Floods determine river behaviour in time and space. Yet quantitative measures of discharge variability from geological stratigraphy are sparse, even though they are critical to understand landscape sensitivity to past and future environmental change. Here we show how storm-driven river floods in the geologic past can be quantified, using Carboniferous stratigraphy as an exemplar. The geometries of dune cross-sets demonstrate that discharge-driven disequilibrium dynamics dominated fluvial deposition in the Pennant Formation of South Wales. Based on bedform preservation theory, we quantify dune turnover timescales and hence the magnitude and duration of flow variability, showing that rivers were perennial but prone to flashy floods lasting 4–16 h. This disequilibrium bedform preservation is consistent across 4 Ma of stratigraphy, and coincides with facies-based markers of flooding, such as mass-preservation of woody debris. We suggest that it is now possible to quantify climate-driven sedimentation events in the geologic past, and reconstruct discharge variability from the rock record on a uniquely short (daily) timescale, revealing a formation dominated by flashy floods in perennial rivers.
Rivers are the most significant drivers of water and sediment transport across the continents1, and associated flood events play a key role in shaping landscapes, impacting ecosystems, and determining the magnitude, characteristics and locus of sedimentation on the surface of the Earth2,3,4,5,6,7,8,9,10. In principle, fluvial strata, which constitute a physical record of ancient river behaviour, provide a key archive to assess the impacts of flooding in the geologic past. An outstanding research challenge for geoscientists is to decode this archive effectively to evaluate: how, where and when fluvial deposits may record extreme events; the extent to which they can be quantified; and how much they may dominate the stratigraphic record7,11,12,13. This is particularly important as constraints on discharge variability from the geologic record provide a critical tool to understand past impacts of climate variability on river behaviour8,14. To-date qualitative insights into flow variability have largely been extracted from the rock record using facies analysis, including observations of supercritical flow indicators10,15,16,17,18,19. However, recent advances in our understanding of fluvial bedform dynamics in disequilibrium conditions raise the possibility of gaining quantitative insights into flow variability in ancient rivers13,20; when used together with sedimentary observations, these advances permit reconstruction of flood magnitudes and variability directly from fluvial stratigraphy.
The approach begins with the fundamental morphometrics of fluvial bedforms20,21,22,23,24,25,26,27,28, in particular dune-scale cross-strata, sub-critical bedforms which are ubiquitous in most ancient river deposits20,21,24,25,26. Cross-sets are preserved when dunes are not fully reworked by the prevailing flow, allowing the remaining bedform to become buried (Fig. 1). The “flood hypothesis” of bedform preservation13 states that enhanced bedform preservation occurs during floods (especially those with flashy hydrographs) when the formative flood duration, Tf, is less than the timescale to rework a bedform, known as the turnover timescale, Tt (Fig. 1, see Table 1 for definitions). This is due to hysteresis in the adjustment of bedforms to changing flow conditions, meaning that when Tf < Tt, bedforms do not have time to adjust in form to reach equilibrium with the prevailing flow. This key signal of flow variability can be extracted from dune-scale cross-strata using measurements of the distribution of heights (hxs) of preserved dune-scale cross-sets to calculate their coefficient of variation, CV13. In steady-state flow conditions, which may occur when Tf ≥ Tt, the spread in cross-set heights in preserved stratigraphy is high: the CV is expected to be in the range 0.88 ± 0.3 because existing theory and experiments demonstrate that bedform migration across random bed topography with low angles of climb, in equilibrium with the prevailing flow, results in low bedform preservation and high CV (Fig. 1a)13,21,22,23. In contrast, when preservation occurs in disequilibrium conditions, which may arise due to flooding, the opposite is true (Fig. 1b). In this case, limited reworking of sediment within a dune results in lower CV26, with a greater proportion of the original dune preserved in stratigraphy. Disequilibrium bedform dynamics have been observed experimentally29, and recently dune cross-set CV has been used to indicate disequilibrium dynamics in stratigraphy20,30. However, flow variability is not the only origin of disequilibrium conditions: enhanced bedform preservation in disequilibrium conditions can also be caused by the presence of morphodynamic hierarchy, such as dunes migrating atop barforms13,20,26. Disequilibrium bedform dynamics caused by flow variability can therefore be difficult to definitively identify in the rock record, due to lack of independent evidence of variable discharge.
Here, we test the flood hypothesis for enhanced bedform preservation in a location where unambiguous evidence of variable discharge conditions, including mass preservation of woody debris, can be combined with quantitative bedform and palaeohydrologic analyses. Therefore, we link for the first time bedform disequilibrium with stratigraphic evidence of flooding. In doing so, we demonstrate how sophisticated insights into water fluxes, climate and discharge variability can now be quantified for the geological past from stratigraphic data.
Results and discussion
We focus on the Pennant Formation of South Wales, UK (Fig. 2), a 1.3 km thick succession of Upper Carboniferous (312.4–308 Ma, corresponding to the Moscovian age, or Bolsovian-Asturian substages) fluvial strata31,32. The five members of the formation (Llynfi, Rhondda, Brithdir, Hughes, Swansea) were deposited when South Wales was located near the equator, at a palaeolatitude of between 2.7◦N and 3.0◦S33. The formation is the product of rivers that drained the Variscan Mountains, flowing north-west28 across foreland basin floodplains34,35. The regional climate was warm and wet, with precipitation rates averaging 1.5–5 mm/day33,36,37. Individual catchment lengths and drainage areas reconstructed for multiple rivers in the Pennant system, based on outcrops in South Wales, average 130–200 km and ~4500−9500 km2, respectively28,38,39. Rapid sedimentation in a foreland basin setting (up to 340 m/Ma)28,34 resulted in a high-fidelity and high-temporal resolution record of fluvial processes across a c. 4 myr time period31,34,35.
