, the depositional age of the giant oyster shell (or the oyster reef) should be ∼7660 cal BP based on the AMS dating results.

4.2 δ¹⁸O and δ¹³C

Many marine shells and freshwater carbonates have equilibrium exchange of carbon and oxygen isotopes between carbonate and water (Friedman and O’Neil Reference Friedman and O’Neil1977; Li et al. Reference Li, Bischoff, Ku and Zhu2004, Reference Li, Xu, Ku, You, Buchheim and Peters2008; Ravelo and Hillaire-Marcel Reference Ravelo, Hillaire-Marcel, Hillaire-Marcel and De Vernal2007). The oxygen isotope equilibrium can be described by the following equation (Friedman and O’Neil Reference Friedman and O’Neil1977):

(3) $$\rm T\left( {^ \circ {\rm{C}}} \right) = 17.0-4.52\left( {{{\rm{\delta }}^{18}}{{\rm{O}}_{\rm{c}}}-{{\rm{\delta }}^{18}}{{\rm{O}}_{\rm{w}}}} \right) + 0.13\,{\left( {{{\rm{\delta }}^{{\rm{18}}}}{{\rm{O}}_{\rm{c}}}-{{\rm{\delta }}^{{\rm{18}}}}{{\rm{O}}_{\rm{w}}}} \right)^2}$$

where δ¹⁸O_c (VPBD) and δ¹⁸O_w (SMOW) are δ¹⁸O values of calcite and equilibrated water, respectively; T is the water temperature at the equilibrium exchange. Eq. (3) can be simplified as the following equation in a temperature range of 0∼50^oC (Zhao et al. Reference Zhao, Li, Liu, Mii, Sun and Shen2015):

(4) $$\rm{\delta ^{18}}{{\rm{O}}_{{\rm{calcite}}}}\,\left( {{\rm{VPDB}}} \right)-{\delta ^{18}}{{\rm{O}}_{{\rm{water}}}}\,\left( {{\rm{SMOW}}} \right) = 3.945-0.232T{\rm{ }}\left( {^ \circ {\rm{C}}} \right)$$

Although it is difficult to know the information of δ¹⁸O_w in the past, for an assumed water δ¹⁸O in a dry season, one can estimate the seasonal temperature. Using stable carbon and oxygen isotope records, we may reconstruct the water temperature of the oyster lived and other conditions ca. 8000 years ago.

Two oyster shells were collected from a culture oyster pool on February 9 and 11, 2008. The oyster pool was using seawater from coastal Tainan City, Taiwan. Figures 3A and 3B exhibit the δ¹⁸O profiles of both left (lower) and right (upper) valves of the two modern oyster shells: 990209 and 990211. All of the δ¹⁸O profiles reveal heavier values in the winter and lighter values in the summer. In the meantime, the δ¹³C profiles are positively correlated with the δ¹⁸O profiles, which means that the shell carbonate is in isotopic equilibrium fraction with its parent water. Paleo-temperature can be reconstructed from such a shell (Mook Reference Mook1971). Here we take the δ¹⁸O profiles of left valves for discussion as the studied ancient oyster shell is a left valve. The Δδ¹⁸O values between winter and summer for 990209 and 990211 are 4.2‰ and 3‰ (Figure 3A), respectively. These results indicate that the oyster shells can have Δδ¹⁸O values of 3‰∼4‰, being lighter in summer and heavier in winter which agrees well with the temperature influence on the oxygen isotopic fractionation. According to Eq. (4), Δδ¹⁸O values of 3‰ and 4‰ represent a temperature change of 13^oC (= 3/0.232) and 17^oC (= 4/0.232), respectively. For such temperature changes between winter and summer, we can examine them with the air temperature change of Tainan City recorded by the meteorological station. Figure 3C shows the air temperature from January to December in Tainan in 2008 as well as the average during 2000–2008. The ΔT between the winter and summer of Tainan in 2008 is 13.4^oC. Assuming the water temperature where the oyster lived reflects closely the monthly air temperature, the Δδ¹⁸O values of 3‰∼4‰ should represent roughly a temperature change of 13^oC. Although this estimation involves a variation of the water δ¹⁸O (δ¹⁸O_water in Eq. [4]) due to salinity change, the major influence factor on the δ¹⁸O_calcite is water temperature because the culture pool used the seawater without adding any freshwater. This study demonstrates that oxygen isotopic fractionation between the oyster shell and its parent water is under equilibrium, so that Eq. (4) can be used for water temperature calculation.

