Tree plantations are an important component of tropical landscapes, providi
ng wood, fuel, and perhaps carbon (C) sequestration. Primary production in
wet tropical plantations is typically nutrient limited. In some Hawaiian Eu
calyptus plantations, nitrogen (N) limitations to production are alleviated
by intercropping N-fixing Albizia trees that may decrease available phosph
orus (P). Thus, sustainable productivity and C sequestration may depend on
species composition. We measured soil N and P availability and ecosystem N
and C sequestration in a 17-yr-old replicated replacement series of Eucalyp
tus and Albizia in Hawaii. Species composition included pure plots of each
species and four proportions of mixtures. Soil N availability increased wit
h the proportion of Albizia in the plot, but soil P availability declined.
Aboveground tree C accumulation showed a synergistic response to increasing
percentage of Albizia, with the mixed stands having more tree C than pure
stands of Eucalyptus or Albizia. In the top 50 cm of soil, total N and C in
creased linearly with percentage of Albizia. Stands with the highest percen
tage of Albizia had 230 g/m(2) mole soil N and 2000 g/m(2) more soil C than
stands without Albizia. Stable C isotope analyses showed that increased so
il C resulted from differences in both tree-derived C and "old" sugarcane-d
erived C. Deeper soil C (50-100 cm) was a substantial fraction (0.36) of to
tal soil C but did not vary among treatments. Our results demonstrate that
tree species effects on nutrient and C dynamics are not as simple as monocu
ltures suggest. Mixed-species afforestation increased tree and soil C accru
al over 17 years, and N inputs may increase soil C storage by decreasing de
composition.