The formation comprises bedded, channelised sandstone bodies, with well-preserved accretion sets and abundant dune-scale cross-bedding28. Separating the cliff-forming sandstone bodies are slope-forming fine-grained sediments representing floodplain deposition35. They contain abundant and well-documented coals34,40 indicating river migration across a forested, swampy foreland, characterised by high retention of surface water. As a result, the Pennant Formation has classically been divided into 3 main facies associations: fluvial channel, floodplain and mire34,35 (Supplementary Information 3). These characteristics are consistent with single-threaded or anastomosing rivers consisting of a few threads, which have been interpreted as showing perennial discharge regimes15,28,31,34,35,40,41. Qualitative observations of heterolithic deposits at channel margins (Supplementary Information 3) and the abundance of in-channel plant debris strongly point to the occurrence of flood events31,34, some of which entrained floodplain vegetation. These observations are consistent with the hypothesis in the thesis of Jones34, based on extensive facies analysis across South Wales, that the Pennant Formation contains evidence of variable discharge conditions. We therefore exploit this setting, including classical descriptions of facies associations34,35 as well as recent reconstructions of palaeo-rivers within the Pennant Formation28 to compare numerical and facies evidence of disequilibrium flow conditions related to floods, and in doing so, quantify discharge variability in a Carboniferous river system for the first time.
Quantitative analysis of flood stratigraphy
We first consider whether this formation contains quantitative evidence of disequilibrium bedform preservation, consistent with the flood hypothesis13, and if so, what this implies about flood durations. We then place these results in the context of facies-based evidence of floods in the form of woody debris accumulations.
The mean cross-set height, hxs, across the Pennant Formation was 0.12 m, with a median of 0.12 m and a standard deviation of 0.06 m (Fig. 3a). Values of maximum height measured within each cross-set average 0.19 m, and the median grain-size in the formation is 0.38 ± 0.06 mm (IQR), i.e., medium-grade sand. Two-tailed Kolmogorov–Smirnov (KS) tests show that the hxs distributions of the Pennant Formation’s five Members are similar with 99.9% confidence (Supplementary Information S3h), and Fig. 3a shows that the distributions of mean hxs follow a similar pattern across all members. This analysis indicates that measured samples of cross-sets have similar height distributions at member and formation level.
Results also show statistically similar low CV distributions for all members with 90% confidence with median CV values spanning 0.36–0.42 (Fig. 3b). The median CV in the Pennant Formation is 0.40 and the mean is 0.41. We emphasize that these CV values are significantly lower than the theoretical value expected for steady-state bedform preservation of CV = 0.88 ± 0.3 (Fig. 4c)13,21,22,23. Indeed, 99.6% of cross-sets have CV below 0.88, and 96.7% have CV below 0.58 (0.88–0.3), suggesting that ~97% of dunes measured were preserved in disequilibrium with the prevailing flow at the time of deposition. These findings are consistent with theory and observations of disequilibrium (enhanced) bedform preservation13,20,25,26 (Fig. 3), and this signal of variable discharge conditions is consistent across all members of the Pennant Formation (Fig. 3c).
These data can be used to quantify bedform turnover timescales, Tt, and prevailing flood durations, Tf. We first explore what our data imply assuming a minimum theoretical bedform preservation ratio (hxs/hd, see Table 1) of 0.313,20,26 to obtain estimates of the maximum durations of Tf and Tt (Fig. 4a). Then we evaluate the sensitivity of these results to higher bedform preservation ratios.
Tt calculations (Eq. 3) suggest dunes required a median of 3.2 days to be fully reworked by flow; similar results are recovered for all members of the Pennant Formation (Fig. 4a). Bedform theory and empirical observations13 demonstrate dunes preserved in the falling limbs of flashy floods, in disequilibrium with the prevailing flow, have a bedform disequilibrium number, T*, of <1, representing the ratio of Tf and Tt. When the CV of cross-set height is as low as 0.4, as our calculations show, T* might be as low as 0.113,20. This means given the average Tt of 3.2 days, Tf is reconstructed as ~8 hours (0.32 days). Flashy floods, which can be defined as having abrupt flow deceleration and T* ≪ 113 are often associated with intense precipitation lasting less than half a day42 and can have almost symmetrical hydrographs15, so the total length of the average flood preserved in the Pennant Formation can be approximated as 16 h. To our knowledge this is the first time flood durations have been estimated for Carboniferous river systems. Based on paleohydrological calculations (Table 1 and ‘Methods’) we recover median bankfull discharge in individual channel threads as 140–160 m3/s, and considering previous reconstructions of several (i.e., 2–4) anastomosing threads28 this could be as high as 640 m3/s.
Because disequilibrium (enhanced) bedform preservation due to flooding is indicated by our CV values (Fig. 3), the estimates presented in Fig. 4a are conservative maxima. The bedform preservation ratio, hxs/hd, is the ratio of measured mean cross-set height to estimated mean original dune height, and is influenced by the equilibrium dynamics of flow. Steady-state dynamics are implicit in many bedform scaling relations22, assuming hxs/hd = 0.3, however plausible non-steady state values of hxs/hd may be as great as 0.6, based on theory and experiments which show enhanced preservation during the falling limbs of flashy floods13,20. As hxs/hd increases from 0.3 to 0.6 for a known hxs (0.12 m on average for the Pennant Formation), the median Tt reduces from 3.2 days to 0.9 days (Fig. 5a). This means that while the falling limb of floods may be as long as 8 h assuming a ‘typical’ bedform preservation ratio of 0.3, Tf could be as short as 2 h assuming a bedform preservation ratio as large as 0.6. Durations are unlikely to be shorter than this as we do not see complete dunes preserved. The shaded regions in Fig. 5 illustrate the plausible range in palaeohydrologic parameters, with bankfull discharges for individual channels reconstructed from cross-set heights as between 88 and 160 m3/s (Fig. 5b). These could represent lower limits on bankfull discharge, with rare gravel-grade dunes suggesting discharges a factor of 1.5–2 greater than the sand fraction in the Pennant Formation28, although independent architectural constraints on channel morphology result in comparable discharge reconstructions, with a median of 140 m3/s per channel28.
