共查询到20条相似文献,搜索用时 343 毫秒
1.
Plant growth, biomass allocation, carbon isotope composition (δ13C), and water use efficiency (WUE) of 31 cultivars of apple (Malus domestica Borkh.) grown under two water regimes were measured. Drought-stressed plants showed significant declines in tree height,
trunk diameter, biomass production, and total leaf area, the extent to which depended upon cultivar. Also, gas exchange rates,
instantaneous and long-term efficiencies (WUEI and WUEL, respectively), and values for δ13C differed among cultivars and watering regimes. Variations in WUEI were mainly due to changes in stomatal conductance (g
s) under drought condition. ‘Qinguan’ and ‘Golden Delicious’ had greater trunk diameter, tree height, and had higher biomass
production and WUEL under drought stress, implying that they are more suitable for arid and semi-arid regions. Moreover, WUEL was significantly and positively correlated with δ13C under two watering regimes, which suggests a potential for evaluating water use efficiency of Malus by measuring carbon isotope composition. 相似文献
2.
Fengjun Zhao Rongfu Gao Yingbai Shen Xiaohua Su Bingyu Zhang 《Frontiers of Forestry in China》2006,1(1):89-94
Foliar carbon isotope composition (δ
13C), total dry biomass, and long-term water use efficiency (WUEL) of 12 Populus deltoids clones were studied under water stress in a greenhouse. Total dry biomass of clones decreased greatly, while δ
13C increased. Single-element variance analysis in the same water treatment indicated that WUEL difference among clones was significant. Clones J2, J6, J7, J8, and J9 were excellent with high WUEL. Extremely significant δ
13C differences among water treatments and clones were revealed by two-element variance analysis. Water proved to be the primary
factor affecting δ
13C under water stress. It showed that there was a good positive correlation between δ
13C and WUEL in the same water treatment, and that a high WUEL always coincided with a high δ
13C. δ
13C might be a reliable indirect index to estimate WUEL among P. deltoids clones.
Translated from Scientia Silvae Sinicae, 2005, 41(1) (in Chinese) 相似文献
3.
Spiraea pubescens, a common shrub in the warm-temperate deciduous forest zone which is distributed in the Dongling Mountain area of Beijing,
was exposed to ambient and enhanced ultraviolet-B (UV-B, 280–320 nm) radiation by artificially supplying a daily dose of 9.4
kJ/m2 for three growing seasons, a level that simulated a 17% depletion in stratospheric ozone. The objective of this study was
to explore the effects of long-term UV-B enhancement on stomatal conductance, leaf tissue δ
13C, leaf water content, and leaf area. Particular attention was paid to the effects of UV-B radiation on water use efficiency
(WUE) and leaf total nitrogen content. Enhanced UV-B radiation significantly reduced leaf area (50.1%) but increased leaf
total nitrogen content (102%). These changes were associated with a decrease in stomatal conductance (16.1%) and intercellular
CO2 concentration/ air CO2 concentration (C
i
/C
a) (4.0%), and an increase in leaf tissue δ
13C (20.5‰), leaf water content (3.1%), specific leaf weight (SLW) (5.2%) and WUE (4.1%). The effects of UV-B on the plant were
greatly affected by the water content of the deep soil (30–40 cm). During the dry season, differences in the stomatal conductance,
δ
13C, and WUE between the control and UV-B treated shrubs were very small; whereas, differences became much greater when soil
water stress disappeared. Furthermore, the effects of UV-B became much less significant as the treatment period progressed
over the three growing seasons. Correlation analysis showed that enhanced UV-B radiation decreased the strength of the correlation
between soil water content and leaf water content, δ
13C, C
i/C
a, stomatal conductance, with the exception of WUE that had a significant correlation coefficient with soil water content.
These results suggest that WUE would become more sensitive to soil water variation due to UV-B radiation. Based on this experiment,
it was found that enhanced UV-B radiation had much more significant effects on morphological traits and growth of S. pubescens than hydro-physiological characteristics.
