For this study, we investigated a coral drill core (CSM-1), 97 cm in length, that was collected in March 2016 from the Sabana Camaguey Archipelago, northern Cuba, approximately 20 km from the main island (Fig. 1) (Alonso-Hernández et al., 2022). The core was obtained from a scleractinian coral colony of the genus Orbicella faveolata located at approximately 10 m depth in the Cayo Santa María area (79.10° W, 22.66° N). The core was dated via sclerochronology on the basis of radiographic density images, revealing an age of 237 years, ranging from 1778 to 2015 (Alonso-Hernández et al., 2022). The method has an approximate ±1 year uncertainty, which may increase progressively with depth from the top of the coral core (Buddemeier et al., 1974). Additionally, the coral exhibited green growth bands with high Mg contents, possibly due to the incorporation of relatively high levels of organic material into the coral skeleton (Cuny-Guirriec et al., 2019; Alonso-Hernández et al., 2022).

The climate of the region is influenced by the southwestern edge of the high-pressure system over the Atlantic (Fig. S1 in the Supplement). The summer and fall seasons correspond to the rainy season with occasional extreme events, such as hurricanes. Hurricanes typically track west- and northwards approximately once every 20 years, affecting mainly the southeast coast of Cuba (Limia et al., 2003; Terry and Kim, 2015). During the winter season, the hydroclimate tends to be dry, with precipitation rates decreasing from 250 mm per month in summer to as low as 25 mm per month in winter (Vose et al., 1992).

The location of the sample core lies within the Florida Strait (Fig. 1), serving as the outflow path for water masses from the Gulf of Mexico, with an estimated flow rate of 28 Sv (Leaman et al., 1995). As a result, the coral is influenced primarily by waters originating from the Caribbean and Gulf of Mexico, as well as very local continental runoff from the northern part of Cuba and eutrophic waters from mangroves bordering the southern key. An additional major yet distant source of freshwater, the Mississippi River, is located approximately 2500 km away, but its flood plumes can extend hundreds of kilometres into the Atlantic (Hitchcock et al., 1997). This large North American river has an annual discharge rate of 0.015 Sv, which can increase fivefold during major flood events. In addition, the Mississippi carries large volumes of sediment particles, which have halved during the past century due to the creation of dams (Folwell, 1921; Carroll, 1990). The mean δ234U value of the Mississippi waters was assessed to be 335 ‰ ± 110 ‰, including strong seasonal variability (Grzymko et al., 2007).

The separation of uranium from the sample carbonate matrix followed the protocol established by Wefing et al. (2017), with modifications outlined by Kerber et al. (2023). Approximately 50–100 mg of the skeletal aragonite sample underwent ultrasonic cleaning and subsequent dissolution in 7 N HNO₃. To serve as a concentration reference, 100 µL of TriSpike, a mixture containing the synthetic isotopes ²³³U, ²³⁶U and ²²⁹Th, was added. Next, uranium was purified through ion exchange chemistry via U/TEVA resin. To remove Ca and other matrix elements, 300 µL U/TEVA chromatographic ion exchange columns were rinsed three times with 7 N HNO₃. Uranium was then eluted using 3 N and 1 N HCl successively (Horwitz et al., 1992). The sample was dried and redissolved, and the column purification was repeated until the Ca concentration of the final solution was <10 ppm. For MC-ICP-MS measurements, the final uranium fraction was evaporated and dissolved in 1.2 mL of 1 % HNO₃ + 0.05 % HF, with any particulates removed by centrifugation.

Measurements were conducted at the Institute of Environmental Physics in Heidelberg using a multicollector ICP-MS (ThermoFisher Neptune^plus) coupled with an ARIDUS II desolvating nebulizer system and an ESI-SC autosampler. The cup configurations and mounted amplifiers used, as well as the data treatment protocols, are presented in detail in Kerber et al. (2023).

Measurements were conducted via the standard bracketing method with the Harwell-Uraninite 1 (HU-1) standard to ensure measurement stability and correct for machine drift. HU-1 was used as an internal bracketing standard for instrumental normalization, its measured ²³⁴U / ²³⁸U ratio was fixed to a constant reference value during data reduction. This step serves purely as an instrumental correction and does not imply a physical assumption of secular equilibrium. Data evaluation was performed using a Python script for Th/U dating analysis based on Kerber et al. (2025). This script encompasses instrumental background corrections, identification and correction of signal outliers, and adjustment for mass bias, accounting for hydride formation, and addressing tailing and scattering of ²³⁸U. δ234U was calculated via the processed activity ratio of ²³⁴U / ²³⁸U and is expressed in per mil (‰) using the following Eq. (1). 1δ234U(‰)=A234UA238U-1⋅1000 with decay constants of λ238=1.55125×10-10 (Jaffey et al., 1971) and λ234=2.82206×10-6 (Cheng et al., 2013). The updated ²³⁴U half-life (Hu et al., 2025) differs only marginally from that of Cheng et al. (2013) and has a negligible effect on δ234U (<0.1 ‰). All δ234U values are thus reported on an activity-based scale defined by the adopted decay constants. Internal errors were determined as 2σ from each measurement, whereas external errors were determined through repeated measurements of the NBS-CRM-112A (CRM112A) standard and an in-house seawater standard.

