Abrasion pH and abrasion solution composition in reference European volcanic soils E. García-Rodeja, J.C. Nóvoa-Munoz, A. Martínez-Cortizas and T. Taboada Dpto. Edafología y Química Agrícola. Facultad de Biología. Universidad de Santiago de Compostela Stevens and Carron (1948) established the use of abrasion pH as an aid in mineral dentification. Later, Grant (1969) used abrasion pH as an indicator of rock weathering and Ferrari and Magaldi (1983) proposed it as an index of potential fertility of soils. The abrasion pH is obtained by grinding the minerals into distilled water; its value is affected by the quantity of residual cations released from primary minerals and the amount and type of clay minerals. In consequence, the higher values are expected in soils that are rich in fresh and weatherable minerals and, as weathering proceeds and the clay content of the soil increases, the abrasion pH tends to decrease. In this study abrasion pH and abrasion solution composition were determined in 15 COST action 622 soils (72 horizons) developed from volcanic materials in different European volcanic regions: Italy (Napoli: Nl, N2; Rome: N3, N4), Azores (N5, N6), Iceland (N7 to N9), Tenerife (NIO to N12), Santorini (N14), France (N16) and Hungary (N19), with the aim to evaluate its use as an index of weathering degree and/or of potential soil fertility in these particular soils using a set of samples that covers a wide range of volcanic materials, climatic conditions and degree of soil development. Abrasion pH was measured in peroxidized samples (to minimize the homogenizing effect of organic matter in the pH values) following the method of Grant (1969) that consists of measuring the pH of a soil (20g):distilled water (40mL) suspension after a grinding period of 2lA min (+ 2 min for settling) in an agatha mortar. After centrifugation of an aliquot of the suspension, base cations (Ca, Mg, Na, K) and Fe, Mn Si and A1 were measured. The results showed a wide range of abrasion pH values (4.5-7.7), with the lower in the soils from Azores (4.5-5.3) and the higher in those from Santorini and Hungary (>7) a fact that can be related to the different climatic conditions (udic vs xeric) determining their weathering and pedogenesis. In some cases the variations along the profile are small (Nl, N2, N5, N6, N14, N19) although the lower values for each soil tend to correspond to the A horizons. In other soils the variation of abrasion pH along the profile is more complex and, frequently, can be associated to discontinuities in the parent material or to different cycles of soil formation. For example, the soil N3 has more acid abrasion pH in the subsurface horizons than in the upper part of the profile with the limit located at a discontinuity marked by a stone line; in the soils NIO, N12 and N8 the buried horizons, with higher degree of weathering and pedological evolution, also have lower pH. Other approach to evaluate the abrasion pH as a weathering index in volcanic soils was to make a comparison to the weathering index of Parker (1970) (WIP), considered the most appropiate for soils on heterogeneous parent materials materials because it only includes the highly mobile alkali and alkaline earth elements in its formulation (Price and Velbel, 2003). (WIP = (100) [(2Na20/0.35)+(MgO/0.9)+(2K20/0.25)+CaO/0.7)]). From the comparison of both parameters (see figure) two groupsof soils can be differentiated. In one side are those from Italy and the N5 from Azores, with higher WIP, developed from more alkaline materials (trachytic and phonolitic), than the other ones, mainly formed on basaltic or andesitic parent materials, which tend to have lower WIP for the same abrasion pH. When both parameters are compared for each soil profile, the expected parallelism between them is only found in two soils (N9, N10), while in other, like N4 or N16, they follow opposite trends. 76

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