__________
Translated from Journal of Plant Ecology, 2006, 30(1): 47–56 [译自: 植物生态学报] 相似文献
4.
《Forest Ecology and Management》2006,221(1-3):285-290
Population differences in dry matter accumulation and allocation, conifer leaf nitrogen status, stomata parameters and water use efficiency were studied in a 7-year-old Picea asperata Mast. plantation that contains seven populations grown from seed collected from different altitudes in the mountains of southwestern China. In our study, we measured dry matter accumulation (DMA), total projected leaf area (LA), specific projected leaf area (SLA), root/shoot ratio (RS), root mass/projected leaf area ratio (R/LA), projected leaf area/stem cross-sectional area ratio (LA/SA), leaf stomatal density (SD), stomatal length (SL) and total stomatal length (TSL), nitrogen content per unit leaf mass (Nmass) and nitrogen content per unit projected leaf area (Narea), and carbon isotope composition (δ13C). Significant differences in these properties among the populations were detected, but these morphological and physiological responses to altitudinal gradients of origins varied non-linearly with increasing altitude. We found that seed source near 2950 m altitude was likely an optimum zone for P. asperata; growth was most vigorous at this altitude, and with increasing altitudinal distance from this optimum the growth decrease. In addition, seedling early growth, including DMA and LA, negatively correlated with RS, R/LA, Nmass, Narea and δ13C, and positively correlated with SLA, LA/SA, SD, SL and TSL. Our results provided strong evidence that variations in these physiological and morphological properties of P. asperata populations reflected genetic adaptations to native habitats. These differences may be used as criteria for genotype selection in the mountains of southwestern China. 相似文献
5.
Seedlings grown under different N supply were examined for relationships between root system size attributes and its hydraulic properties. These relationships were also studied on seedlings of different stock types (grown in different container types). Measurements with root pressure probes were taken at various times after germination, under applied hydrostatic pressure and non-limiting soil moisture. Different N-treatments and stock types were used solely to produce seedling of different sizes, especially root system sizes. Specific root hydraulic conductivity (Lpr) typically declined with an increasing root system size and correlations between Lpr and the root system size attributes were often negative. The flow of water through the root system correlated well with root system size attributes only in young (3–4 month old) seedlings but the correlations were inconsistent among different N treatments and stock types. Neither the root system surface area nor dry weight reliably reflected its ability to absorb and conduct water. Generally, the amount of water delivered through the root system and available for transpiration per unit or leaf surface area or unit of leaf dry weight correlated poorly or negatively with the root system size. Practical and scientific implications of the findings are discussed.
*Paper presented at Forest Seedling Root Development Conference: From the Nursery to the Field, Eugene, Oregon, May 12–13, 2004. 相似文献
6.
Takuya Kajimoto Akira Osawa Yojiro Matsuura Anatoly P. Abaimov Olga A. Zyryanova Kazuma Kondo Naoko Tokuchi Muneto Hirobe 《Journal of Forest Research》2007,12(2):103-112
We present results of individual-based root system measurement and analysis applied for Larix gmelinii trees growing on the continuous permafrost region of central Siberia. The data of root excavation taken from the three stands
were used for the analyses; young (26 years old), mature (105 years old), and uneven-aged over-mature stand (220 years old).
