R. Ceulemans et al., EFFECTS OF ELEVATED ATMOSPHERIC CO2 ON GROWTH, BIOMASS PRODUCTION ANDNITROGEN ALLOCATION OF 2 POPULUS CLONES, Journal of biogeography, 22(2-3), 1995, pp. 261-268
Two hybrid poplar (Populus) clones (i.e. fast growing clone Beaupre an
d slower growing clone Robusta) were grown from cuttings at close spac
ings in four open top chambers (OTCs) on the Campus of the University
of Antwerpen, Belgium. The four OTCs represented two atmospheric CO2 t
reatments, i.e. ambient and elevated (= ambient + 350 mu mol mol(-1)).
Treatments lasted for a full growing season (April-November 1993) and
results of the first growing season are being reported. In both clone
s the elevated CO2 treatment resulted in a significant increase in pla
nt height and in biomass production, both of stems and branches. Plant
s of both clones produced significantly more, but shorter, side branch
es under the elevated CO2 treatment. In terms of biomass accumulation
the slower growing clone Robusta benefited relatively more (+ 37%) fro
m the elevated CO2 concentrations than the fast growing clone Beaupre
(+ 24%). In terms of leaf weight ratio, the slower growing clone becam
e relatively more efficient under elevated CO2 than the fast growing c
lone. The elevated atmospheric CO2 treatment significantly increased t
he total leaf area per plant and leaf area index per OTC; maximum LAI
increased by 18% in clone Beaupre and by only 8% in the slower growing
clone Robusta. In the fast growing elope the increase in leaf area in
dex was entirely caused by an increase in individual leaf area, while
in the slower growing clone also a 5% higher leaf production was obser
ved under the elevated CO2. The total length of the growing season was
on average reduced by the elevated CO2 treatment; in the slower growi
ng clone mainly by an advancement of bud set and in the faster growing
clone by a slight delay of bud break in early spring. In both clones
elevated CO2 decreased nitrogen concentration and increased C/N ratio
in all plant organs, but no data for the below-ground compartment were
available. Therefore, although similar trends in the responses to ele
vated atmospheric CO2 were observed in both clones, the relative effic
iency of these responses differed between the fast and the slower grow
ing poplar clones, suggesting interactions between growth rate, growth
strategy and response to elevated atmospheric CO2.