Estimation of weathering rates for critical load calculations in Finland

Abstract

The formation of base cations through mineral weathering in forest soils is one of the key parameters in calculating critical loads. Weathering rates in Finland have been estimated using a variety of methods. In the first approach, three weathering rate categories were assigned to soils according to the bedrock type. The second approach was based on an empirical relationship obtained from Swedish field studies. Changes in zirconium content through the soil profile were used to estimate element losses in soil after deglaciation. These calculated losses correlated well with the total calcium and magnesium concentrations in till C-horizons and the effective temperature sum (ETS). Comprehensive geochemical data for the parent till fine fraction (<0.06 mm) was available through the reconnaissance scale till geochemical mapping program of the Geological Survey of Finland (GSF). The equations obtained from Swedish studies were based on the use of the coarse (<2.0 mm) till fraction, and the differences in element concentrations between the fine and coarse size fractions remained a potential source of uncertainty estimating overall weathering rates. In the third approach, new geochemical data from the <2.0 mm till fraction from southern Finland were used to make new weathering rate estimates. The use of soil geochemistry instead of bedrock map classification clearly led to an improvement in the estimates of soil weathering rates in glacied terrains. The use of the fine till fraction (<0.06 mm) in the zirconium approach generally resulted in overestimations of the weathering rate. The new geochemical data for the coarse till fraction (<2 mm) are now consistent with the input requirements of the zirconium method, although the results still require further evaluation. Finnish soil profiles have a shorter weathering history than most of the Swedish ones and the uppermost layer in Finnish podsols has in some cases developed in a different till layer than the C-horizon.