In this article, we highlight two topics: (1) factors affecting spatio-temporal pattern of root system development, and (2)
interactions between aboveground (i.e., crown) and belowground (i.e., root) competition. For the first topic, the detailed
observation of lateral roots was applied to one sample tree of the overmature stand. The tree constructed a superficial (<30 cm
in depth) and rather asymmetric root system, and each lateral root expanded mainly into elevated mounds rather than depressed
troughs. This indicated that spatial development of an individual root system was largely affected by microtopography (i.e.,
earth hummocks). For these lateral roots, elongation growth curves were reconstructed using annual-ring data, and annual growth
rates and patterns were compared among them. The comparison suggested that temporal root system development is associated
with differences in carbon allocation among the lateral roots. For the second topic, we examined relationships between individual
crown projection area (CA) and horizontal rooting area (RA) for the sample trees of each stand. RA was almost equal to CA
in the young stand, while RA was much larger (three or four times) than CA in the mature and overmature stands. Two measures
of stand-level space occupation, crown area index (aboveground: CAI; sum of CAs per unit land area) and rooting area index
(belowground: RAI; sum of RAs), were estimated in each stand. The estimates of RAI (1.3–1.8 m2 m−2) exceeded unity in all stands. In contrast, CAI exceeded unity (1.3 m2 m−2) only in the young stand, and was much smaller (<0.3 m2 m−2) in the two older stands. These between-stand differences in RAI–CAI relationships suggest that intertree competition for
both aboveground and belowground spaces occurred in the young stand, but only belowground competition still occurred in the
two older stands. Based on this finding, we hypothesized that competition below the ground may become predominant as a stand
ages in L. gmelinii forests. Methodological limitations of our analysis are also discussed, especially for the analysis using the two indices
of space occupation (CAI, RAI). 相似文献
7.
采用盆栽控制试验,研究了不同浓度(0、60、120和180 mmol·L-1)Na2SO4胁迫对沙枣幼苗生长和光合特性的影响。结果表明:(1)盐胁迫对沙枣幼苗生长具有显著的抑制效应。不同浓度Na2SO4胁迫沙枣的株高、侧枝数、总叶面积、单株叶片数、比叶面积以及各组织(除根)生物量均显著低于对照,且均随盐胁迫浓度的升高呈下降趋势,而根冠比值则由对照的0.153 1显著增加到180 mmol·L-1Na2SO4胁迫幼苗的0.348 7。(2)盐胁迫显著降低了沙枣幼苗的光合能力。随着Na2SO4胁迫的加剧,净光合速率(Pn)、气孔导度(Gs)、胞间CO2浓度(Ci)和蒸腾速率(Tr)均呈下降的趋势,而气孔限制值(Ls)和水分利用效率(WUE)则依次增加,且Pn下降主要受气孔限制;180 mmol·L-1Na2SO4胁迫沙枣幼苗的Pn、Gs、Ci和Tr分别为对照的71.57%、30.85%、67.15%和51.65%,而Ls和WUE则分别为对照的1.91、1.38倍。(3)盐胁迫强度与幼苗株高、总叶面积、单株叶片数、比叶面积、茎生物量、叶生物量、总生物量等生长指标以及Pn、Gs、Ci、Tr等光合参数呈极显著负相关,叶片的光合参数与总叶面积、单株叶片数呈显著或极显著正相关,而叶片的生长指标、光合参数与幼苗的株高生长和生物量累积也呈显著或极显著正相关。 相似文献
8.
Yanwei Lu Baoli Duan Xiaolu Zhang Helena Korpelainen Frank Berninger Chunyang Li 《Annals of Forest Science》2009,66(6):613-613
9.
Barnes AD 《Tree physiology》2002,22(10):733-740
One-year-old loblolly pine (Pinus taeda L.) seedlings from four seed sources (Arkansas, Georgia, Texas and Virginia) grown in 1-m-deep sand-filled pits in two water regimes (well-watered and drought) were studied, to gain insight into the process of seedling establishment. Whole-plant transpiration was measured biweekly from July to December. Whole-plant harvests were conducted at 6-week intervals from April to December. Whole-plant transpiration and transpiration per unit leaf and root area were affected by treatment, seedlot and phenology. Seedlings of the Arkansas seedlot maintained significantly higher transpiration rates per unit leaf and root area during drought than seedlings of the Virginia, Georgia or Texas seedlots, but did not accumulate greater biomass. The high transpiration rates of the Arkansas seedlings were attributed to their deep root systems. Allometric relationships indicated that, relative to the whole plant, biomass allocation to needles of drought-treated seedlings was enhanced during the summer (allometric ratio 1.09), whereas allocation to roots was enhanced in the spring and fall (allometric ratios of 1.13 and 1.09, respectively). Relative to the whole plant, biomass allocation to needles of well-watered seedlings was enhanced throughout the experiment (allometric ratio of 1.16 declining to 1.05), whereas the allometric ratio of root to total biomass was 0.89 or less throughout. Allometric relationships also indicated variation in biomass partitioning to roots in three soil layers (0-30, 30-60 and 60-100 cm), which differed among harvests in each soil layer. Root growth in both well-watered and drought-treated seedlings was concentrated in the top soil layer in the spring, shifted to the middle and bottom soil layers in the summer, and then increased in the top soil layer in the fall. Compared with well-watered seedlings, drought-treated seedlings had higher rates of root growth in the bottom soil layer in the fall, a characteristic that would confer tolerance to future periods of limited soil water availability. 相似文献
10.