Finally, we note that the flow intermittency factor of a river, If, can be used to obtain quantitative contextual information on annual flow regime, and can be visualised as the proportion of the year a river would need to maintain bankfull discharge conditions to equal an estimate of the yearly water budget. For ancient fluvial systems such as the Pennant Formation, If can be estimated using published constraints on palaeogeographic and palaeo-precipitation rates (see ‘Methods’) to obtain a plausible annual water budget, and we exploit these to obtain first-order estimates of water flow intermittency factors for Pennant rivers. By comparing these constraints on mean annual discharge to our bankfull estimates (Fig. 4b), we estimate If = 0.17–0.44 (see ‘Methods’). This suggests that if the rivers of the Pennant Formation sustained bankfull conditions they could complete annual discharge in 62–160 days, which is consistent with perennial river systems, as discussed further below.
Facies-based evidence for flooding
The quantitative analysis above, based on bedform theory, indicates that sediment deposition in the palaeo-rivers of the Variscan Foreland was controlled by disequilibrium bedform dynamics, which we relate to floods that had durations up to 16 h. But to what extent are these quantitative conclusions supported by facies-based observations? Fluvial channel facies in the Pennant Formation can be divided into three major lithofacies (conglomerate, sandstone and heterolithic) after Jones and Hartley35 which have been well-documented since the 1960s, and for which variable discharge conditions have been qualitatively suggested. We do not repeat these analyses but focus on the conglomerate lithofacies, first described by Jones and Hartley35 as conglomerates in which the clasts often comprise plant debris. We present new observations of woody debris, below, which we link to our quantitative approach. Further contextual details on facies that have been observed in the Pennant Formation34 are presented in Supplementary Information 3.
Dense accumulations of fossilised plant materials, or “plant conglomerates”35, are abundant and well-documented in the Pennant Formation. Plant fossils are preserved as a mixture of coalified compactions, compressions, as casts with well-preserved surface features, and occasional perimineralization. Identifiable fossils are mostly genus Calamites and Lepidodendron. Calamites, a genus of arborescent Equisetales (horsetails), grew in rapidly shifting and aggrading riparian settings43, proximal to channels, inhabiting levees, bars, and overhanging river channels. Calamites grew to its full height within 2 seasons, whereas Lepidodendron grew further from river channels, requiring more established substrate before reaching ~35 m in height and developing woody branches after 5–10 years of growth31,41,44,45. Although ubiquitous throughout the Pennant Formation, the densest plant accumulations (Fig. 6), historically referred to as “conglomerates”35 are observed in this study at 6 localities (Supplementary Information S3), but are documented throughout the formation31,34,35,41,46. They are characterised by large volumes of woody debris preserved at the bases of channel packages and accretion sets (Supplementary Fig. S2), only containing gravel-grade lithic clasts in a few rare instances. Conglomeratic debris beds are 0.25–3 m in thickness, and contain mostly Lepidodendron preserved as casts and compactions at varied stages of surface degradation. Fossils overlap and interlock, and occur in a matrix of highly macerated vegetation mixed with sand and organic-rich mud and silt. The conglomerate lithofacies contains a higher proportion of large debris fossils than the sandstone lithofacies (Fig. 6, Supplementary Information 3), and associated sediment is often poorly organised, but may contain a range of bedforms, from high-angle dune-scale cross stratification to upper plane-bed lamination. No in situ plant fossils (e.g., stumps) are observed.
The maximum length of woody debris we observed is 250 cm, with a median of 13 cm (Fig. 6f). The maximum reconstructed cylindrical volume of plant debris is 95,000 cm3 with a median of 237 cm3. While these woody debris accumulations have not before been linked with palaeohydrological observations, KS tests (see ‘Methods’ and S3, 4) demonstrate that dune cross-sets, where found in close association with woody debris in the conglomerate lithofacies, have an even lower CV than those documented elsewhere (Fig. 3) with 90% confidence. This shows that, whilst bedform preservation for sandy channel deposits is enhanced consistently at formation level, even greater enhancement is observed where debris-dominated facies associations are present. These data suggest that disequilibrium bedform preservation prevailed throughout the Pennant Formation and was particularly enhanced in flow associated with preservation of woody debris.
We interpret the observed debris conglomerates as log-jam deposits, generated by floods. First, the characteristics of the log-jam deposits observed here are similar to modern and ancient examples10,16,46,47,48,49, where debris orientation, sorting, and palaeobiology are comparable. Once plant material is in the river channel, log-jams can occur due to obstacles or flow separation between large objects such as bars or entire tree trunks50. Therefore, secondly, the formation of log-jams in the palaeo-rivers of the Variscan foreland is feasible due to the known presence of barforms and because Lepidodendron grew large enough to act as key members in log-jams43. Further, log-jams are known to have been frequent and diverse in Carboniferous rainforests43, and in ancient alluvial systems4,10,16,49,50. Moreover, The classic observations of Jones34 document woody debris up to 10 m long, suggesting the presence of material large enough to generate a significant obstruction in the channel43. We suggest, therefore, that the deposits observed represent transport jams as described by Gibling et al.43 and we link these events to the discharge variability documented using our quantitative bedform approach.
Implications of bedform disequilibrium
Based on our quantitative bedform analysis, we document a CV of dune-scale cross-set height distributions in the Pennant Formation of 0.40 ± 0.07 (IQR) found throughout the unit (Fig. 3), which demonstrates that stratigraphy in the Pennant Formation preserves non-steady-state bedform dynamics. This is coupled with clear evidence for variable discharge conditions and the occurrence of floods. We show that 97% of observed cross-sets (N = 271) possess low CV (classified as ≤0.88 ± 0.3) consistent with enhanced dune preservation, and this appears to be the norm across up to 1.3 km of stratigraphy, a significant interval representing 4 Ma of deposition. Enhanced bedform preservation is being increasingly recognised in ancient fluvial systems20,30. Uniquely, our work in the Pennant Formation also links this signature to facies-based observations of flood-driven woody debris entrainment and deposition, and we interpret these disequilibrium conditions to likely reflect the prevailing flow during the falling limbs of floods. Based on bedform turnover timescale calculations, we reconstructed falling limb flood durations (Tf) of 2–8 h, suggesting that relatively flashy floods had a total duration 4–16 h, with bankfull discharges of 140–160 m3/s per channel thread. This duration is consistent with published estimates of catchment size, with flow estimated to propagate through a catchment typical of the outcrops studied in 12–40 h28 (Supplementary Information 2). This is the first time that dune-scale bedform-based analyses of variable discharge conditions have been used to constrain flood durations in the ancient past. In conjunction with facies-based approaches, discussed below, this methodology provides a new way to quantify the magnitude and duration of floods in the stratigraphic record.