For the ancient oyster shell, the oldest part was selected for high-resolution stable isotope study. In a 5.5-cm section, a total of 79 subsamples were taken (Figure 4), but only 69 samples had δ¹⁸O and δ¹³C results due to sample amount limitation. The δ¹⁸O varies from –6.03‰ to –1.33‰, whereas the δ¹³C variation is between –2.21‰ and –0.31‰. These profiles show the following features: (1) the δ¹⁸O and δ¹³C values co-vary (R² = 0.6, n = 69); (2) the δ¹⁸O has long-term variations superimposed on minor fluctuations, which may display seasonal cycles; and (3) the Δδ¹⁸O values for the long-term cycles are ∼4‰ which is close to the value of the modern oyster shells. Although some growth bands (thin dark lines) appear in the picture of the shell section in Figure 4, these bands are certainly not annual bands, based on the δ¹⁸O and δ¹³C profiles. To view the δ¹⁸O and δ¹³C profiles, the δ¹⁸O values from samples 3–8 are between –2‰ to –1‰, reflecting the winter values under cold water temperatures. Then, the δ¹⁸O sharply increased and reached a minimum of around –5.2‰ (samples 16–17), representing the summer values under warm and less saline water conditions as the relationship of the water δ¹⁸O value and salinity is positively correlated (Dämmer et al. Reference Dämmer, Nooijer, Sebille, Haak and Reichart2020). Thus, one may assume the δ¹⁸O trend from sample 1 to 18 accounted for a one-year cycle, so we assign the cycle as Year 1 (Yr 1 in Figure 4). The δ¹³C trend corresponded positively to the δ¹⁸O trend, being heavier values in the winter and lighter values in the summer. Unlike the modern cultured oysters which lived in a pool, the ancient oyster lived in a natural environment where the δ¹³C could be influenced by the δ¹³C of surface runoff (Li et al. Reference Li, Xu, Ku, You, Buchheim and Peters2008). The δ¹³C of total dissolved CO₂ (mainly HCO₃ ⁻) in the marine surface water is around 0‰ (V-PDB) under isotopic equilibrium exchange with the atmospheric CO₂. When organic matter is decomposed, the CO₂ from the organic carbon with lighter δ¹³C enters the surface water, which makes the δ¹³C of total dissolved CO₂ to be lighter. In the summertime, higher organic matter decomposition under warm and humid conditions in the surface runoff leads to lighter δ¹³C than that in the wintertime. In Taiwan, summer monsoon rains have lighter δ¹⁸O due to amount and source effects. In contrast, the δ¹⁸O and δ¹³C of surface water in wintertime are relatively heavier. Therefore, the δ¹⁸O and δ¹³C values have covariance. Based on the δ¹⁸O and δ¹³C profiles shown in Figure 4, one may identify four annual cycles. Except Yr 3, the δ¹⁸O and δ¹³C in other three years were strongly correlated. The poor correlation of δ¹⁸O and δ¹³C in Yr 3 was probably due to the influence of heavy and frequent rains in the warm seasons because the δ¹⁸O values were quite depleted (Figure 4). Note that the fluctuations of the δ¹⁸O and δ¹³C in the wintertime were relatively small, whereas the summer δ¹⁸O and δ¹³C variations were large, especially when the oyster got older. The large fluctuation in the summer δ¹⁸O and δ¹³C could be attributed to the salinity change because heavy rains (or typhoon) mainly occur in summer to autumn. For such a reason, the winter δ¹⁸O value reflects more temperature effect but less salinity effect on isotopic exchange with calcium carbonate and its parent water.

4.3 Sea Level during 8090∼7660 cal BP

The ancient oyster lived in a shallow saline water environment (less than 5 m water depth) around ∼7660 cal BP based on the AMS dating result. This oyster reef was –5.5 m a.s.l., representing a high stand of the marine transgression in Taipei Basin during the early Holocene. In the same section, the P. placenta shell sample which had a LSC ¹⁴C age of 7643±54 BP and Marine20 curve calibrated ¹⁴C age of 7845±175 cal BP was 0.5 m a.s.l. at the sampling time (Table 1 and Figure 1). Thus, according to the LSC dating results of the grass sample, oyster shell and the P. placenta shell as well as the AMS dating results, depositional age of the studied stratum was 8090∼7660 cal BP. The studied section contained at least 5 m thick sediments between the oyster shell and the P. placenta shell. However, the ¹⁴C dating results of the oyster shells and P. placenta shell are no difference within uncertainties (Table 1). The 5-m thick sediments of the studying site were deposited very fast within a short time period around 8000 cal BP, which is the sedimentary feature of marine transgression. The same situation was found in a drill core which was located ∼5 km north of our studying site (Figure 1). Two LSC ¹⁴C ages of the marine shell samples from core depths of 18.1 and 22.2 m were 8630±415 and 8510±290 cal BP (2σ), respectively (Table 1). The 4-m thick sediments were also deposited very fast. Thus, the marine transgression in Taipei Basin occurred during 8600 cal BP to 7660 cal BP. One can treat the oyster and P. placenta site as a shoreline during 8090∼7660 cal BP. Assuming the elevations of these shells represent the sea level in the early Holocene, we can estimate their minimum sea level elevations.