11.
Lvliu Zou Guchou Sun Ping Zhao Xi’an Cai Xiaoping Zeng Xiaojing Liu 《Frontiers of Forestry in China》2009,4(2):201-207
Using the PMS pressure chamber and isotope mass spectrometer (MAT-252), the leaf juice of Acacia mangium was obtained, and the carbon isotope discrimination (D) representing the most recently fixed carbon in the juice was determined.
At the same time, the water-use efficiency of A. mangium was estimated. The results indicated that the carbon isotope ratio in the air of forest canopy (δ
a), 10 m high a bove ground averaged − 7.57 ± 1.41 ‰ in cloudy days, and − 8.54±0.67‰ in sunny days, respectively. The diurnal
change of the carbon isotope ratio in the photosynthetic products of the leaf juice (δ
p) was of saddle type in cloudy days, but dropped down from morning to later afternoon in sunny days. A strong negative correlation
between δ
p and leaf-to-air vapor pressure deficit (D) was observed in sunny days, but a slight change in δ
p was found in cloudy days. The δ
p also decreased with decreasing leaf water potential (Ψ), reflecting that water stress could cause the decrease of δ
p. The carbon isotope discrimination of the leaf juice was positively correlated with the ratio between intercellular (P
i) and atmospheric (P
a) partial pressure of CO2. For A. mangium, the isotope effect on diffusion of atmospheric CO2 via stomata was denoted by a = 4.6‰, and that in net C3 diffusion with respect to P
i was indicated by b = 28.2‰. The results were in reasonable accord with the theoretically diffusive and biochemical fractionation of carbon isotope.
It was defined that carbon isotope discrimination of photosynthetic products in A. mangium leaf juice was in proportion to that from photosynthetic products in dry material. The water-use efficiency estimated by
the carbon isotope discrimination in leaf juice, fit well with that measured by gas exchange system (R
2 = 0.86, p < 0.0001). The application of leaf juice in measuring the stable carbon isotope discrimination would reduce the effects of
fluctuating environmental factors during the synthesis of dry matter, and improve the ecophysiological studies on carbon and
water balance when scaling from the plant to canopy in the fields.
__________
Translated from Chinese Journal of Ecology, 2008, 27(4): 497–503 [译自: 生态学杂志] 相似文献
12.
Growth and physiological performance of multipurpose tree species can be severely constrained by low phosphorus (P) availability
in highly weathered soils. Limitations to plant growth are accentuated by seasonal dry periods. The overall objective of this
study was to examine P fertilization and irrigation effects on survival, growth, biomass partitioning, foliar nutrients, intrinsic
water-use efficiency (WUE) indexed by δ13C, Rhizobium nodulation, and carbohydrate content as an indicator of resprouting potential, of mimosa (Albizia julibrissin Durz.), a N2-fixing tree species being tested for browse in agroforestry practices in south-central USA. In a field experiment carried
out during two growing seasons near Booneville, Arkansas, USA, mimosa had a strong growth response to irrigation. The trial
was arranged in a split plot design with three replications with irrigation as main plot treatment and P as sub-plot treatment.