Discussion of woody debris
We present evidence of log-jams and woody debris accumulations throughout the Pennant Formation, and we interpret these to have formed during floods, such as those that we quantify above. Rapid sedimentation and high-fidelity surface preservation of fossils in the conglomerate lithofacies, as well as their poor sorting and significant volume, speaks to high-magnitude storm-driven events. Plant accumulations including woody and peaty debris in accretion packages in other facies associations35 (e.g., the sandstone lithofacies, Supplementary Information 3) can also be explained by high-discharge events. These deposits are ubiquitous in the formation and occur in every member, implying deposition in rivers that were prone to discharge variability in a tropical ever-wet rainforest setting.
While plant material can be recruited into river channels by direct abscission, wind-blown input, and undercutting and collapse of the banks51, we suggest that the woody debris conglomerates present strong evidence of overbank flooding: firstly, the volume and density of many of the conglomeratic beds speak to the rapid recruitment of vegetation from large areas of forested floodplain, especially when considering estimates on Carboniferous tree spacing52,53. Secondly, the abundance of comminuted plant material gives insight into formation mechanism, implying maceration during transport, or prior decomposition on the forest floor. When found amongst large samples of woody debris this either requires flood water to transport rotted vegetation from the floodplain or to macerate fresh vegetation in high-energy flow. Further, these deposits are poorly sorted, with the lengths of measurable debris fossils in the 5−95% range being 0.03–1 m. It is unlikely this could be caused by gradual build-up of logs on/adjacent to a barform, and instead suggests rapid accumulation in a high energy setting. Third, the high quality of preservation of many fossils suggests rapid sedimentation, occurring predominantly during high and falling stages of flood events50.
Incremental floodplain cannibalisation is not favoured in this interpretation of log-jam debris recruitment not only due to the large volume of the deposits, but also due to the disproportionate absence of fossilised plant roots. If vegetation was recruited by bank collapse, this would place the entire tree, including roots, into the channel. However, these deposits do not contain roots, but mostly branches of Lepidodendron, which must have been collected by overbank flow where these organisms grew. Lepidodendron grew relatively far from river channels, requiring at least 5–10 years of stable growth before generating branches51,54, so it is unlikely that large volumes of branch material would have been recruited directly from the river bank. Furthermore, the absence of any in situ tree fossils suggests woody material was not sourced from plants living within the channel, consistent with palaeohydrologic reconstructions of these systems28 that show they were perennial. Palaeohydrological reconstructions show rivers channels were no wider than 200 m. Bank collapse on a scale large enough to incorporate enough of the floodplain into the channel to potentially cause a log-jam is therefore unlikely, and only occurs in the largest rivers today55,56,57,58. Even if undercutting and bank collapse were an additional mechanism, this process occurs especially during floods43,50,59.
Together, our quantitative analyses, coupled with our observations of log-jam deposits, show that disequilibrium conditions related to variable discharge and flooding are ubiquitous across 1.3 km of Welsh Carboniferous stratigraphy. Our data are unique in the ability to link qualitative facies indicators of potential discharge variability to quantitative evidence of enhanced bedform preservation. Where woody debris is found in the densest concentrations (i.e., log-jam deposits in the conglomerate lithofacies and plant-rich beds in the sandstone lithofacies), it coincides with lower cross-set CV to 90% confidence (Fig. 3b). Almost all cross-sets measured across the formation indicate disequilibrium preservation, interpreted to be driven by flashy floods, however, dunes associated with debris-transporting flood events are preserved with the lowest CV values. This demonstrates that debris accumulations record the same high-discharge events that are recorded by the disequilibrium preservation of dunes in ancient rivers, establishing dune cross-set CV as a robust indicator of discharge variability. This also highlights the critical importance of uniting facies-based evidence of variable discharge conditions with quantitative insights from bedform theory.
Interpretation of discharge regimes
A number of indicators have been developed to identify systems with high discharge variability in the geologic record10,15,16,60, including Froude transcritical or supercritical structures and evidence of long periods free of discharge (e.g., in situ vegetation), often associated with strong seasonal precipitation patterns. However, facies evidence indicates that rivers had persistent discharge61 rather than strongly seasonal or highly intermittent discharge patterns10,15,16,28,34,35, consistent with our quantitative calculations. In the Pennant Formation transcritical- or supercritical sedimentary structures have been rarely observed, as sedimentation is dominated by subcritical dune bedforms alongside occasional upper plane-bed lamination in close association with woody debris. Moreover, supercritical conditions are not expected in these rivers given their reconstructed morphodynamics and flow velocities (see also Supplementary Information 3). The abundance and diversity of plants in upper Carboniferous coal forests implies that vegetation would colonise the river channel if long periods free of discharge occurred. However, no in situ vegetation has been observed in this formation, leading to the inference that rivers were perennial15,16. Moreover, the Pennant Formation’s fluvial channel facies contains abundant well-developed accretion sets, characteristic of perennial river deposits, as opposed to streams supplied largely by seasonal precipitation15,17,18,62,63,64,65. Serinaldi et al.66 also note that monsoonal regimes are typically characterized by sustained floods (5–25 days). Tt calculations, on the other hand, yield flood durations less than 1 day, which is inconsistent with models of subtropical systems, but consistent with flashy, precipitation- (storm-) driven floods in a perennial system. Further, Leary and Ganti13 found that sustained floods may have sufficiently long recession periods that bedforms reach equilibrium with the flow, in contrast with our results showing disequilibrium bedform preservation. All of these factors point towards a system not dominated by strong seasonality, but instead by storm precipitation on a daily timescale.
