Geological Survey of Denmark and Greenland Bulletin 17, 2009, 37-40 The Danish landscape is characterised by low relief and conse- quently the risk of soil erosion is low compared to many cen- tral and southern European countries with more variable terrain (European Environment Agency 2000; Van der Knijff et al. 2000). However, even in countries with less intensive ero- sion, water-induced soil erosion is recognised as an increasingly important environmental issue due to its role in the transport of nutrients, pesticides and other contaminants to rivers, lakes and coastal waters (e.g. Stone 2000). There are relatively few monitoring programmes of sedi- ment erosion in Denmark and those that exist typically only cover the last few decades (Veihe et al. 2003). Therefore, it is difficult to identify long-term trends and baseline conditions. However, the geological record provides insight into patterns and rates of soil erosion through time. Lake and fjord sediment archives are especially useful because they can provide contin- uous and undisturbed sediment successions that can be ana - lysed at high temporal resolution. These sediment records can be examined using a variety of approaches that include sedi- mentological, geochemical and biological analyses and thus generate important insight into baseline states, trajectories and responses to forcing mechanisms over long timescales, which would otherwise be difficult to obtain. The records are typi- cally limited to yielding insight only into the average rate of erosion and they often provide little information about the spatial extent or distribution of erosional processes within a catchment area. In this paper we present an example of a long-term ero- sional record from Gudme Sø, Fyn (Fig. 1). Numerous archae - ological excavations have been undertaken near Gudme Sø, and the Geological Survey of Denmark and Greenland has carried out analyses of sediments from the lake to provide a continuous picture of landscape changes. Sediment accumu- lation rates of minerogenic matter and pollen analysis are here used to ex plore the erosional response to changes in land-use. Study site and methods Gudme Sø is located on south-east Fyn c. 5 km from the sea in a gently undulating terrain with surface deposits consist- ing of clay till (Fig. 1). The lake has a surface area of 9 ha, a mean water depth of 0.5 m, and a catchment area of 48 ha. It has no major natural inlets or outlets. An 11.8 m long sed- iment core of slightly humic gyttja with low calcareous con- tent and varying silt and clay contents was retrieved from the lake. Age determination was provided by radiocarbon dating, and the chronology at the top of the core was further refined by linear interpolation, using the first occurrence of spheroidal carbonaceous fly-ash particles and the date of the sediment sur- face (i.e. the year of coring) as bracketing ages (Fig. 2). Sediment accumulation rates of minerogenic matter (SAR-min in mg/cm2 per year) were calculated and used as prox ies of soil erosion from the catchment area to the lake (e.g. Mackereth 1966). The changes in SAR-min values were compared to pollen-inferred changes in vegetation and land- use from the same sediment core. The increases and decreases in non-arboreal pollen (NAP) were used as a record of changes in the proportion of open land. It is assumed that the variation in the sum of taxa of cultivated plants and Plantago lanceolata (ribwort plantain) reflects changes in the extent of arable land, and pastures or meadows, respectively (Behre 1981; Gaillard 2007). The record of colonies of the green algae Pediastrum sp. is used as proxy evidence for in-lake pro- ductivity (Bradshaw et al. 2005). Soil erosion and land-use change during the last six millennia recorded in lake sediments of Gudme Sø, Fyn, Denmark Peter Rasmussen and Jesper Olsen © GEUS, 2009. Geological Survey of Denmark and Greenland Bulletin 17, 37–40. Available at: www.geus.dk/publications/bull 37 Fig. 1. Aerial photograph of Gudme Sø seen from the south-east. The lake size is c. 490 × 250 m. Today the lake catchment area (48 ha) con- sists of 50% tilled, 25.8% natural and 24.2% built-up area. Photograph courtesy of The Royal Danish Air Force. ROSA_2008:ROSA-2008 01/07/09 15:48 Side 37 Results and discussion Chronology The 14C dates from the Gudme Sø sediment core are based on bulk sediment samples and may overestimate their actual ages due to the hard-water effect (Björck & Wohlfarth 2001). However, the CaCO3 content of the sediments is very low and the ages of key-pollen, stratigraphical levels at Gudme Sø are in agreement with other independent ages from corre- sponding levels in Danish bogs where the dated peat is unaf- fected by hard water (Table 1). Hence, we consider the Gudme Sø age–depth model to be reasonably accurate and reliable within c. 100 years. In the following, all ages are given in calendar years BC/AD. Incipient landscape disturbance In Fig. 3 the history of the last c. 6000 years of soil erosion to the Gudme Sø basin is compared with contemporary changes in vegetation and land-use. Coincident increases in total NAP and taxa of cultivated plants and in SAR-min suggest