The combined procedual replicates yielded a mean variability of 0.35 ‰, with a 2σ reproducibility of 0.54 ‰ (n=6) in δ234U values across replicate groups. The standard deviation from the in-house seawater standard also falls into that range at 0.55 ‰ (2σ, n=11). The external error was determined by repeated measurements of CRM112A in each measurement batch. The analyses resulted in a renormalisation of the mean value of δ234U (CRM112A) to -38.48 ‰ (±0.30 ‰, 2σM=±0.17 ‰, n=16).

Figure 2 shows the δ234U values of CRM112A. Further advances in coral δ234U measurements are described in Greve et al. (2026a).

Figure 3 shows a total of 104 samples that were collected from the 237-year record of the coral, with each sample representing an integration of one year. These annual samples present a mean δ234U value of 145.75 ‰, with a standard deviation of 1.22 ‰. The large data ensemble and small variance contribute to an uncertainty in the mean value of ±0.24 ‰ (2σM, n=104). This uncertainty of the mean is comparable to that obtained for the CRM112A standard (Fig. 2). The measured mean δ234U value of 145.75 ‰ is identical to that of modern seawater (Kipp et al., 2022). Analysis of the small-scale variability within the last 165 years from 1850–2014 reveals a range of 3.32 ‰, from 144.35 ‰ to 147.27 ‰. This variance is 2.5 times greater than that observed in modern seawater (Kipp et al., 2022). Notably, an even higher variability is observed in earlier years, specifically from 1778–1846, during which the δ234U values exhibit a total variance of 8.10 ‰, fluctuating from 143.17 ‰ to 151.27 ‰.

Corals incorporate the uranium isotopic ratio of seawater (δ234U_SW) into their skeleton without measurable fractionation (Robinson et al., 2004b; Wang et al., 2017; Kipp et al., 2022). However, one known factor that can cause fractionation is the postdepositional diagenetic alteration of the coral skeletal material (Delanghe et al., 2002; Robinson et al., 2004b; Wang et al., 2017).

Uranium isotope variations in the Cuban coral are independent of growth parameters (e.g., density) or green banding with high Mg concentration (Fig. S3) (Alonso-Hernández et al., 2022). As Mg / Ca is the proxy most sensitive to skeleton diagenesis, such as calcite or secondary aragonite formation (Allison et al., 2007; Hathorne et al., 2011), the absence of correlation between δ234U and Mg / Ca suggests that diagenesis has not influenced the δ234U values along the core. Studies have shown that secondary aragonite also has a higher U content than primary skeletal aragonite does (Eggins et al., 2005; Allison et al., 2007; Hathorne et al., 2011), which implies a possible correlation between uranium content and isotopic composition. This correlation was not detected in our results (Table S1 and Fig. S3). Furthermore, a diagenetic overprint could result in extraordinarily high δ234U values exceeding 10 ‰ above those of seawater. According to Chutcharavan et al. (2018), a benchmark of 156 ‰ is used to indicate diagenetic alteration of fossil coral material. However, in the coral analysed here, no such elevated values were observed. Consequently, these observations, as well as the excellent agreement of the mean isotopic compositions of corals with those of modern seawater, allow us to conclude that the CSM-1 coral can be used to monitor the U isotopic compositions of local seawater over the past 237 years.

Studies conducted in restricted ocean basins have demonstrated a δ234U offset towards higher values, a shift attributed to the substantial influence of meltwater or river discharge (Andersen et al., 2007; Zhou et al., 2015; Wang et al., 2017; Arendt et al., 2018). Despite the Caribbean being a semi-enclosed basin, it receives a high inflow rate of Atlantic waters, estimated at 28 Sv, which exit the Caribbean and Gulf of Mexico near the sample location (Johns et al., 2002). These substantial throughflow rates support the strong control of seawater on the coral mean δ234U values.

With excellent reproducibility and overall high precision, even subtle variability can be resolved. The variability in seawater δ234U_sw was recently reported to be 1.3 ‰ (Kipp et al., 2022). Under different climate and global weathering conditions, such as during the last sea level low stand and maximum global ice volume, i.e., the Last Glacial Maximum, seawater δ234U_sw decreased systematically worldwide by 6±2 ‰ (Henderson, 2002; Esat and Yokoyama, 2006; Chutcharavan et al., 2018). The major sources of isotopic variability in the surface ocean are continental runoff and submerged groundwater. Continental freshwater has a very large range of δ234U values from as low as 70 ‰ to 1030 ‰, depending on the continental U cycle driven by erosion and the type of regional weathering (Dunk et al., 2002; Li et al., 2018). In the tropics, chemical weathering prevails, reducing the excess leaching of ²³⁴U from the host rock. Moreover, the residence times of freshwater in karstic environments, such as in the Cuban core location, are within days or months to years, resulting in δ234U values that are at the lower end of the freshwater scale (Dunk et al., 2002; Paces et al., 2002; Gonzalez-De Zayas et al., 2013; Iturralde-Vinent et al., 2016). Thus, changes in the local freshwater contribution to the ocean could cause the δ234U_sw values to shift slightly lower than those of seawater. The annual precipitation from 1960–2008 near the coral location has a mean of 482.9 mm yr⁻¹ and varies by approximately 124.5 mm yr⁻¹ (Centella-Artola et al., 2023). Thus, the interannual precipitation variability indicates substantial variations of at least ±25 % in the local freshwater supply.

