Stochastic alluvial fan and terrace formation triggered by a high-magnitude Holocene landslide in the Klados Gorge, Crete

Self Cite

The impact of Quaternary climate cycles on denudation rates and fluvial aggradation and incision is debated, especially in non-glaciated regions. Here we present paleo-denudation rates and geochronological constraints on aggradation and incision from the Sfakia and Elafonisi alluvialfan sequences on Crete, Greece. We report seven optically stimulated luminescence (OSL), ten radiocarbon ages, and eight 10 Be and eight 36 Cl denudation rates from modern and terrace sediments. For five samples, 10 Be and 36 Cl were measured on the same sample by measuring 10 Be on cherts and 36 Cl on calcite. Results indicate relatively steady denudation rates throughout the past 80kyr, but the aggradation and incision history indicate a link with shifts in climate. At the Elafonisi fan, we identify four periods of aggradation coinciding with Marine Isotope Stages (MIS) 2, 4, 5a/b, and likely 6, and three periods of incision coinciding with MIS 1, 3, and likely 5e. At the Sfakia fan, rapid aggradation occurred during MIS 2 and 4, analogous to aggradation periods at the Elafonisi fan system, followed by up to 50 m of incision during MIS 1. Nearby climate and vegetation records show that MIS 2, 4, and 6 were characterized by cold and dry climates with sparse vegetation, whereas forest cover and wet conditions prevailed during MIS 1, 3, and 5. Our data thus suggest that past changes in climate had little effect on landscape-wide denudation rates, but exerted a strong control on the aggradation-incision behaviour of alluvial channels on Crete. During glacial stages, we attribute aggradation to hillslope sediment release promoted by reduced vegetation cover and decreased river sediment transport capacity; conversely, incision occurred during relatively warm and wet stages due to increased river transport capacity. We conclude that, in this landscape, past hydroclimate variations outcompeted changes in sediment supply as the primary driver of alluvial deposition and incision.

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Paleo‐denudation rates suggest variations in runoff drove aggradation during last glacial cycle, Crete, Greece

Ott

Scherler

Wegmann

et al. 2022

Self Cite

“…Along the south central coast alone, over 40 rivers drain predominantly limestone gorges that commonly preserve morphological and sedimentary evidence for Quaternary changes in sediment supply and flow regime that have resulted from variations in tectonic activity (including uplift, faulting, local subsidence, and seismic shaking), climate, and human land use (e.g., Booth, 2010;Bruni et al, 2021;Maas, 1998;Maas & Macklin, 2002;Maas et al, 1998;Macklin et al, 2010;Noble, 2004;Pope et al, 2008).…”

Section: Regional Settingmentioning

confidence: 99%

“…This is especially the case in those parts of Cretan catchments underlain by more easily erodible Neogene sediments such as the Messara Plain, where major agricultural intensification led to accelerated fine-grained sedimentation in the downstream Anapodaris Gorge during the mid-12th century CE (Macklin et al, 2010). However, in the steepland catchments of south-western Crete that tend to be underlain by more mechanically resistant lithologies (e.g., limestones, phylitte quartzites), tectonic activity, climatic fluctuations, and/or stochastic events (e.g., mass movements) have been shown to be the primary controls of major valley floor incision and aggradation phases (Bruni et al, 2021;Macklin et al, 2010;Maas & Macklin, 2002;Maas et al, 1998;Pope et al, 2008Pope et al, , 2016. Valley-floor vegetation (e.g., maquis, phrygana, Cretan pine [Pinus brutia] and oleander [Nerium oleander]) tends to be patchy and has had little influence on these incision and aggradation phases (Maas & Macklin, 2002;Macklin et al, 2010).…”

Section: Regional Settingmentioning

confidence: 99%

How have Cretan rivers responded to late Holocene uplift? A multi‐millennial, multi‐catchment field experiment to evaluate the applicability of Schumm and Parker's (1973) complex response model