a causal link between agricultural activities and soil loss. The low SAR-min values in the late Mesolithic (c. 4200– 3900 BC) suggest a low level of soil disturbance, which is in good agreement with the pollen data. Very low NAP values (c. 2%) indicate that the landscape was dominated by closed- canopy forests with only a sparse field layer vegetation (Iver - sen 1973). During the Mesolithic, anthropogenic impact on the vegetation appears to have been negligible, and landscape disturbance was driven by natural agencies, implying that the sediment flux to the lake at this time represents a ‘natural’ baseline state. In Denmark the cultural shift from the Mesolithic (hunt- ing-fishing-gathering) to the Neolithic (farming) way of living took place c. 3900 BC. Approximately 200 years later (c. 3650–3500 BC) a marked increase in both SAR-min and NAP values at Gudme Sø indicate an erosional event clearly triggered by deforestation that was associated with incipient agricultural activities. At that time the first pollen types unambiguously indicative of crop cultivation and pastoral farming occurred (cereals and Plantago lanceolata, respec- tively). Interestingly, the data indicate that catchment distur- bance and agricultural activities precede accelerated erosion rates by c. 150–200 years, thus showing a delay or threshold effect in the system’s response. Between c. 3350 and 3200 BC soil erosion rates increased again, although this time not correlated with pollen evidence of land clearance or intensified agriculture. Low soil erosion rates between c. 3200 and 2650 BC and low NAP values indicate catchment stability. At about 2650 BC a renewed and short-lived (c. 2650–2550 BC) deforestation was accom- panied by intensified agricultural activities reflected in high percentages of NAP, Plantago lanceolata and cultivated taxa. Despite the apparent intensity of this brief land clearance episode, the erosional response was moderate. This might be 38 20001000010002000300040005000 Age (calendar years BC/AD) D ep th b el o w s ed im en t su rf ac e (c m ) K-5839 K-6022 K-5840 K-6023 K-5771 K-6024 K-5770 K-6025 K-5841 K-6026 K-5842 K-5769 K-5768 200 300 400 500 600 700 800 900 1000 1100 1200 100 Table 1. 14C dates of pollen-analytical levels in Gudme Sø and three Danish raised bogs Gudme Fuglsø Abkær Holmegaard Sø Mose Mose Mose Data partly from Odgaard (1994). 1st Centaurea cyanus (cornflower) AD 1320 AD 1360 AD 1240 AD 1350 1st Secale cereale (rye) 170 BC 80 BC 80 BC 80 BC Fagus sylvatica (beech) 3–5% 960 BC 890 BC 240 BC 920 BC Fagus sylvatica (beech) > 0.5–1% 1460 BC 1320 BC 1320 BC 1400 BC 1st Plantago lanceolata (ribwort plantain) 3650 BC 3630 BC 3000 BC 3800 BC Elm decline 3990 BC 3830 BC 3870 BC 3500 BC Fig. 2. Age–depth model for the Gudme Sø sediment succession based on 13 calibrated 14C dates, the date of the first occurrence of spheroidal carbonaceous fly-ash particles (blue dot at AD 1900; Odgaard 1993) and the age of the sediment surface (red dot at AD 1989). The K-numbers are the laboratory numbers for the dated samples. The small diagrams show probability distributions of the calibrated ages. The age–depth model was established using the programme Bpeat (Blaauw & Christen 2005). ROSA_2008:ROSA-2008 01/07/09 15:48 Side 38 due to the type of land-use at a time when subsistence economy most likely was predominantly based on pastoral farming. In contrast to arable farming, such land-use implies the maintenance of permanently grass-covered pasture that would be less prone to erosion than cultivated fields (Veihe et al. 2003). After 2550 BC, low soil erosion rates indicate a long period of relative stability in the catchment area, which lasted until the middle of the Bronze Age at c. 1000 BC. Landscape transformation For c. 150 years, between 1000 and 850 BC, the landscape around Gudme Sø changed drastically and became far more open than previously as suggested by the increase in NAP. Extensive forest clearance and expansion of areas used for livestock grazing and crop cultivation led to comprehensive landscape disturbance and a marked increase in erosion rates to the lake. The contemporary increase in Pediastrum sp. indicates a larger nutrient loss from the catchment area to the lake due to soil in-wash, which enhanced the in-lake pro- ductivity. After c. 200 years, the sediment influx to the lake gradually declined and stabilised, despite a continued high an thro pogenic impact on the landscape as indicated by the continued high NAP values. In the Iron Age around 100 BC, the erosion rates in - creased slightly and remained almost constant until c. AD 400. Thereafter, there was a short-lived disturbance period around AD 400–500 with intensified arable farming (in - creased abundances of cultivated taxa), accelerated soil ero- sion, and higher lake productivity (raised percentages of Pediastrum sp.). High percentages of Cannabis-type pollen in this period (not shown) indicate that the lake was used for retting hemp, a process in which stems are soaked in water to free their bast fibres from the surrounding tissue in order to produce fibres for example for cloth and rope making. Hemp-retting in the lake most likely