Finally, estimates of the water flux intermittency factor, If, reconstructed for the Pennant Formation of 0.17 to 0.44 (see ‘Methods’) are not consistent with ephemeral discharge rivers20,27 but suggest the total annual water budget could be completed if bankfull conditions were sustained for around 1/3 of the year. The dominant grain-size, abundance of vegetation and perhumid climate is also potentially analogous to fluvial-dominated channels of the Mahakan Delta, Indonesia67. The intermittency factors we obtain are therefore broadly characteristic of perennial but variable flow in sand-bedded rivers68.
One final implication of the low CV values for fluvial cross-sets documented in this study is elevated bedform preservation ratios. The palaeohydrological and facies-based results of this study show the “unusual completeness”11 of the strata (in terms of bedform preservation) is likely due to discharge variability related to flooding13,15,28. This conclusion raises important questions about preservation of flow events in the stratigraphic record11,21. Variscan tectonics and associated accommodation generation undoubtedly contributed to the high rates of alluvial aggradation, as well as the preservation of woody debris4. However, given that almost the entire Pennant Formation contains the signature of disequilibrium bedform preservation, steady-state flow conditions appear to be disproportionately underrepresented. One explanation is that river sediment may behave in a state of disequilibrium more often than not due to the known hysteresis between flow conditions and adjusting dune morphology69. If this is true for the Pennant Formation, then this study offers further evidence that ancient rivers should not be treated as binary—either at steady-state or non-steady-state—but that disequilibrium bedform preservation is occurring regularly due to constant discharge variability.
However, given that we have extensive facies-based evidence for flood discharge conditions, our observations (e.g., Fig. 6) provide clear evidence for significant changes in flow conditions. Floods occurred over brief timescales, as we quantify above, therefore leaving perennial flow states to dominate the annual hydrograph, but evidently not the sedimentary record. In this scenario, the finding that 97% of observed cross-sets show CV values consistent with flood-driven discharge variability implies the exclusion of the vast majority of geologic time from the depositional record11. This study provides bedform-based evidence of disequilibrium flow conditions driven by flashy, storm-driven flooding, which we are able to link unambiguously with independent evidence of ancient floods for the first time, and adds to growing evidence that many systems may dominantly preserve sediment under conditions of bedform disequilibrium20,29,30. Consequently, we are able to reconstruct the signature of discharge variability on a daily timescale and our work illustrates how quantitative bedform analyses increasingly enable flood characteristics to be recovered from the rock record.
Taken together, these results demonstrate vividly how a careful combination of bedform and facies-based approaches can unlock fresh insights into Earth’s sedimentary systems and surface processes. This study represents the first quantitative investigation of bedform dynamics in Carboniferous palaeo-rivers and show how preserved bedforms can be used to extract signals of ancient discharge variability from fluvial stratigraphy. Palaeohydrological reconstructions reveal that the sand-bedded perennial palaeo-rivers in the Variscan foreland of the UK were significantly influenced by precipitation-driven flood variability, the signature of which dominated stratigraphy over a period of 4 Ma. Floods had duration 4–16 h, causing enhanced preservation of dunes and recruiting large volumes of woody debris, sometimes as log-jams, and floods had discharge magnitudes of 140–160 m3/s in individual channel threads.
Primary data were collected in Autumn 2021 and Spring 2022 across 20 sites in the South Wales and Pembrokeshire Coalfields (Fig. 2; Supplementary Data 1, 2) from the five Members of the Pennant Formation. Primary data included cross-set height distributions (Fig. 7a, b), the geometries of various architectural elements (Fig. 7c, d), grain-size, and observations of flood facies (Fig. 6).
Cross-set height distributions were collected following the sampling strategy of Lyster et al.20, Ganti et al.24 and are explained in detail by Wood et al.28. Cross-set bounding surfaces were first identified, and cross-set height was measured (to a precision of ±5 mm) at regular intervals, with between 7 and 61 measurements per cross-set. We used cross-bed dip directions, palaeoflow estimates (both regional and local) and 3D outcrops with more than one exposed plane to ensure we sampled the cross-set parallel to the migration direction. A total of 4390 height measurements were taken across 271 cross-sets. Measurements of maximum cross-set height (with sample size N = 1735) were also collected separately. Relationships were established between the maximum and mean height from the recorded distributions (Supplementary Information 2), allowing estimation of mean hxs from cross-sets where only the maximum value was measured. This increased the sample size of mean cross-set heights to N = 6125. For each observed cross-set, the grain-size of the sediment was also established (see Supplementary Information 2 for more detail on methods). The geometries of architectural elements, including the dimensions of channel and accretion packages, were measured using a Haglof Laser Geo laser range finder to a precision of ±5 cm. Data on woody debris fossils were collected by measuring their long and short axis to a precision of ±5 mm, and their location within the stratigraphic architecture was recorded.
Fundamental to the “flood hypothesis”26 is the detection of enhanced bedform preservation in fluvial strata. Measured hxs distributions were used to calculate the coefficient of variation of cross-set height, CV, where:
in which σ is the standard deviation and μ is the mean of the cross-set heights within a single cross-set. The CV reflects the preservation of the original dune, and therefore the equilibrium dynamics of flow: a CV of 0.88 is expected in equilibrium conditions21,22,23 and CV decreases as bedform preservation becomes enhanced (Fig. 1).
where hd is the mean original dune height, and hxs is the mean cross-set height. Values of hd were then used in an array of further palaeohydrological calculations to build a complete picture of river morphodynamics. See Supplementary Information 2 for further detail on palaeohydrologic calculations and uncertainty.
