TY - JOUR
T1 - Can 239+240Pu replace 137Cs as an erosion tracer in agricultural landscapes contaminated with Chernobyl fallout?
AU - Schimmack, W.
AU - Auerswald, K.
AU - Bunzl, K.
N1 - Funding Information:
This work was financed in part by the Bundesministerium für Bildung, Wissenschaft, Forschung und Technologie (BMBF No. 0339370) and the Bayerische Staatsministerium für Unterricht und Kultus, Wissenschaft und Kunst. We acknowledge the excellent technical assistance of V. Tschöpp and F. Dietl, the geodetic survey by Dr. W. Maurer, Lehrstuhl für Geodäsie, München and the soil sampling by Dr. A. Scheinost und Dr. W. Sinowski, Lehrstuhl für Bodenkunde.
PY - 2001
Y1 - 2001
N2 - Erosion studies often use 137Cs from the global fallout (main period: 1953-1964) as a tracer in the soil. In many European countries, where 137Cs was deposited in considerable amounts also by the Chernobyl fallout in 1986, the global fallout fraction (GF-Cs) has to be separated from the Chernobyl fraction by means of the isotope 134Cs. In a few years, this will no longer be possible due to the short half-life of 134Cs (2yr). Because GF-Cs in the soil can then no longer be determined, the potential of using 239+240Pu as a tracer is evaluated. This radionuclide originates in most European countries essentially only from the global fallout. The activities and spatial distributions of Pu and GF-Cs were compared in the soil of a steep field (inclination about 20%, area ca. 3 ha, main soil type Dystric Eutrochrept), sampled at 48 nodes of a 25x25m2 grid. The reference values were determined at 12 points adjacent to the field. Their validity was assured by an inventory study of radiocaesium in a 70ha area surrounding the field sampling 275 nodes of a 50x50m2 grid. In the field studied, the activity concentrations of GF-Cs and Pu in the Ap horizon were not correlated (Spearman correlation coefficient R=0.20, p>0.05), and the activity balance of Pu differed from that of GF-Cs. Whereas no net loss of GF-Cs from the field was observed as compared to the reference site, Pu was more mobile with an average loss of ca. 11% per unit area. In addition, the spatial pattern of GF-Cs and Pu in the field differed significantly. The reason may be that due to their different associations with soil constituents, Pu and Cs represent different fractions of the soil, exhibiting different properties with respect to erosion/deposition processes. This indicates that both radionuclides or one of them may not be appropriate to quantify past erosion. When tracer losses are used to calibrate or verify erosion prediction models, systematic deviations may not only stem from model shortcomings but also from tracer technique. Copyright (C) 2000 Elsevier Science Ltd.
AB - Erosion studies often use 137Cs from the global fallout (main period: 1953-1964) as a tracer in the soil. In many European countries, where 137Cs was deposited in considerable amounts also by the Chernobyl fallout in 1986, the global fallout fraction (GF-Cs) has to be separated from the Chernobyl fraction by means of the isotope 134Cs. In a few years, this will no longer be possible due to the short half-life of 134Cs (2yr). Because GF-Cs in the soil can then no longer be determined, the potential of using 239+240Pu as a tracer is evaluated. This radionuclide originates in most European countries essentially only from the global fallout. The activities and spatial distributions of Pu and GF-Cs were compared in the soil of a steep field (inclination about 20%, area ca. 3 ha, main soil type Dystric Eutrochrept), sampled at 48 nodes of a 25x25m2 grid. The reference values were determined at 12 points adjacent to the field. Their validity was assured by an inventory study of radiocaesium in a 70ha area surrounding the field sampling 275 nodes of a 50x50m2 grid. In the field studied, the activity concentrations of GF-Cs and Pu in the Ap horizon were not correlated (Spearman correlation coefficient R=0.20, p>0.05), and the activity balance of Pu differed from that of GF-Cs. Whereas no net loss of GF-Cs from the field was observed as compared to the reference site, Pu was more mobile with an average loss of ca. 11% per unit area. In addition, the spatial pattern of GF-Cs and Pu in the field differed significantly. The reason may be that due to their different associations with soil constituents, Pu and Cs represent different fractions of the soil, exhibiting different properties with respect to erosion/deposition processes. This indicates that both radionuclides or one of them may not be appropriate to quantify past erosion. When tracer losses are used to calibrate or verify erosion prediction models, systematic deviations may not only stem from model shortcomings but also from tracer technique. Copyright (C) 2000 Elsevier Science Ltd.
KW - Chernobyl fallout
KW - Erosion
KW - Global fallout
KW - Plutonium
KW - Radiocaesium
UR - http://www.scopus.com/inward/record.url?scp=0034747639&partnerID=8YFLogxK
U2 - 10.1016/S0265-931X(00)00117-X
DO - 10.1016/S0265-931X(00)00117-X
M3 - Article
C2 - 11378925
AN - SCOPUS:0034747639
SN - 0265-931X
VL - 53
SP - 41
EP - 57
JO - Journal of Environmental Radioactivity
JF - Journal of Environmental Radioactivity
IS - 1
ER -