Over the past 120 years, the coral record has shown considerable variability on decadal timescales, which is approximately 2–3 times greater than that expected in open ocean seawater (Fig. 3) (Andersen et al., 2010; Kipp et al., 2022). Interestingly, the δ234U variations have exhibited a negative correlation with the regional precipitation record since 1960 (r=-0.6, p<0.05, n=21) (Fig. 4) (Centella-Artola et al., 2023).

These subtle variations in δ234U are close to the reproducibility limit of the U isotope measurements but are still statistically noteworthy. The local δ234U_SW value is dependent on the input of terrestrial sourced freshwater, such as river runoff and submarine groundwater discharge. In Cuba, the residence time of precipitated water is relatively short and in the range of days to months due to the karstic terrain (Gonzalez-De Zayas et al., 2013; Iturralde-Vinent et al., 2016). Uranium isotopic compositions in groundwater are influenced by both redox conditions and uranium concentrations. Typically, an inverse relationship exists between groundwater uranium concentration and δ234U; deep, reducing groundwaters with low uranium concentrations tend to show higher δ234U values than oxic, near-surface waters with higher concentrations (Osmond and Cowart, 1976; Asikainen, 1981). Redox conditions also influence uranium mobility and isotope fractionation, with well-oxidizing groundwaters yielding lower activity ratios (Suksi et al., 2006). Catchment-scale denudation further affects these ratios: a U-shaped relationship has been observed, where both low and high denudation rates correspond to elevated δ234U values, while intermediate rates yield lower values (Li et al., 2018). Studies from the Yucatán Peninsula and Tampa Bay, Florida, have reported low δ234U values in groundwater and estuarine waters, which also showed relatively high uranium concentrations (Osmond and Cowart, 2000; Swarzenski and Baskaran, 2007; Schorndorf et al., 2023). The low δ234U values in the coral may therefore reflect shallow groundwater runoff influenced by oxidizing conditions and/or moderate denudation rates in riverine waters in the region. Hence, the freshwater runoff coming from the Carbonate Hinterland (Iturralde-Vinent et al., 2016) and related to precipitation may lead to a moderate decrease of δ234U values in coastal seawater. This process likely explains the anticorrelation of coral δ234U values, where lower δ234U values coincided with high annual precipitation over the last 50 years (Fig. 4). A study of a sediment core situated approximately 100 km east of the analysed coral core revealed a freshwater influence on organic matter by approximately 15 % from 1900–1970 (Alonso-Hernández et al., 2022). During this time, the coral exhibited a mean δ234U of 145.25 ‰, at the lower limit of open ocean seawater, possibly reflecting a persistent but minor local freshwater influence. The influence on δ234U is likely far lower than that observed for organic matter by Alonso-Hernández et al. (2020) because of the lack of high-discharge rivers nearby.

A commonly used proxy for sea surface salinity is stable oxygen isotopes in seawater (δ18O_sw), as they depend on both freshwater influx and evaporation (Leder et al., 1996; Gagan et al., 1998, 2000; Ren et al., 2003). A comparison with reconstructed δ18O_sw values from tropical corals in proximity to the sample location also revealed similarities at annual time scales (Fig. 4) (Table S2) (Smith et al., 2006; Harbott et al., 2023). The δ18O_sw is calculated from the measured coral δ18O values (Smith et al., 2006), which are influenced by seawater δ18O_sw and temperature. By subtracting the temperature component derived from the Sr/Ca record of the same coral, the δ18O_sw at the time of coral growth can be calculated (Ren et al., 2003). Note that the SST, estimated via the Li / Ca ratio (Alonso-Hernández et al., 2022), is not significant correlated with the coral δ234U values (Fig. S2).

For the 19th century, the coral δ234U values aligned with the δ18O record of a stalagmite from western Cuba, interpreted as a proxy for rainfall amount (Fensterer et al., 2012). This alignment falls within the uncertainty of the stalagmite age model (Fig. 4). Before 1860, the stalagmite and coral records diverged from one another, suggesting a potential additional source of δ234U and its variability. Here, we propose that this source is linked to distant freshwater discharge from the North American continent and/or a synchronous reduction in the strength of the Gulf of Mexico current, which is not traced by the hydroclimate record of the stalagmite.

The highest variability in the coral δ234U values occurred between 1778 and 1846, with δ234U values ranging from 144.1 ‰ to 152.5 ‰ . This time interval of high δ234U variability coincides with the end of a period of colder SSTs in the Caribbean during the LIA (Winter et al., 2000; Haase-Schramm et al., 2003; Kilbourne et al., 2008).