2.1. Geomorphological mapping

Geomorphological mapping presented here was validated with earlier 1:10,000 field mapping (Dawson Reference Dawson1979), and later updated for Islay (Dawson Reference Dawson1982) using ground survey and aerial photography. The altitudes of all emerged features were initially surveyed to UK Liverpool datum, with all traverses completed with closing errors of no greater than 10 cm. A separate survey between Liverpool and Newlyn Ordnance Survey benchmarks ensured that all altitudes reported here refer to Newlyn datum (OD). The altitudes and GPS locations of those emerged ridge whose gravels were sampled and used to calculate ¹⁰Be exposure ages for dating purposes were also cross-checked against aerial photography and the mapped positions of emerged shoreline features.

The surveyed heights of all emerged marine terrace fragments were plotted on shoreline height-distance diagrams constructed normal to the shoreline uplift isobases, to allow individual shorelines and beach ridge features to be distinguished from each other. The altitudes of all vegetated and unvegetated beach ridges were also surveyed to OD, with the crest altitudes of prominent individual ridges being determined at several points along their length. Where individual ridges formed part of a staircase of ridges, the altitudes of individual swales separating pairs of ridges were determined at multiple points along their lengths to allow ridge and swale profiles to be constructed.

At all sites, the altitude, latitude and longitude were recorded using a handheld Garmin 60Csx GPS. At several sites, two samples of emerged gravels were collected – a single large clast (15 cm b-axis) and 4–5 smaller clasts (5 cm b-axis) – to test whether grain size influences the cosmogenic nuclide concentration. All samples were selected randomly. On the unvegetated emerged beach ridges, only ridges that were too coarse-grained and well-drained to have ever supported the development of covering peat were sampled (Table 1). Where sampling involved moraine or glacifluvial terraces grading to well-defined emerged marine features, the depth of peat overlying the uppermost gravels was measured to allow a shielding factor to be included into the exposure age calculation. Topographic shielding was measured in the field using a compass and clinometer (Table 1). Since clasts will have some amount of nuclide inheritance prior to final deposition dependent on how long they reside in swash zone before final deposition, we estimated the cosmogenic nuclide concentration accumulated prior to deposition by sampling similar size and shape clasts from deep within three abandoned sea caves (two at ~5 m to the rear of the present beach, the other at ~13 m) (Tables 1, 2). After a sample is deposited within a cave, cosmogenic nuclide production is reduced to <0.4 % due to shielding by 15–20 m of overlying rock. Thus, the measured cosmogenic nuclide concentrations in cave clasts provides a minimum constraint on inheritance due to residence time in the swash zone. The clast may have been active in the cave for a period of time while accumulating negligible amounts of ¹⁰Be, and so its ¹⁰Be inventory could underestimate the true amount of inheritance of clasts elsewhere in the system.

Table 1 Grid reference location data, altitude values and shielding parameter values for ¹⁰Be samples used in this study.

* Samples split and processed in separate laboratories; NERC Cosmogenic Isotope Analysis Facility and SUERC Cosmogenic Nuclide Laboratory.

¹ Sample thickness (cm) and shielding factor (in brackets) calculated using a rock density of 2.7 g cm⁻³ and a cosmic-ray attenuation length of 160 g cm⁻².

² Calculated according to Dunne et al. (Reference Dunne, Elmore and Muzikar1999).

³ Correction for shielding by sand (density 1.8 g cm⁻³) and peat (density 0.7 g cm⁻³), assuming peat thickness increased linearly during the last 2 ka of exposure.

Table 2 Dissolved quartz mass values, ⁹Be, ¹⁰Be and exposure age data used in this study

¹ Isotope ratios were normalised to NIST SRM 4325 using ¹⁰Be/⁹Be = 2.79 × 10^–11.

² Atoms of ¹⁰Be in the ⁹Be carrier.

³ Blank corrected ¹⁰Be concentration. Propagated uncertainties include uncertainties in the process blank, carrier mass and counting statistics.

⁴ Calculated with the CRONUS-Earth online calculator (Balco et al. Reference Balco, Stone, Lifton and Dunai2008) version 3 (wrapper: 3.0.2; get_age: 3.0.2; muons: 1A, α = 1; validate: validate_v3_input.m – 3.0; consts: 3.0.4; http://hess.ess.washington.edu/), using the LSDn scaling method. Uncertainties include analytical and production rate uncertainties reported at 1 sigma confidence level.

⁵ Inheritance-adjusted exposure ages calculated after subtracting the mean ¹⁰Be concentration of the lower cave samples from the ¹⁰Be concentration in the beach cobble samples below 14 m above sea level and the mean ¹⁰Be concentration of the upper cave sample from the ¹⁰Be concentration in the beach cobble samples at and above 14 m above sea level.

