Lm. Mayer, RELATIONSHIPS BETWEEN MINERAL SURFACES AND ORGANIC-CARBON CONCENTRATIONS IN SOILS AND SEDIMENTS, Chemical geology, 114(3-4), 1994, pp. 347-363
Relationships between mineral specific surface area and organic carbon
(OC) concentration are examined for sediments and soil A-horizons fro
m throughout the world. I found (published elsewhere) that continental
shelf sediments from many different regions exhibit downcore loss of
OC to a refractory background level which shows a consistent relations
hip with mineral surface area (slope = 0.86 mg m-2 OC). This trend is
equivalent to a monolayer of organic matter over all surfaces, and is
termed the monolayer-equivalent (ME) level. Sediments and soils from o
ther environments are compared to this empirically derived relationshi
p. Several continental slope areas show extension of this relationship
to considerable depth. Marked excesses of OC above this trend, which
persist downcore, were found in sediments with high carbonate mineral
content or slope sediments with low dissolved oxygen concentrations in
the overlying water column. About half of the soils examined also adh
ered to this relationship, while soils with high carbonate content, lo
w pH, or poor drainage showed OC concentrations higher than the ME lev
el. OC concentrations below the ME level are found in deltaic regions
and areas with low organic matter delivery such as the deep sea or ari
d soils. The nature of mineral surfaces was examined using N2 adsorpti
on-desorption isotherms, and most surface area was found to be present
as pores with < 8-nm widths. A hypothesis is developed that explains
the observed OC concentrations as a saturation of adsorption sites wit
hin small pores, which are small enough to exclude hydrolytic enzymes
and hence protect organic matter against biological attack. The relati
onship between this hypothesis and other hypothesized protection mecha
nisms is discussed. Adsorption is shown to provide a mechanistic and q
uantitative explanation for spatial and temporal relationships between
sedimentation rate and OC burial.