Collection

Modern aquatic mollusks were collected live in October of 2020 (n=5), 2021 (n=2), and 2022 (n=4) near the assumed end of the shell growth period for the mollusks. The mollusks were collected from three different sites within Four Mile Creek study area. Sites 1 and 3 are situated within pool-riffle complexes, whereas Site 4 is situated along a bedrock (shale-limestone) reach of the stream (Figure 2; Table S1). Aquatic gastropods (Physidae, possibly Physa acuta) and invasive aquatic clams (Corbicula fluminea) were collected as these were the only taxa of live specimens readily found (Table 1). The aquatic clam specimens were all collected from riffles, whereas the gastropods were collected from slower moving waters (channel margins or pools).

Table 1 Freshwater reservoir effects (FREs) of aquatic mollusks collected live.

^ Physidae: Physa gyrina or Physa acuta.

* FRE = Freshwater Reservoir Effect. The F¹⁴C (May–October) was predicted to be 1.0013 ± 0.002 in 2020, 0.9969 ± 0.002 in 2021, and 0.9926 ± 0.002 in 2022 (Hua et al. Reference Hua2022).

Fossil aquatic mollusk shells and organic material (small pieces of wood or charcoal) were collected as matched pairs from excavated backhoe trenches or river outcrops of paleochannel deposits within the Four Mile Creek valley (Tables 2 and S1). The paleochannel deposits at these sites were all coarse-grained (pebble-sized) and likely riffle-run sequences. The fossil mollusk shell and organic material comprising a matched pair were collected from similar depths within the stratigraphic section. A larger variety of species were identified in the fossil mollusk samples compared to the modern samples, so species sampled were more diverse in the fossil record. In addition to the fossil matched pairs, three additional paleochannel deposits with fossil shells that had been ¹⁴C dated were utilized to demonstrate the impact of the FRE age correction and error on samples (Tables 3 and S1).

Chemical Pretreatment

Both the modern and fossil carbonate shell samples were soaked in 18.2 MΩ water, sonicated briefly (∼3 s to 6 min total) depending on the fragility of the shell, and rinsed to remove any detrital sediment. Samples were then soaked in 10–15 mL of 5.65–6% sodium hypochlorite (NaOCl) at 60°C for >4 hr, rinsed 3 times with 18.2 MΩ water, then dried in a vacuum drying oven at 60°C overnight. Fossil carbonate shell samples were leached with 0.1 N HCl to remove the outer shell material (>20% of shell mass) that can sometimes contain secondary carbonate coatings. Samples were then rinsed 3 times with 18.2 MΩ water and dried in a vacuum drying oven at 60°C overnight. Once modern and fossil carbonate shells were dried, 15–30 mg of shell was selected and sent to Direct AMS for analysis. Modern samples were not acid leached, and no samples were powdered, to reduce the possibility of atmospheric CO₂ interacting with the increased surface area of shell material.

Modern samples of Physidae were ∼5–12 mm in length. The age of the Physidae specimens at the time of collection is unknown and the entire specimen was used for ¹⁴C analysis. The modern Corbicula fluminea samples were approximately 10–20 mm in width and are thought to be <2 years old based on their size. From these modern Corbicula fluminea shells, small fragments (2–4 mm) from recent shell growth from multiple specimens at each locality were combined for ¹⁴C analysis.

Organic samples were manually separated from any soil material through careful selection in the lab. Larger organic pieces were then crushed or broken into smaller pieces to allow better penetration during chemical pretreatment. Organic samples then underwent standard acid, base, acid (ABA) chemical pretreatment with 1 N HCl at 60°C for at least 30 min, and this step was repeated if there was a strong reaction, followed by 1 N NaOH at 60°C for at least 30 min, and this step was repeated until the supernatant was clear or a light tea color, followed by 1 N HCl at 60°C for at least 30 min. Samples were then rinsed with 18.2 MΩ water and decanted until the pH was greater than 4. Finally, 5–10 mg of pretreated material was sent to Direct AMS for analysis (Tenison Reference Tenison2022).

Calculation of Freshwater Reservoir Effects: Modern Mollusks

The modern freshwater reservoir effect (FRE_modern) was calculated for each sample of aquatic mollusks collected live in 2020, 2021, and 2022 by comparing the percent Modern Carbon (pMC) of the aquatic mollusk shells relative to the atmosphere at the time of collection:

(2) $${\rm{FR}}{{\rm{E}}_{{\rm{modern}}}} = 8033*\;\ln \left( {{{{\rm{pM}}{{\rm{C}}_{\left( {{\rm{atm}}} \right)}}} \over {{\rm{pM}}{{\rm{C}}_{\left( {{\rm{mol}}} \right)}}}}} \right)$$

where 8033 is the conventional Libby mean life of ¹⁴C; ${\rm{pM}}{{\rm{C}}_{\left( {{\rm{atm}}} \right)}}$ is the ¹⁴C concentration of the atmosphere at the time of collection for the aquatic mollusks; and ${\rm{pM}}{{\rm{C}}_{\left( {{\rm{mol}}} \right)}}$ is the ¹⁴C concentration of the aquatic mollusk shells.

The ¹⁴C concentration of the atmosphere at the time of sample collection was determined by extrapolation from the 1950–2019 atmospheric ¹⁴C concentration (Hua et al. Reference Hua2022) for Zone 2 as defined by the authors. The atmospheric ¹⁴C content was extrapolated to be 1.0013 ± 0.002, or 100.13 pMC, for 2020 (May–October); 0.9969 ± 0.002, or 99.69 pMC, for 2021 (May–October); and 0.9926 ± 0.002, or 99.26 pMC. FREs were determined separately for each year.