To estimate uncertainty, Monte Carlo uncertainty propagation was used to generate a distribution of values for hd that reflects the true spread of the data, following previous hydrological studies20,27,70. For Eq. 2, 106 random samples were generated between bounds defined by μ − σ and μ + σ where μ is the mean and σ is one standard deviation. This was repeated for all formulae with a stated error, and propagated uncertainties were carried through.
Bedform turnover timescale (Tt) is defined as the time to displace the volume per unit width of sediment in a bedform, i.e., the length of time required for a bedform to be completely reworked by the prevailing flow12. This parameter is used to indicate whether bedforms evolved in equilibrium with the prevailing flow, as a Tt that is greater than the duration of the prevailing flow, Tf, implies a hysteresis that results in limited reworking of the bedform. This study determines Tt using the methods of Myrow et al.12 and Martin and Jerolmack69, in which:
where λ is dune wavelength (approximated as λ = 7.3H, where H is the formative flow depth), the shape factor β ≈ 0.55 and qb is the unit bedload flux (See Supplementary Information 2). Myrow et al.12 define a dimensionless bedform disequilibrium number, T∗:
Using data compiled from experiments and modern rivers by Leary and Ganti13, it is possible to establish plausible values of T∗ for calculated values of CV. Their results imply that dunes preserved in disequilibrium with falling-limb flood discharge lead to cross-sets low values of CV and T∗. Based on their data, we take 0.1 as a plausible value of T∗, meaning Tf = 0.1Tt.
The flow intermittency factor, If, is defined as the fraction of the total time in which bankfull flow would accomplish the same amount of water discharge as the real hydrograph68:
where ΣQ(t) is the sum of the time-dependent discharge, Qbf is the discharge at bankfull conditions and Σt is the timespan. Flow intermittency requires estimation of a yearly water budget, and this necessitates a range of assumptions. Based on atmospheric general circulation models33,36, the palaeo-precipitation rate was estimated as between 1.5 and 2.5 mm/day, and catchment area has been estimated by Wood et al.28 as 4500−9500 km2, based on catchment scaling relationships39 and previously published palaeogeographic constraints32. Multiplying mean annual precipitation rates by the catchment area gives an estimate of the discharge (m2/s) supplied to the catchment, once modified to account for infiltration and evaporation of 20%71 (Supplementary Information 2).
Two-tailed Kolomogorov-Smirnov (KS) tests were performed in order to test the similarity of datasets, with the null hypothesis that the tested datasets have similar distributions. Firstly, the hxs data collected in each member were tested against each other and against the data collected from the Pennant Formation as a whole. Secondly, the same tests were conducted for the cross-set CV. Finally, the CV values of cross-sets associated with woody debris were tested against those not associated with debris. See S2h, S2i and S2j in Supplementary Data 2, respectively, for these statistical tests.
Milliman, J. D. & Meade, R. H. Worldwide delivery of river sediment to the oceans. Geology 91, 1–21 (1983).
Baker, V. R., Kochel, R. C. & Patton, P. C. Flood Geomorphology (Wiley-Interscience, 1988).
Parsons, M., McLoughlin, C. A., Kotschy, K. A., Rogers, K. H. & Rountree, M. W. The effects of extreme floods on the biophysical heterogeneity of river landscapes. Front. Ecol. Environ. 3, 487–494 (2009).
Trümper, S. et al. Late Palaeozoic red beds elucidate fluvial architectures preserving large woody debris in the seasonal tropics of central Pangaea. Sedimentology 67, 1973–2012 (2020).
Palik, B. et al. Geomorphic variation in riparian tree mortality and stream coarse woody debris recruitment from record flooding in a coastal plain stream. Écoscience 5, 551–560 (2016).
Comiti, F., Lucía, A. & Rickenmann, D. Large wood recruitment and transport during large floods: a review. Geomorphology 269, 23–39 (2016).
Whittaker, A. C. et al. in EGU General Assembly, Vienna, Austria, 23–27 May 2022, EGU-6440 (2022).
Watkins, S. E. et al. Are landscapes buffered to high-frequency climate change? A comparison of sediment fluxes and depositional volumes in the Corinth Rift, central Greece, over the past 130 k.y. GSA Bull. 131, 372–388 (2018).
Romans, B. W., Castelltort, S., Covault, J. A., Fildani, A. & Walsh, J. P. Environmental signal propagation in sedimentary systems across timescales. Earth Sci. Rev. 153, 7–29 (2016).
Fielding, C. R., Alexander, J. & Allen, J. P. The role of discharge variability in the formation and preservation of alluvial sediment bodies. Sediment Geol. 365, 1–20 (2018).
Paola, C., Ganti, V., Mohrig, D., Runkel, A. C. & Straub, K. M. Time not our time: physical controls on the preservation and measurement of geologic time. Annu. Rev. Earth Planet. Sci. 46, 409–438 (2018).
Myrow, P. M., Jerolmack, D. J. & Perron, J. T. Bedform disequilibrium. J. Sediment. Res. 88, 1096–1113 (2018).
Leary, K. C. P. & Ganti, V. Preserved fluvial cross strata record bedform disequilibrium dynamics. Geophys. Res. Lett. 47, e2019GL085910 (2020).
Colombera, L., Arévalo, O. J. & Mountney, N. P. Fluvial-system response to climate change: The Paleocene-Eocene Tremp Group, Pyrenees, Spain. Glob. Planet Change 157, 1–17 (2017).
Plink-Björklund, P. Morphodynamics of rivers strongly affected by monsoon precipitation: review of depositional style and forcing factors. Sediment Geol. 323, 110–147 (2015).
Fielding, C. R., Allen, J. P., Alexander, J. & Gibling, M. G. Facies model for fluvial systems in the seasonal tropics and subtropics. Geology 37, 623–626 (2009).
Adams, M. M. & Bhattacharya, J. P. No change in fluvial style across a sequence boundary, Cretaceous Blackhawk and Castlegate formations of central Utah, U.S.A. J. Sediment. Res. 75, 1038–1051 (2005).
