TY - JOUR
T1 - Photosynthetic characteristics in canopies of Quercus rubra, Quercus prinus and Acer rubrum differ in response to soil water availability
AU - Turnbull, Matthew H.
AU - Whitehead, David
AU - Tissue, David T.
AU - Schuster, William S. F.
AU - Brown, Kim J.
AU - Engel, Victor C.
AU - Griffin, Kevin L.
PY - 2002
Y1 - 2002
N2 - Photosynthesis and related leaf characteristics were measured in canopies of co-occurring Quercus rubra L. (red oak), Quercus prinus L. (chestnut oak) and Acer rubrum L. (red maple) trees. Mature (20+ m tall) trees were investigated at sites of differing soil water availability within a catchment (a drier upper site and a wetter lower site). Leaf photosynthetic characteristics differed significantly between species and in response to site and position in the canopy. Photosynthetic capacity (A
max) was significantly greater at the wetter site in all canopy strata in A. rubrum but not in Q. rubra or Q. prinus. Our findings for A. rubrum are generally consistent with those predicting that species with higher specific leaf area (SLA) will have higher A
max per unit leaf nitrogen (N) and that species with leaves with lower SLA (e.g.Q. rubra and Q. prinus) will have shallower slopes of the A
max - N relationship. Importantly, the relationships between A
max and N
area (and by implication photosynthetic nitrogen-use efficiency, PNUE) differed in A. rubrum between the sites, with PNUE significantly lower at the drier site. The lower photosynthetic capacity and PNUE must substantially reduce carbon acquisition capacity in A. rubrum under these field conditions. Maximum stomatal conductance (g
smax) differed significantly between species, with g
smax greatest in Q. rubra and Q. prinus. In Q. rubra and Q. prinus, g
smax was significantly lower at the upper site than the lower site. There was no significant response of g
smax to site in A. rubrum. These stomatal responses were consistent with the C
i/C
a ratio, which was significantly lower in leaves of Q. rubra and Q. prinus at the upper site, but did not differ between sites in A. rubrum. Leaf δ
13C was significantly lower in A. rubrum than in either Q. rubra or Q. prinus at both sites. These findings indicate differences in stomatal behaviour in A. rubrum which are likely to contribute to lower water use efficiency at both sites. Our results support the hypothesis that the two Quercus species, in contrast to A. rubrum, maintain photosynthetic capacity at the drier site whilst minimising transpirational water loss. They also suggest, based primarily on physiological evidence, that the ability of A. rubrum to compete with other species of these deciduous forests may be limited, particularly in sites of low moisture availability and during low rainfall years.
AB - Photosynthesis and related leaf characteristics were measured in canopies of co-occurring Quercus rubra L. (red oak), Quercus prinus L. (chestnut oak) and Acer rubrum L. (red maple) trees. Mature (20+ m tall) trees were investigated at sites of differing soil water availability within a catchment (a drier upper site and a wetter lower site). Leaf photosynthetic characteristics differed significantly between species and in response to site and position in the canopy. Photosynthetic capacity (A
max) was significantly greater at the wetter site in all canopy strata in A. rubrum but not in Q. rubra or Q. prinus. Our findings for A. rubrum are generally consistent with those predicting that species with higher specific leaf area (SLA) will have higher A
max per unit leaf nitrogen (N) and that species with leaves with lower SLA (e.g.Q. rubra and Q. prinus) will have shallower slopes of the A
max - N relationship. Importantly, the relationships between A
max and N
area (and by implication photosynthetic nitrogen-use efficiency, PNUE) differed in A. rubrum between the sites, with PNUE significantly lower at the drier site. The lower photosynthetic capacity and PNUE must substantially reduce carbon acquisition capacity in A. rubrum under these field conditions. Maximum stomatal conductance (g
smax) differed significantly between species, with g
smax greatest in Q. rubra and Q. prinus. In Q. rubra and Q. prinus, g
smax was significantly lower at the upper site than the lower site. There was no significant response of g
smax to site in A. rubrum. These stomatal responses were consistent with the C
i/C
a ratio, which was significantly lower in leaves of Q. rubra and Q. prinus at the upper site, but did not differ between sites in A. rubrum. Leaf δ
13C was significantly lower in A. rubrum than in either Q. rubra or Q. prinus at both sites. These findings indicate differences in stomatal behaviour in A. rubrum which are likely to contribute to lower water use efficiency at both sites. Our results support the hypothesis that the two Quercus species, in contrast to A. rubrum, maintain photosynthetic capacity at the drier site whilst minimising transpirational water loss. They also suggest, based primarily on physiological evidence, that the ability of A. rubrum to compete with other species of these deciduous forests may be limited, particularly in sites of low moisture availability and during low rainfall years.
KW - deciduous forest
KW - forest trees
KW - photosynthesis
KW - root-zone water content
KW - stomatal conductance
KW - Deciduous forest
KW - Root-zone water content
KW - Stomatal conductance
KW - Photosynthesis
UR - http://handle.uws.edu.au:8081/1959.7/34693
UR - http://www.scopus.com/inward/record.url?scp=0036941710&partnerID=8YFLogxK
M3 - Article
SN - 0029-8549
VL - 130
SP - 515
EP - 524
JO - Oecologia
JF - Oecologia
IS - 4
ER -