Macklin

Booth²,

Brewer

et al. 2022

‘Complex response’ (Schumm, 1973, Geomorphic thresholds and complex response of drainage systems. In Morisawa, M. (ed.), Fluvial Geomorphology. Binghamton: New York State University Publications: 299‐310) describes situations in which a single event triggers a series of progressively damped morphological and sedimentary adjustments within a catchment. Schumm and Parker's (1973, Implications of complex response of drainage systems for Quaternary alluvial stratigraphy. Nature 243: 99–100) classic stream table experiment of drainage system development showed that one baselevel fall event could result in formation of two sets of paired river terraces that need not be related to additional external (e.g., climate) influences. Despite its enduring popularity in fluvial geomorphology, large‐scale and long‐term field evaluations of Schumm and Parker's complex response model are very limited. Here, we report on a multi‐millennial, multi‐catchment field experiment in south‐western Crete where a high‐magnitude earthquake (estimated magnitude 8.3–8.5) on 21 July 365 ce resulted in up to 9 m of instantaneous uplift over a land area exceeding 6000 km2. Geomorphological, sedimentological, and chronological investigations were used to investigate the erosional and depositional histories in three catchments with outlets uplifted by the 365 ce event. These catchments were compared with the Anapodaris catchment in south central Crete where baselevel was not significantly affected by the earthquake. Although all uplifted catchments experienced valley floor incision, this occurred hundreds of years after 365 ce during a period of wetter climate. The number and age of trunk stream incision and aggradation phases are similar in both uplifted and non‐uplifted catchments, indicating that river responses following the 365 ce uplift event have not followed complex response trajectories in the form documented by Schumm and Parker (1973). This finding highlights the need for rigorous evaluation of other catchment or river response concepts, including through the combined use of laboratory experimental results, field data, and geochronology. In an era of rapid environmental change, characterizing and anticipating catchment and river system response increasingly will depend on a healthy interplay between different investigative approaches.

“…The sedimentary architecture of alluvial fan systems results from different cycles of erosion and sedimentation (e.g., de Haas et al., 2019; Harvey, 2012; Mather et al., 2017). Although the sediments stored in an alluvial fan are a fraction of those transported from its feeder catchment, they can document the legacy of floods, sediment‐laden flows, and debris flows (Bruni et al., 2021; Davies & Korup, 2007; Korup, 2004). Careful investigations and analyses of such sediments may help to understand how and under which conditions sediments were transported, deposited, and preserved (e.g., Bardou & Jaboyedoff, 2008; Crosta & Frattini, 2004).…”

Section: Introductionmentioning

confidence: 99%

Tracing past extreme floods on an alluvial fan using geophysical surveying

Arboleda‐Zapata,

Guillemoteau,

Lucía

et al. 2023

SummarySedimentary units in alluvial fans may record gradual transport and deposition during multiple floods or sediment‐laden flows or, conversely, during few catastrophic events. While outcrops are a valuable source of direct information to constrain past geomorphic and hydrologic processes, such exposures are scarce, especially along aggrading rivers or those that have been subject to recent catastrophic sedimentation. In this context, near‐surface geophysical techniques can constrain the dimensions, internal architecture, composition, and petrophysical properties of different sedimentary units. We consider the Grimmbach alluvial fan in the cuesta landscape of southwestern Germany, which was heavily impacted by sediment and wood loads during a flash flood in 2016; published radiocarbon dates indicate that at least three floods similar to the one in 2016 may have occurred since the 17th century. To test whether and to which detail near‐surface geophysics might reveal the sedimentary legacy of these floods, we survey the Grimmbach alluvial fan using detailed topographic data and geophysical imaging based on electromagnetic induction, electrical resistivity tomography (ERT), and ground‐penetrating radar. Our geophysical results indicate former channel courses and two coarse bar deposits up to 3 m below the surface, which are comparable with the more extensive bar deposits of the 2016 flood. From the ERT models, we interpret coarse, up to 5 m thick, gravel lag overlying bedrock at a maximum depth of 10 m. Our geophysical results also highlight patches of finer materials derived from gradual sedimentation and soil development. Overall, our results show that the Grimmbach alluvial fan may have formed and reshaped during catastrophic flows, which likely caused channel avulsions. Our findings point to the need to reconsider flash flood and debris‐flow hazards in similar headwaters and fans of this seemingly quiescent cuesta landscape in southern Germany.