Foliage and wood parameters of branches of 12-year-old loblolly pine (
Pinus taeda L.) trees were characterized after 21 months of exposure t
o fertilizer, irrigation and elevated CO2 treatments. Branches of lobl
olly pine trees were enclosed in plastic chambers and exposed to ambie
nt, ambient +175 and ambient +350 umol mol(-1) CO2 concentrations. Mea
surements of foliage and wood at the fascicle, flush and branch levels
were made at the end of the 21 month study period. The +350 CO2 treat
ment did not significantly increase fascicle radius or length but did
increase the number of fascicles on the first flush. Fertilization sig
nificantly increased fascicle radius and length, while irrigation sign
ificantly increased number of fascicles and flush length of first flus
h. The +350 CO2 treatment also significantly increased flush length of
the first flush. Significant interaction of fertilization and irrigat
ion with CO2 was observed for fascicle length. Significant interaction
s of fertilization and irrigation were also observed for flush length,
number of fascicles and fascicle length. Observed increases in fascic
le radius, fascicle length, number of fascicles and flush length may h
ave been responsible for the significantly higher flush leaf area obse
rved for the all three treatments. Also, a combination of fertilizatio
n and irrigation increased leaf area by 82% compared to that in the co
ntrol when averaged across CO2 treatments. At the branch level +350 CO
2 treatment significantly increased shoot length but not the number of
flushes on the branch. In general with the exception of bark density
and total number of needle scales, neither fertilization nor irrigatio
n had any significant effect on other branch level parameters. Results
from this study indicate that with 'global change' an increase in CO2
alone may increase leaf area via an increase in flush length and numb
er of fascicles. Combining increases in CO2 with fertilization and irr
igation could greatly enhance leaf area which when coupled to observed
increases in net photosynthesis as a result of elevated CO2 could gre
atly increase productivity of loblolly pine trees.