11:00 AM - 1:00 PM
[HQR04-P06] High-resolution dating of surface peat based on 137Cs and 210Pb radioactivity concentration
Keywords:wetland, peat, Cs-137 dating, Pb-210 dating, γ-ray detector, carbon reservoir
Wetlands are one of the largest carbon reservoirs in terrestrial ecosystems (e.g. Yu et al., 2010; Loisel et al., 2014). The carbon sequestration of peat is mainly controlled by the degree of decomposition, which is climate-dependent especially in subarctic wetlands where the low temperature inhibits the decomposition of organic materials. However, recent studies have shown that global warming will enhance peat decomposition and consequently reduce the carbon storage in wetlands (e.g. Wilson et al., 2021). To estimate the effect of climate change on peat decomposition and its capacity as a carbon reservoir, high-resolution chronologies of wetland sediments are required.
Tephrochronology and radiocarbon (14C) dating have often been used to estimate the age of sedimentation of peat. However, indicator tephras are not always found in the surface layers of sediments. 14C dating method is difficult to apply on the topmost sediment layers, which are likely to contain 14C from nuclear testing around 1950-1960. Topsoils have shown increased disturbances by human influence during the Anthropocene (Crutzen, 2006), which renders them unusable. Although the beginning of the Anthropocene is still controversial and has not been formally defined as a geological age unit, human activities have clearly affected the Earth's surface environment as exemplified by the rapid increase in carbon dioxide concentration and the release of anthropogenic radioactive materials since the mid-20th century (e.g., Aoyama and Hirose, 2004). In order to understand the influence of human activities on the sedimentary environment of wetlands, it is necessary to obtain high-resolution chronological information on the scale of several years to several decades. In this study, we used cesium-137 (137Cs) and lead-210 (210Pb) to date the topmost wetland sediment samples. These methods can estimate sediments ages and can be applied in areas with relatively high sedimentation rates that are difficult to analyze by 14C dating. In this study, we measured the radioactivity concentrations of 137Cs and 210Pb in the topmost wetland sediment samples, and attempted to clarify the sedimentation and development process of wetland sediments by high resolution in the past several decades.
The sedimentation rate of surface peat can be estimated from the depth of the peak 137Cs radioactivity concentration which corresponds to the time of global fallout. More detailed sedimentation rates can be calculated from the decay trend of 210Pb. The sedimentation rate at the surface layer was calculated to be ~0.18 cm/yr. The low 210Pb concentration at 0-5 cmbs (centimeters below surface) is estimated to be due to the contribution of mainly of Sphagnum remains which contain few soil particles that adsorb 210Pb within the stratum. The sedimentation age of this area was calculated from the 210Pb concentration excluding this surface layer and the sedimentation rate estimated from 137Cs peak. The result of this estimation implied that the sediment in the surface 12 cm is about 65 years old. In addition, it takes about 30 years for the plant remains to be converted to soil in the study area, based on the changes in facies from Sphagnum remains to decomposed peat.
Tephrochronology and radiocarbon (14C) dating have often been used to estimate the age of sedimentation of peat. However, indicator tephras are not always found in the surface layers of sediments. 14C dating method is difficult to apply on the topmost sediment layers, which are likely to contain 14C from nuclear testing around 1950-1960. Topsoils have shown increased disturbances by human influence during the Anthropocene (Crutzen, 2006), which renders them unusable. Although the beginning of the Anthropocene is still controversial and has not been formally defined as a geological age unit, human activities have clearly affected the Earth's surface environment as exemplified by the rapid increase in carbon dioxide concentration and the release of anthropogenic radioactive materials since the mid-20th century (e.g., Aoyama and Hirose, 2004). In order to understand the influence of human activities on the sedimentary environment of wetlands, it is necessary to obtain high-resolution chronological information on the scale of several years to several decades. In this study, we used cesium-137 (137Cs) and lead-210 (210Pb) to date the topmost wetland sediment samples. These methods can estimate sediments ages and can be applied in areas with relatively high sedimentation rates that are difficult to analyze by 14C dating. In this study, we measured the radioactivity concentrations of 137Cs and 210Pb in the topmost wetland sediment samples, and attempted to clarify the sedimentation and development process of wetland sediments by high resolution in the past several decades.
The sedimentation rate of surface peat can be estimated from the depth of the peak 137Cs radioactivity concentration which corresponds to the time of global fallout. More detailed sedimentation rates can be calculated from the decay trend of 210Pb. The sedimentation rate at the surface layer was calculated to be ~0.18 cm/yr. The low 210Pb concentration at 0-5 cmbs (centimeters below surface) is estimated to be due to the contribution of mainly of Sphagnum remains which contain few soil particles that adsorb 210Pb within the stratum. The sedimentation age of this area was calculated from the 210Pb concentration excluding this surface layer and the sedimentation rate estimated from 137Cs peak. The result of this estimation implied that the sediment in the surface 12 cm is about 65 years old. In addition, it takes about 30 years for the plant remains to be converted to soil in the study area, based on the changes in facies from Sphagnum remains to decomposed peat.