The quartzite gravel samples were crushed and sieved, and the 250–500 μm fraction was cleaned with aqua regia. Approximately 80 g of the samples was etched multiple times in 2 % hydrofluoric acid to remove the minor amounts of non-quartz contaminants and to remove any meteoric ¹⁰Be that may have adhered to grain surfaces (Kohl & Nishiizumi Reference Kohl and Nishiizumi1992). Quartz purity was assayed and the clean quartz fractions were split between two laboratories to prepare targets for accelerator mass spectrometry. The Jura samples were processed in the Natural Environment Research Council (NERC) Cosmogenic Isotope Analysis Facility, and the Islay samples in the Scottish Universities Enviromental Research Centre (SUERC) Cosmogenic Nuclide Laboratory. Three samples (I04, I06 and I07) were shared to check interlaboratory compatibility. The samples were spiked with between 166 and 285 μg of ⁹Be carrier before being dissolved in 48 % w/w hydrofluoric acid (HF). Matrix contaminants (iron, calcium, titanium) were removed using ion chromatography. Beryllium hydroxide was precipitated, calcined at 900 °C and the final beryllium oxide (BeO) sample mixed with a niobium binder (BeO: Nb = 1:6) before being pressed into target cathodes for Accelerator mass spectrometry (AMS) measurement.

AMS targets were measured at the SUERC AMS Laboratory (Freeman et al. Reference Freeman, Bishop, Bryant, Cook, Dougans, Ertunc, Fallick, Ganeshram, Maten, Naysmith, Schnabel, Scott, Summerfield and Xu2007; Xu et al. Reference Xu, Dougans and Freeman2010). ¹⁰Be/⁹Be ratios (Table 2) were normalised to the NIST4325 standard reference material (¹⁰Be/⁹Be ratio of 2.79 × 10⁻¹¹; Nishiizumi et al. Reference Nishiizumi, Imamura, Caffee, Southon, Finkel and Mcaninch2007). All isotopic ratios were corrected using full chemistry procedural blanks. Background corrections ranged between 3 % and 60 % of the measured AMS ¹⁰Be/⁹Be ratio (Table 2). Final analytical errors in ¹⁰Be concentration (¹⁰Be atom/g-quartz) were derived from the quadrature addition of the uncertainty in the AMS ratio, and a 2 % uncertainty in Be-spike assay resulting in a combined analytical error ranging from 4 % to 5.8 % (Table 2).

¹⁰Be surface exposure ages were calculated using version 3 of the online exposure age calculator described by Balco et al. (Reference Balco, Stone, Lifton and Dunai2008, 2013) and subsequently updated (http://hess.ess.washington.edu/; wrapper: 3.0.2; get_age: 3.0.2; muons: 1A, α = 1; validate: validate_v3_input.m – 3.0; consts: 3.0.4). The ages presented in Table 1 are based on the scaling method (Lifton et al. Reference Lifton, Sato and Dunai2014), and two calibration data sets – the CRONUS Primary Be-10 calibration data set (Borchers et al. Reference Borchers, Marrero, Balco, Caffee, Goehring, Lifton, Nishiizumi, Phillips, Schaefer and Stone2016), and a local ¹⁰Be calibration dataset (LLPR) derived from ¹⁰Be concentrations in samples from boulders on the Younger Dryas terminal moraine at the southern end of Loch Lomond, ~95 km ENE of Jura (Fabel et al. Reference Fabel, Ballantyne and Xu2012). The age of this moraine is independently constrained by radiocarbon dating (MacLeod et al. Reference MacLeod, Palmer, Lowe, Rose, Bryant and Merritt2011). The advantage of using a local calibration data set is that it minimises production rate scaling by inferring production rates from sites that are close in paleomagnetic field characteristics, elevation and age to the unknown-age sites being dated. Using a local calibration data set is, therefore, less subject to production rate scaling uncertainties than extrapolating production rates inferred from a globally distributed set of calibration data to parts of location-age space that are not well represented by the calibration sites (Balco Reference Balco2013). Therefore, the LLPR derived ages and full uncertainties are used here. We do not include atmospheric pressure anomalies and assume no significant erosion of the quartzite gravels during exposure (ɛ = 0 mm a⁻¹), and no prior exposure except in the swash zone, as noted above. The samples on Islay were collected from under a relatively shallow (<37 cm) peat cover. Fulop et al. (Reference Fulop, Bishop, Fabel, Cook, Everest, Schnabel, Codilean and Xu2015) demonstrated that a 15–30-cm-thick peat developed on a moraine ~95 km to the ENE of our sample sites started forming at a maximum of ~2000 years BP. Assuming the same bulk density of 0.5–0.9 g cm⁻³, and linear growth for 2000 years, the maximum peat cover (36.5 cm) reduces cosmogenic nuclide production in the immediately underlying beach gravels by 6–10 % during the last 2000 years of exposure. Although shielding by peat cover only influences the ages by 0.7–1.2 %, it has been included for the peat covered samples.

