A new mechanism for calcium loss in forest-floor soils

CALCIUM is the fifth most abundant element in trees, and is an essential component for wood formation and the maintenance of cell walls. Depletion of Ca from the rooting zone can result in acidification of soil1 and surface water2 and possibly growth decline and dieback of red spruce3,4. During the past six decades, concentrations of root-available Ca (exchangeable and acid-extractable forms) in forest-floor soils have decreased in the northeastern United States5,6. Both net forest growth and acid deposition have been put forth as mechanisms that can account for this Ca depletion5,6. Here, however, we present data collected in red spruce forests in the northeastern United States that are inconsistent with either of these mechanisms. We propose that aluminium, mobilized in the mineral soil by acid deposition, is transported into the forest floor in a reactive form that reduces storage of Ca, and thus its availability for root uptake. This results in potential stress to trees and, by increasing the demand for Ca, also decreases neutralization of drainage waters, thereby leading to acidification of lakes and streams.

[1]  Gene E. Likens,et al.  Steep declines in atmospheric base cations in regions of Europe and North America , 1994, Nature.

[2]  F. D. Coninck Major mechanisms in formation of spodic horizons , 1980 .

[3]  C. Cronan Differential adsorption of Al, Ca, and Mg by roots of red spruce (Picea rubens Sarg.). , 1991, Tree physiology.

[4]  H. Blume,et al.  Page, A. L., R. H. Miller and D. R. Keeney (Ed., 1982): Methods of soil analysis; 2. Chemical and microbiological properties, 2. Aufl. 1184 S., American Soc. of Agronomy (Publ.), Madison, Wisconsin, USA, gebunden 36 Dollar. , 1985 .

[5]  N. Christophersen,et al.  Water Flow Paths and the Spatial Distribution of Soils and Exchangeable Cations in an Acid Rain-Impacted and a Pristine Catchment in Norway , 1991 .

[6]  W. K. Roy,et al.  Acid deposition alters red spruce physiology: laboratory studies support field observations , 1993 .

[7]  Andrew J. Friedland,et al.  Determination of soil exchangeable-cation loss and weathering rates using Sr isotopes , 1993, Nature.

[8]  J. Aber,et al.  Experimental inducement of nitrogen saturation at the watershed scale , 1993 .

[9]  Lindsey E. Rustad,et al.  Biogeochemical controls on aluminum chemistry in the O horizon of a red spruce (Picea rubens Sarg.) stand in central Maine, USA , 1995 .

[10]  A. Stein,et al.  The solubility of aluminum in acidic forest soils: Long-term changes due to acid deposition , 1994 .

[11]  A. J. Friedland,et al.  Trace metal content of the forest floor in the green mountains of Vermont: Spatial and temporal patterns , 1984 .

[12]  Paul R. Bloom,et al.  Predicting aqueous aluminium concentrations in natural waters , 1986, Nature.

[13]  Dale W. Johnson,et al.  Soil-Mediated Effects of Atmospheric Deposition on Eastern U.S. Spruce-Fir Forests , 1992 .

[14]  C. Cronan,et al.  ALBIOS: A Comparison of Aluminum Biogeochemistry in Forested Watersheds Exposed to Acidic Deposition , 1989 .

[15]  A. Jenkins,et al.  An assessment of terrestrial liming strategies in upland Wales , 1991 .

[16]  T. Siccama,et al.  Acid rain and soils of the Adirondacks. I. Changes in pH and available calcium. 1930-1984 , 1994 .

[17]  Walter C. Shortle,et al.  Aluminum-Induced Calcium Deficiency Syndrome in Declining Red Spruce , 1988, Science.

[18]  Mary Beth Adams,et al.  Ecology and Decline of Red Spruce in the Eastern United States , 2011, Ecological Studies.

[19]  C. Driscoll,et al.  Acidic deposition and internal proton sources in acidification of soils and waters , 1984, Nature.

[20]  Walter C. Shortle,et al.  Timing, magnitude, and impact of acidic deposition on sensitive forest sites , 1992 .

[21]  C. Federer,et al.  The organic fraction–bulk density relationship and the expression of nutrient content in forest soils , 1993 .