The uncertainties within 1 standard deviation for the FRE_modern of each sample of aquatic mollusk shells collected live were calculated using the following equation (Philippsen Reference Philippsen2013: Eq. 3):

(3) $$\sigma \,of\,FR{E_{modern}} = 8033{\rm{*\;}}\sqrt {{{\left( {{{\Delta {\rm{pM}}{{\rm{C}}_{\left( {{\rm{atm}}} \right)}}} \over {{\rm{pM}}{{\rm{C}}_{\left( {{\rm{atm}}} \right)}}}}} \right)}^2} + {\rm{\;}}{{\left( {{{\Delta {\rm{pM}}{{\rm{C}}_{\left( {{\rm{mol}}} \right)}}} \over {{\rm{pM}}{{\rm{C}}_{\left( {{\rm{mol}}} \right)}}}}} \right)}^2}} $$

where $\Delta {\rm{pM}}{{\rm{C}}_{\left( {{\rm{atm}}} \right)}}$ is the error associated with the ${\rm{pM}}{{\rm{C}}_{\left( {{\rm{atm}}} \right)}}$ ; $\Delta {\rm{pM}}{{\rm{C}}_{\left( {{\rm{mol}}} \right)}}$ is the error associated with the ${\rm{pM}}{{\rm{C}}_{\left( {{\rm{mol}}} \right)}}$ ; and all other variables are used as previously defined.

The FRE_modern and 1 standard deviation of FRE_modern of each year were averaged to get the final ¹⁴C FRE_modern value for each year. A weighted mean was not used for these samples as the errors for individual samples were similar.

Calculation of Freshwater Reservoir Effects: Fossil Mollusks

The freshwater reservoir effect for each set of matched shell-organic fossil pair (FRE_fossil) was calculated by subtracting the conventional ¹⁴C age of the organic sample from the age of the shell sample. The overall fossil freshwater reservoir effect was determined by calculating the weighted mean of the fossil pair reservoir ages (e.g., Yu et al. Reference Yu, Chen, Cheng, Chen and Hou2018). However, before the weighted mean was calculated, age-adjustment using linear regression was used to remove the effect of the ¹⁴C age on the 1σ uncertainties. This was necessary due to the large temporal span of the matched pair dataset. The weighted mean calculation weights ¹⁴C ages with smaller uncertainties greater than ¹⁴C ages with larger uncertainties, so it is necessary to remove this effect as otherwise there is a temporal bias in the data.

A linear regression between each ¹⁴C age and its 1σ uncertainty (x=age, y=1σ) was calculated to determine the strength of correlation (R²=0.84) and the slope (b₁=0.0023) for the relationship (Figure 4). The age-adjustment to remove the effect of age from the 1σ values was then calculated for each fossil ¹⁴C sample using the equation:

(4) $$Age\;Adjusted\;1\sigma = Y - {b_1}*X$$

Figure 4 Plot of the uncalibrated ¹⁴C ages of fossil organic and shell material versus the 1σ uncertainty of the ¹⁴C age from Four Mile Creek.

where Y is the original, non-adjusted 1σ value; b ₁ is the slope from the linear regression model; and X is the ¹⁴C age associated with the original, non-adjusted 1σ value.

The age-adjusted uncertainty was then calculated using the propagation of uncertainty equation for subtraction:

(5) $$Age\;Adjusted\;Paired\;1\sigma = \sqrt {\sigma _A^2 + \sigma _B^2 - 2{\sigma _{AB}}} $$

where ${\sigma _A}$ is the age-adjusted 1σ value for the shell sample; ${\sigma _B}$ is the age-adjusted 1σ value for the organic sample; and ${\sigma _{AB}}$ is the covariance variable, which was not used.

The freshwater reservoir effect (FRE_fossil) and age-adjusted uncertainty for each set of matched pair samples were utilized to calculate the overall combined weighted mean of the five fossil matched pair samples, i.e. the weighted mean of FRE_fossil (Bevington and Robinson Reference Bevington and Robinson2003: Eq. 4.17):

(6) $$Weighted\;Mean\;of\;FR{E_{fossil}} = {\rm\mu} ' = {{\mathop \sum \nolimits_i {{{R_i}} \over {\sigma _i^2}}} \over {\mathop \sum \nolimits_i {1 \over {\sigma _i^2}}}}$$

where R _i is the reservoir effect value from each matched pair; and σ _i is the age adjusted 1σ uncertainty from each matched pair.

The uncertainty associated with the weighted mean of FRE_fossil was calculated by determining the weighted average of the variance of the reservoir effect (Bevington and Robinson Reference Bevington and Robinson2003:Eq. 4.22) and square-rooting the result to get σ (standard deviation):

(7) $$Weighted\;\sigma \;of\;FR{E_{fossil}} = \;\sigma = \sqrt {\left( {{{\sum {w_i}R_i^2} \over {\sum {w_i}}} - \mu {'^2}} \right)*{N \over {\left( {N - 1} \right)}}} $$

where w _i is $1/\sigma _i^2$ , where σ _i is the uncertainty in each R_i value; R _i is the reservoir effect value from each matched pair; µ’ is the weighted mean of FRE_fossil (result of Eq. 6); and N is the sample size.