Due to the normal fault of Shanchiao Fault, Taipei Basin has been sinking through the late Pleistocene to Holocene. Based on the ¹⁴C dates and sample depths of a drill core (Sungshan No. 2) that is the nearest core from our study site, the tectonic subsidence/uplift rates were 0.0, +0.2 and −0.3 mm/yr at 8780, 9610 and 9790 cal BP, respectively (Chen et al. Reference Chen, Lin, Yang, Fei, Shea, Kung, Lin and Yang2008). Assuming a subsidence rate of 0.1 mm/yr on the eastern edge of Taipei Basin throughout Holocene, the subsidence at the sampling site would be 0.8 m over the past 8300 years, which is within the uncertainty of the estimation. Thus, the oyster had an elevation of –5 m a.s.l. and the P. placenta shell had 0 m a.s.l. during 8090∼7660 cal BP. Given a range of 1–3 m water depths for the marine animals to live, the elevations of the sea level are estimated 1∼3 m a.s.l. during 8090∼7660 cal BP. From 8600 cal BP to 7600 cal BP, the sea level was rising; and the sea level was about 1–3 m higher during 8090∼7660 cal BP than the modern sea level.

Chen et al. (Reference Chen, Lin, Yang, Fei, Shea, Kung, Lin and Yang2008) concluded: (1) seawater entered Taipei Basin around 10,000 cal BP during the Holocene marine transgression which turned the sedimentary environment of Taipei Basin from freshwater lake to semi-saline estuary environments; (2) the sea level stand in Taipei Basin reached the highest level during 8160∼7850 cal BP which was higher than modern sea level; (3) then sea level dropped. Our study of the marine shells agrees well with the above conclusions, but further refines the sea level change in the early Holocene: the sea level rose from 8600 cal BP to 7600 cal BP; and the decline of sea level was after 7600 cal BP.

According to the review paper of Smith et al. (Reference Smith, Harrison, Firth and Jordan2011), sea level rise during the early Holocene behaved differently in different regions. However, the meltwater flux from the discharges of Lake Agassize/Ojibway in North America occurred around 8470 cal BP caused a strong increase in sea level. Our oyster shell was deposited shortly after this time, agreeing well with the sea level rise event. The Melting Water Pulse (MWP) 1d marked between 7100 and 7700 cal BP in Figure 3 of Smith et al. (Reference Smith, Harrison, Firth and Jordan2011) was supported by the studies of Liu et al. (Reference Liu, Milliman, Gao and Cheng2004) and Yu et al. (Reference Yu, Berglund, Sandgren and Lambeck2007). The average AMS dating result of the oyster shell in the study site, 7660±96 cal BP (Marine20 calibrated), agrees very well with the age of MWP 1d. Furthermore, many previous studies have shown that sea level rose from 8300 cal BP to 7600 cal BP (Bird et al. Reference Bird, Fifield, Teh, Chang, Shirlaw and Lambeck2007, Reference Bird, Austin, Murster, Fifield, Mojtahid and Sargeant2010; Li et al. Reference Li, Törnqvist, Nevitt and Kohl2012; Smith et al. Reference Smith, Harrison and Jordan2013; Tanabe Reference Tanabe2020). This rising trend clearly appeared in our study site. Although some previous publications indicated that the Holocene high stand of sea level reached the maximum between 5000 and 7000 cal BP (e.g., Zong Reference Zong2004; Bird et al. Reference Bird, Austin, Murster, Fifield, Mojtahid and Sargeant2010; Smith et al. Reference Smith, Harrison and Jordan2013; Tanabe Reference Tanabe2020), we had no marine shells in our study section to support the above scenario. The marine regression in Taipei Basin might occur as early as 7000 cal BP (Teng et al. Reference Teng, Lee, Liew, Sheng-Rong Song and Huan-Chi Liu2004; Chen et al. Reference Chen, Lin, Yang, Fei, Shea, Kung, Lin and Yang2008).

In addition, Chen et al. (Reference Chen, Yang, Chen and Huang2020) studied the marine terrace evolution in the Coastal Range of eastern Taiwan. Based on ¹⁴C ages and shore features, they concluded that the constructive processes of marine transgression during 14,790∼8500 cal BP resulted in a relatively rapid sea-level rise associated with fast shoreline transgression. The sea level reached at the peak of the postglacial marine transgression around 8500 cal BP (Chen et al. Reference Chen, Yang, Chen and Huang2020). Since 8500 cal BP, the sea level started to fall and five marine terraces formed during the regressional sequences. The highest marine terrace (T1) was dated in an age range of 8150±150∼7705 ± 225 cal BP, reflecting the beginning of marine regression earlier than 8150 cal BP. Our dates in Table 1 show (1) the postglacial marine transgression from 8600 cal BP to 7660 cal BP and (2) the sea level reached the peak during 8090∼7660 cal BP. Our dating results of the marine transgression and regression agree with the ages of Chen et al. (Reference Chen, Yang, Chen and Huang2020).

