Vegetation and soil properties were described across a well-dated sand
-dune chronosequence bordering northern Lake Michigan to document patt
erns and rates of primary succession and forest ecosystem development,
and to determine environmental constraints that potentially drive suc
cession and regulate species diversity. The site experienced frequent
and continuing formation of 72 shore-parallel dune ridges over the pas
t 2375 yr. Across the chronosequence represented by the youngest 13 du
ne ridges aged 25-440 yr, there were clear patterns of species turnove
r and community convergence as well as successional changes in species
diversity, aboveground biomass, aboveground litter production, net ec
osystem production, nutrient pools, and nutrient cycling. Dune-buildin
g species were replaced by evergreen shrubs and bunchgrass within 100
yr, which in turn, were replaced by mixed pine forest within 345 yr. P
lant-species richness increased to a peak in developing forest at 285
yr but thereafter decreased as early-successional species disappeared
from the communities. Rates of species addition peaked between 95 and
145 yr as forest species invaded, whereas rates of species loss peaked
between 345 and 440 yr as early-successional species were lost from t
he developing forest. Development of the forest ecosystem required sim
ilar to 300 yr (i.e., 145-440 years). Total ecosystem carbon increased
in a logistic manner to 128 Mg C/ha, with net ecosystem production pe
aking at 30 g C.m(-2).yr(-1) in developing forest. Aboveground biomass
and O horizon mass increased to similar to 137 Mg/ha and similar to 7
9 Mg/ha, respectively, whereas aboveground litter production increased
to 3.5 Mg.ha(-1).yr(-1) at 440 yr, but thereafter varied between 175
and 350 Mg.ha(-1).yr(-1). Total carbon and total nitrogen in the upper
15 cm of mineral soil and O horizon accumulated to similar to 42 Mg/h
a and similar to 1.36 Mg/ha, respectively. Estimated average rates of
carbon and nitrogen accumulation over 440 yr of ecosystem aggradation
were 23.2 g.m(-2).yr(-1) for carbon and 0.38 g.m(-2).yr(-1) for nitrog
en. Because nitrogen-fixing plants are rare on the upland dune ridges,
ecosystem aggradation depends largely on atmospheric nitrogen inputs.
Following colonization by conifers, soil acidification resulted in ra
pid leaching losses of calcium and magnesium, whereas phosphorus and p
otassium were cycled more tightly. The dune chronosequence represents
a complex gradient of changing environmental constraints that differen
tially reduce the survival, growth, and reproduction of plant species.
Young dune ridges near the lake shore are characterized by strong win
ds, sand burial and erosion, high insolation, high rates of evaporatio
n, and low availability of nitrogen and phosphorus. These conditions a
meliorate with increasing dune age as wind velocities and sand movemen
t diminish with distance from the lake, as accumulating organic matter
improves the moisture-holding capacity and nitrogen availability of t
he soil, and as mineral weathering mobilizes soil phosphorus. However,
in developing forest, light and cationic nutrients may become limitin
g, and decreased light availability, cool soil temperatures, and accum
ulation of a thick forest floor may limit recruitment from seed for ma
ny species. These numerous potential environmental constraints suggest
a considerable complexity in this ostensibly simple ecosystem.