Chamberlin, E. P. & Hajek, E. A. Using bar preservation to constrain reworking in channel-dominated fluvial stratigraphy. Geology 47, 531–534 (2019).
McMahon, W. J. & Davies, N. S. High-energy flood events recorded in the Mesoproterozoic Meall Dearg Formation, NW Scotland; their recognition and implications for the study of pre-vegetation alluvium. J. Geol. Soc. Lond. 175, 13–32 (2018).
Lyster, S. J., Whittaker, A. C., Hajek, E. A. & Ganti, V. Field evidence for disequilibrium dynamics in preserved fluvial cross-strata: a record of discharge variability or morphodynamic hierarchy? Earth Planet Sci. Lett. 579, 117355 (2022).
Paola, C. & Borgman, L. Reconstructing random topography from preserved stratification. Sedimentology 38, 553–565 (1991).
Leclair, S. F. & Bridge, J. S. Quantitative interpretation of sedimentary structures formed by river dunes. J. Sediment. Res. 71, 713–716 (2001).
Leclair, S. F. Preservation of cross-strata due to the migration of subaqueous dunes: an experimental investigation. Sedimentology 49, 1157–1180 (2002).
Ganti, V., Whittaker, A. C., Lamb, M. P. & Fischer, W. W. Low-gradient, single-threaded rivers prior to greening of the continents. Proc. Natl Acad. Sci. USA 116, 11652–11657 (2019).
Leary, K. & Buscombe, D. Estimating Sand Bedload in Rivers by Tracking Dunes: a comparison of methods based on bed elevation time-series. Earth Surf. Dyn. Discuss. 8, 161–172 (2019).
Ganti, V., Hajek, E. A., Leary, K., Straub, K. M. & Paola, C. Morphodynamic hierarchy and the fabric of the sedimentary record. Geophys. Res. Lett. 47, e2020GL087921 (2020).
Lyster, S. J. et al. Reconstructing the morphologies and hydrodynamics of ancient rivers from source to sink: Cretaceous Western Interior Basin, Utah, USA. Sedimentology 68, 2854–2886 (2021).
Wood, J., McLeod, J. S., Lyster, S. J. & Whittaker, A. C. Rivers of the Variscan Foreland: fluvial morphodynamics in the Pennant Formation of South Wales, UK. J. Geol. Soc. https://doi.org/10.31223/X5TK94 (2022).
Jerolmack, D. J. & Mohrig, D. Frozen dynamics of migrating bedforms. Geology 33, 57–60 (2005).
Cardenas, B. T. et al. The anatomy of exhumed river-channel belts: Bedform to belt-scale river kinematics of the Ruby Ranch Member, Cretaceous Cedar Mountain Formation, Utah, USA. Sedimentology 67, 3655–3682 (2020).
Falcon-Lang, H. J., Cleal, C. J., Pendleton, J. L. & Wellman, C. H. Pennsylvanian (mid/late Bolsovian-Asturian) permineralised plant assemblages of the Pennant Sandstone Formation of southern Britain: systematics and palaeoecology. Rev. Palaeobot. Palynol. 173, 23–45 (2012).
Burgess, P. M. & Gayer, R. A. Late Carboniferous tectonic subsidence in South Wales: implications for Variscan basin evolution and tectonic history in SW Britain. J. Geol. Soc. Lond. 157, 93–104 (2000).
Tabor, N. J. & Poulsen, C. J. Palaeoclimate across the Late Pennsylvanian-Early Permian tropical palaeolatitudes: a review of climate indicators, their distribution, and relation to palaeophysiographic climate factors. Palaeogeogr. Palaeoclimatol. Palaeoecol. 268, 293–310 (2008).
Jones, C. M. The Sedimentology of Carboniferous Fluvial and Deltaic Sequences; the Roaches Grit Group of the South-West Pennines and the Pennant Sandstone of the Rhondda Valleys (Keele University, 1977).
Jones, J. A. & Hartley, A. J. Reservoir characteristics of a braid-plain depositional system: the Upper Carboniferous Pennant Sandstone of South Wales. Geol. Soc. Spec. Publ. 73, 143–156 (1993).
Peyser, C. E. & Poulsen, C. J. Controls on Permo-Carboniferous precipitation over tropical Pangaea: a GCM sensitivity study. Palaeogeogr. Palaeoclimatol. Palaeoecol. 268, 181–192 (2008).
Sombroek, W. Spatial and temporal patterns of Amazon rainfall. Consequences for the planning of agricultural occupation and the protection of primary forests. Ambio 30, 388–396 (2001).
Nyberg, B. et al. Revisiting morphological relationships of modern source-to-sink segments as a first-order approach to scale ancient sedimentary systems. Sediment Geol. 373, 111–133 (2018).
Hack, J. T., Seaton, F. A. & Nolan, T. B. Studies of Longitudinal Stream Profiles in Virginia and Maryland (United States Department of the Interior, 1957).
Jenkins, B. H. J. The sequence and correlation of the coal measures of Pembrokeshire. Q. J. Geol. Soc. 118, 65–101 (1961).
Cleal, C. J. & Thomas, B. M. Plant Fossils of the British Coal Measures (The Palaeontological Association, 1994).
Brunner, M. I. et al. Flood type specific construction of synthetic design hydrographs. Water Resour. Res. 53, 1390–1406 (2017).
Gibling, M. R., Bashforth, A. R., Falcon-Lang, H. J., Allen, J. P. & Fielding, C. R. Log jams and flood sediment buildup caused channel abandonment and avulsion in the Pennsylvanian of Atlantic Canada. J. Sediment. Res. 80, 268–287 (2010).
Thomas, B. A. & Cleal, C. J. Arborescent lycophyte growth in the late Carboniferous coal swamps. N. Phytol. 218, 885–890 (2018).
Dimichele, W. A., Pfefferkorn, H. W. & Gastaldo, R. A. Response of Late Carboniferous and Early Permian plant communities to climate change. Annu. Rev. Earth Planet Sci. 29, 461–487 (2001).