4.4 Estimated Winter Temperature around ∼7660 cal BP

In Section 4.2 above, we have demonstrated the isotopic equilibrium fractionation between the marine shell and its parent water and identified at least four annual cycles in the shell. These giant oysters were able to live at least four years around ∼7660 cal BP. However, such large oysters have not been found in late Holocene in Taiwan. Crassostrea gigas is widely distributed in Japan, Korea, China and successfully cultured in the coast water of European countries (e.g., France, Norway, etc.). According to early studies, Crassostrea gigas is able to survive in a water body with relatively large ranges of salinity and water temperature (Miossec et al. Reference Miossec, Deuff and Goulletquer2009). The cultured oyster in Taiwan can live in water with salinity as low as 9‰ (Seawater is about 33–35‰). Temperature requirement for Crassostrea gigas is above 18^oC for spawning (Mann Reference Mann1979) and above 22^oC for larval development (Arakawa Reference Arakawa1990; Shatkin et al. Reference Shatkin, Shumway and Hawes1997). Here we estimate the winter temperature around ∼7660 cal BP to illustrate temperature influence on the disappearance of the giant Crassostrea gigas in Taiwan.

As we discussed the δ¹⁸O of the shell would have larger influence from the depleted δ¹⁸O of meteorological water in the summer, while the δ¹⁸O value of the winter shell carbonate should have minimal influence of freshwater. If we assume the maximum δ¹⁸O in each year in the oyster shell reflecting isotopic equilibrium under coldest temperature and heaviest δ¹⁸O of water, then we can estimate the winter temperature around ∼7660 cal BP.

In Taipei Basin, cold and dry season resulted in the heaviest δ¹⁸O and δ¹³C in the oyster shell carbonate. During this season, the δ¹⁸O of coastal water had least influence of surface runoff. Thus, we use the heaviest δ¹³C_c in each year to pinpoint the δ¹⁸O_c of cold and dry season. With an assumed δ¹⁸O of water, we can calculate the water temperature. From Figure 4, the maximum δ¹⁸O value in each year are selected as below. Using Eq. (4) and assuming δ¹⁸O_w = –1.7‰ to –1.2‰ (SMOW), we can calculate winter temperature:

• Yr 1, Sample 3, δ¹³C = –0.71‰, δ¹⁸O_c = –1.33‰, T = 15.3^oC to 17.6^oC

• Yr 2, Sample 20, δ¹³C = –0.68‰, δ¹⁸O_c = –2.02‰, T = 18.5^oC to 20.8^oC

• Yr 3, Sample 52, δ¹³C = –0.89‰, δ¹⁸O_c = –2.30‰, T = 19.8^oC to 22.1^oC

• Yr 4, Sample 68, δ¹³C = –0.51‰, δ¹⁸O_c = –2.54‰, T = 20.9^oC to 23.3^oC

Considering the modern sea surface water has a δ¹⁸O_w of 0‰, the δ¹⁸O_w range of –1.7‰ to –1.2‰ for the oyster depositional site with minimal freshwater influence should be reasonable. First of all, the δ¹⁸O_w value of the modern seawater is for open ocean surface water. In general, coastal water has lower salinity due to influence of surface runoff, so that δ¹⁸O_w value of coastal water should be lighter than that of the open ocean surface water. Second, the studied site represents a higher sea level shoreline, which means that the seawater rose due to more freshwater input. Thirdly, many studies show that the climatic conditions were generally warmer and wetter during the early-to-middle Holocene in Taiwan and south China (e.g., Ding et al. Reference Ding, Zheng, Zheng and Kao2020). For wetter climates and higher sea level in the coastal environment, lower salinity and lighter δ¹⁸O_w value are expected. Therefore, the δ¹⁸O_w value of the studied site should be lighter than 0‰. For these reasons, we assume that the δ¹⁸O_w was –1.7‰ to –1.2‰. The calculated winter temperature ranged from 15 to 23^oC. The large shift in winter temperature during the four years may be due to salinity influence on the calculation. The estimated winter temperature around ∼7660 cal BP was warmer than the modern winter temperature in Taipei which is 14–16^oC. The giant oyster lived in ∼7660 cal BP under a warmer condition. Then, the disappearance of the oyster in the late Holocene in Taiwan should not be due to current global warming.