3.1. Dating constraints

Two cave samples collected at 5 m OD just above the active gravel beaches (Cave 2A and the I08 cave; Tables 1, 2) have similar ¹⁰Be concentrations, with an uncertainty weighted mean of 6022 ± 810 atom g⁻¹. The third cave sample (Cave 1), collected from a higher elevation cave deposit (13 m OD), has a much lower ¹⁰Be concentration (1673 ± 962 atom g⁻¹). The ¹⁰Be concentration in the higher elevation cave sample implies a short residence time in the swash zone prior to deposition (about 400 years or so). This could be due to more rapid RSL lowering at the time of deposition, or deposition in a brief period of cave reactivation during a period of Holocene RSL rise observed elsewhere along the Scottish west coast (Shennan et al. Reference Shennan, Hamilton, Hillier, Hunter, Woodall, Bradley, Milne, Brooks and Bassett2006). Since beach ridges deposited above this sample location are likely to have been deposited during a period of more rapidly falling RSL, we subtract the ¹⁰Be concentration of the higher elevation cave sample from all beach ridge samples at and above 14 m OD, and acknowledge that the 400 years value may well overestimate the residence time over the earlier period of RSL fall. For samples below 14 m OD, we subtract the mean of the ¹⁰Be concentration in the lower two cave samples. The inheritance adjusted exposure ages are used in the text (Table 2).

The timing of deglaciation across SW Jura is well constrained by five ¹⁰Be dates on boulders that comprise part of the Sgriob na Caillich medial moraine (Fig. 6; Table 2) (Ballantyne et al. Reference Ballantyne, Wilson, Gheorgiu and Rodes2014; Small et al. Reference Small, Benetti, Dove, Ballantyne, Fabel, Clark, Gheorghiu, Newall and Sheng2017; Ballantyne & Dawson Reference Ballantyne and Dawson2019). Collectively, the exposure ages for two medial moraine boulder samples collected by Ballantyne et al. (Reference Ballantyne, Wilson, Gheorgiu and Rodes2014) and three boulder samples collected during this study (S1, S2, S3) published in Small et al. (Reference Small, Benetti, Dove, Ballantyne, Fabel, Clark, Gheorghiu, Newall and Sheng2017) yield an arithmetic mean exposure age of 16.5 ± 0.8 ka. Here, we use the ~16.5 ka age as the reference age for deglaciation and assume that all ¹⁰Be exposure ages for the Jura and Islay emerged beach gravels are younger. ¹⁰Be exposure ages of five single largest clasts (>15 cm b-axis) on five of the highest beach ridges uniformly yield ages older than ~16.5 ka, even after the inheritance derived from the cave samples is subtracted. Accordingly, these five sample ages are discounted from this study (Table 2).

Figure 6 Vertical Google Earth image (18.02.22) of Sgriob na Caillich medial moraine, SW Jura. At the seaward end of the hillslope, Loch na Sgrioba separates the moraine from an unvegetated emerged gravel ridge that cuts across the moraine at right angles (see also Fig. 10).

Figure 7 Cross profile of the 55 beach ridge staircase sequence at Loch Aoinidh, W Jura. A shorter profile across a staircase of vegetated beach ridges, A–B is also shown (see Fig. 5). The three ¹⁰Be exposure age determinations for this ridge sequence are also shown.

Figure 8 Cross profile C–D at Shian Bay, seaward from late-glacial marine limit showing the dimensions of the Colonsay Ridge and related ¹⁰Be exposure ages (see also Figs 5, 10; Table 2).

The ages from amalgamated smaller clasts sampled from individual emerged ridges are likely to reflect more surface abrasion than larger clasts due to more frequent movement in the source swash zone. They are thus less likely to exhibit inheritance and so may provide a more accurate constraint on emerged beach age. In addition, there may also be greater local post-depositional shielding of smaller clasts by surrounding larger clasts. Both effects – abrasion and, to a lesser extent, shielding – serve to lower the measured nuclide concentration, reduce the effect of inheritance and provide some degree of confidence in their ages. However, the three samples from Holocene beach ridges do not show the same trend (Table 2) and it may be that the older ages in all samples where the comparison can be made include material that has been remobilised from older beach ridges.

3.2. Chronology

3.2.5. NE Islay

In NE Islay, two ¹⁰Be exposure ages were determined for glacifluvial deposits located within the limits of the Coir Odhar moraine (Fig. 9). Here, two outwash samples are located landward and upslope from a clearly defined late-glacial marine terrace and cliff, the inner edge of which marks the highest level reached by the late-glacial sea in this area (~26.4 m). The two ages for the gravel deposits are 12.7 ± 0.6 ka and 10.8 ± 0.4 ka (Fig. 9; Table 2). In the same area, two dates were obtained from quartzite cobbles on Holocene-emerged beaches at 15 m OD, located below the Main Rock Platform cliff, giving ages of 4.3 ± 0.5 ka and 3.9 ± 0.3 ka (Tables 1, 2).

Figure 9 Geomorphological map of Coir Odhar area, NE Islay, showing partial truncation of outer moraine area by the highest late-glacial emerged marine terrace. The locations of ¹⁰Be exposure samples and ages of alluvial gravels located inside the moraine complex are also shown.