contributed to the increased input of minerogenic material, as plants for retting may have been placed in the lake with roots; this could also have contributed to the nutrient enrichment of the lake at that time (Odgaard 1994). Between c. AD 600 and 900 the soil erosion rate to the lake decreased, in agreement with the reduced anthropogenic impact on the landscape as reflected in the decreasing NAP values. At this time, the use of the lake for hemp-retting almost ceased and the percentage value of Pediastrum sp. declined. Between AD 950 and 1050, i.e. in the second half of the Viking Age, the pollen data suggest renewed deforesta- tion followed by greatly intensified arable farming (elevated percentages of cultivated taxa). This marked change in land- use led to an unprecedented increase in soil erosion that likely caused eutrophication of the lake involving blooms of Pedia - strum sp. The nutrient enrichment of the lake may have been further intensified by resumption of hemp-retting in the lake, a procedure which continued to around AD 1900. During the Medieval period, the anthropogenic impact on the landscape increased significantly as land clearance in - 39 2000 M es ol ith ic N eo lit hic Br on ze A ge Iro n Ag e M ed iev al M od er n 40 20 SA R -m in ( m g/ cm 2 pe r yr ) 10% 1500% 1000% 500% 10% 4000 3500 3000 2500 2000 1500 1000 500 5000 1000 1500 60 40 20 Age (calendar years BC/AD) N A P (% ) SAR-min SAR-min x 10 NAP (%) ∑ Pollen from cultivated taxa Pediastrum sp. Plantago lanceolata A B C D Fig. 3. A: Sediment accumulation rate of mine - ro genic matter (SAR-min; proxy of soil erosion rate) and non-arboreal pollen (NAP; proxy for open land). The results of the pollen analysis are presented as percentages of the total sum of pollen and spores from terrestrial plants. B: Pollen percentages of the sum of cultivated taxa. C: Pollen percentages of Plantago lanceo - lata (ribwort plantain). D: Percentages of the green algae Pediastrum sp. (calculated on the basis of the terrestrial pollen and spore sum). For B, C and D the dark-coloured curves are percentages and the light-coloured areas represent 10 times exaggeration. ROSA_2008:ROSA-2008 01/07/09 15:48 Side 39 40 creased and crop cultivation intensified. The cultivation of large new areas was facilitated by the introduction of new farming technology such as the mouldboard plough and ridge-and-furrow. At Gudme Sø, the intensive arable farming in the Middle Ages led to steadily increasing sediment yields. The abundance of Pediastrum sp. at this time suggests con- tinued eutrophication. In Modern time (AD 1536 to the Present) the area around the lake was further cultivated at the expense of woodland. From c. AD 1500 to 1950, NAP values increased from c. 30% to 55% indicating widespread agricultural activities predom- inantly characterised by crop cultivation. The high and in - creasing human impact during this period corresponds closely to a dramatic and unprecedented increase in soil ero- sion, which peaked around AD 1950 contemporaneously with the highest NAP values in the entire record. A rapid and marked increase in the percentage of Pediastrum sp. at the beginning of the 18th century signifies the onset of a major nutrient enrichment of the lake. Concluding remarks The investigation of the lake sediments from Gudme Sø provides a 6000-year-record of soil erosion rates as well as contemporary pollen-inferred changes in vegetation and land-use. The study demonstrates a close correlation between changes in agricultural activity and rates of soil erosion in the catchment area of the lake. Prior to the late Viking Age, ero- sion to the lake occurred in pulses triggered by episodes of land clearance followed by periods of relative stability in the catchment area. After the late Viking Age, soil erosion accel- erated continuously and reached a peak in the mid-20th century with erosion rates approximately 30 times higher than the pre-disturbance rates in the Mesolithic. The study dem onstrates that after the introduction of agriculture, soil erosion was mainly caused by human activity rather than cli mate. This general result has also emerged from other lake-based studies of long-term erosion in Denmark (Ras - mussen & Bradshaw 2005) and southern Sweden (Dearing 1991). According to current climate models we can expect an in crease in precipitation, more rainfall in the winter season and a higher frequency of extreme precipitation events in the future (Christensen et al. 2006). Given these predic- tions, climate will undoubtedly be of growing significance as a forcing mechanism for soil erosion. Acknowledgement The Gudme Sø investigation is part of an archaeological research project funded by A.P. 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Veihe, A., Hasholt, B. & Schiøtz, I.G. 2003: Soil erosion in Denmark: processes and politics. Environmental Science & Policy 6, 37–50. Authors’ addresses P.R., Geological Survey of Denmark and Greenland, Øster Voldgade 10, DK-1350 Copenhagen K, Denmark. E-mail: per@geus.dk J.O., Department of Earth Sciences, Aarhus University, Høegh-Guldbergs Gade 2, DK-8000 Århus C, Denmark. ROSA_2008:ROSA-2008 01/07/09 15:48 Side 40