Falcon-Lang, H. J. & Bashforth, A. R. Morphology, anatomy, and upland ecology of large cordaitalean trees from the Middle Pennsylvanian of. Rev. Palaeobot. Palynol. 135, 223–243 (2005).
Falcon-Lang, H. J. & Bashforth, A. R. Pennsylvania uplands were forested by giant cordaitalean trees. Geology 32, 417–420 (2004).
Bashforth, A. R. Canadian Society of Petroleum Geologists & Geological Association of Canada. Late Carboniferous (Bolsovian) macroflora from the Barachois Group, Bay St. George Basin, southwestern Newfoundland, Canada 123 (2005).
Davies, N. S. & Gibling, M. R. The sedimentary record of Carboniferous rivers: continuing influence of land plant evolution on alluvial processes and Palaeozoic ecosystems. Earth Sci. Rev. 120, 40–79 (2013).
Alexander, J., Fielding, C. R. & Jenkins, G. Plant-material deposition in the tropical Burdekin River, Australia: implications for ancient fluvial sediments. Palaeogeogr. Palaeoclimatol. Palaeoecol. 153, 105–125 (1999).
Phillips, T. L. & Dimichele, W. A. Comparative ecology and life-history biology of arborescent lycopsids in Late Carboniferous Swamps of Euramerica. Ann. Mo. Bot. Gard. 79, 560–588 (1992).
Melrose, C. S. A. Fossilized Forests of the Lower Carboniferous Horton Blufff Formation, Nova Scotia (2003).
Wagner, R. H. & Diez, J. B. Verdeña (Spain): life and death of a Carboniferous forest community. C. R. Palevol. 6, 495–504 (2007).
Stewart, W. N. & Rothwell, G. W. Paleobotany and the Evolution of Plants 521 (2009).
Hagerty, D. J., Spoor, M. F. & Ullrich, C. R. Bank failure and erosion on the Ohio river. Eng. Geol. 17, 141–158 (1981).
Thorne, C. R., Russell, A. P. G. & Alam, M. K. Planform pattern and channel evolution of the Brahmaputra River, Bangladesh. Geol. Soc. Lond. Spec. Publ. 75, 257–276 (1993).
Coleman, J. M. Brahmaputra river: channel processes and sedimentation. Sediment Geol. 3, 129–239 (1969).
Martin, C. A. L. & Turner, B. R. Origins of massive-type sandstones in braided river systems. Earth Sci. Rev. 44, 15–38 (1998).
Robison, E. G. & Beschta, R. L. Characteristics of coarse woody debris for several coastal streams of southeast Alaska, USA. Can. J. Fish. Aquat. Sci. 47, 1684–1693 (1990).
Fielding, C. R. Upper flow regime sheets, lenses and scour fills: extending the range of architectural elements for fluvial sediment bodies. Sediment Geol. 190, 227–240 (2006).
Hansford, M. R., Plink-Björklund, P. & Jones, E. R. Global quantitative analyses of river discharge variability and hydrograph shape with respect to climate types. Earth Sci. Rev. 200, 102977 (2020).
Cotter, E. Paleoflow characteristics of a late Cretaceous river in Utah from analysis of sedimentary structures in the Ferron Sandstone. J. Sediment Pet. 41, 129–142 (1971).
Miall, A. D. Reconstructing fluvial macroform architecture from two-dimensional outcrops: examples from the Castlegate Sandstone, Book Cliffs, Utah. J. Sediment. Res. B64, 146–158 (1994).
Hampson, G. J., Jewell, T. O., Irfan, N., Gani, M. R. & Bracken, B. Modest change in fluvial style with varying accommodation in regressive alluvial-to-coastal-plain wedge: Upper Cretaceous Blackhawk Formation, Wasatch Plateau, central Utah, USA. J. Sediment. Res. 83, 145–169 (2013).
Flood, Y. S. & Hampson, G. J. Facies and architectural analysis to interpret avulsion style and variability: Upper Cretaceous Blackhawk Formation, Wasatch Plateau, Central Utah, U.S.A. J. Sediment. Res. 84, 743–762 (2014).
Serinaldi, F., Loecker, F., Kilsby, C. G. & Bast, H. Flood propagation and duration in large river basins: a data-driven analysis for reinsurance purposes. Nat. Hazards 94, 71–92 (2018).
Gastaldo, R. A. & Huc, A.-Y. Sediment facies, depositional environments, and distribution of phytoclasts in the recent Mahakam River Delta, Kalimantan, Indonesia. Palaios 7, 574–590 (1992).
Hayden, A. T., Lamb, M. P. & McElroy, B. J. Constraining the timespan of fluvial activity from the intermittency of sediment transport on Earth and Mars. Geophys. Res. Lett. 48, e2021GL092598 (2021).
Martin, R. L. & Jerolmack, D. J. Origin of hysteresis in bed form response to unsteady flows. Water Resour. Res. 49, 1314–1333 (2013).
Mahon, R. C. & McElroy, B. Indirect estimation of bedload flux from modern sand-bed rivers and ancient fluvial strata. Geology 46, 579–582 (2018).
Gupta, P. K., Chauhan, S. & Oza, M. P. Modelling surface run-off and trends analysis over India. J. Earth Syst. Sci. 125, 1089–1102 (2016).
Waters, C. N., Waters, R. A., Barclay, W. J. & Davies, J. R. A Lithostratigraphical Framework for the Carboniferous Successions of southern Great Britain (onshore) (2009).
Barclay, W. J. Geology of the Swansea District—A Brief Explanation of the Geological Map. Short Explanation of the British Geological Survey. 1:50,000 Sheet 247 Swansea (England and Wales) (2011).
The authors acknowledge research support from Imperial College London. We are grateful to Gary Hampson and Cedric John for useful feedback on an early version of the manuscript.
The authors declare no competing interests.
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McLeod, J.S., Wood, J., Lyster, S.J. et al. Quantitative constraints on flood variability in the rock record. Nat Commun 14, 3362 (2023). https://doi.org/10.1038/s41467-023-38967-8