Mean total plant aboveground biomass at the end of the second growing season was 9.8 and 44.1 g plant−1 for the rainfed treatment without and with 300 mm of irrigation water, respectively. Placed P fertilization increased mean
total aboveground biomass from 19 g plant−1 for the 0-P treatment to 69 g plant−1 for the treatment with 90 kg P ha−1 year−1. Similarly, irrigation consistently increased stem basal diameter, total height, survival, root, stem, foliar and total aboveground
biomass, and number of nodules per plant. Phosphorus fertilization increased basal diameter, and root and stem biomass in
both irrigation treatments, survival and nodulation in the rainfed treatment, and foliar and total aboveground biomass in
the rainfed +300 mm irrigation treatment. There was a decrease of foliar δ13C suggesting that WUE decreased with P fertilization. In a pot experiment, seedlings were subjected to a factorial combination
of two irrigation treatments and six P levels in a randomized complete block design. Irrigation increased basal diameter,
root, stem, foliar and total biomass, leaf area and nodulation, whereas P fertilization (i.e., levels from 0 to 3.68 g P kg−1 soil) had similar effect in all the above variables except foliar biomass. Foliar P concentration to obtain 90% of the maximum
total plant biomass (critical level) was estimated at 0.157%. Total nonstructural and water soluble carbohydrate, and starch
concentrations increased non-linearly with irrigation and P addition suggesting impaired re-growth potential after defoliation
of seedlings with reduced water supply and at low soil P availability. Results of this study indicated strong limitations
for growth and regrowth potential of mimosa on a highly weathered soil with very low P availability and seasonal water content
shortages. Placed (i.e., near the plant base) application of P appeared to be a good strategy to fertilize perennial woody
plants. 相似文献
13.
· Key message
We observed coordinated differences in water-use efficiency, 13 C isotope composition, and whole-plant transpiration efficiency among nine Acacia species, although the up scaling from leaf to whole-plant level resulted in different relationships in Sahelian and Australian species.· Context
The genus Acacia sensu lato contains a large variety of tropical to Mediterranean species adapted to habitats ranging from mesic to arid in Africa and Australia.· Aims
We checked whether transpiration efficiency differed among a range of nine Sahelian and Australian species and whether it was related to the degree of aridity of the original area or to their type of foliage (pinnate leaves or phyllodes).· Methods
Intrinsic water-use efficiency (W I) was recorded from leaf gas exchange and whole-plant transpiration efficiency (TE) from biomass production and water consumption of potted seedlings. Both W I and TE were compared to 13C discrimination (Δ13C) computed from either bulk foliage or extracted cellulose.· Results
At leaf level, Δ13C matched closely W I across species, while at the whole-plant level, the relationship between TE and either Δ13C or W I differed between the Sahelian and the Australian species. Large interspecific differences were found but they were not related to the aridity of the origin nor to the type of foliage.· Conclusion
Δ13C captured well the variability of W I among several Acacia species while species differences in carbon-use efficiency (the fraction of carbon assimilated recovered in plant biomass) or the relative nocturnal transpiration may disrupt the relationship between TE and Δ13C.14.
Satish Chandra Garkoti 《Journal of Forest Research》2011,16(2):136-143
Fine root biomass, rates of dry matter production and nutrients dynamics were estimated for 1 year in three high elevation
forests of the Indian central Himalaya. Fine root biomass and productivity were higher in closed canopied cappadocian maple
forest (9.92 Mg ha−1 and 6.34 Mg ha−1 year−1, respectively), followed by Himalayan birch forest (6.35 Mg ha−1 and 4.44 Mg ha−1 year−1) and Bell rhododendron forest (6.23 Mg ha−1 and 2.94 Mg ha−1 year−1). Both fine root biomass and productivity declined with an increase in elevation. Across the sites, fine root biomass was
maximal in fall and minimal in summer. In all sites, maximum nutrient concentration in fine roots was in the rainy season
and minimum in winter. Fine root biomass per unit basal area was positively related with elevation, Bell rhododendron forest
having the largest fine root biomass per unit of basal area (0.53 Mg m−2) and cappadocian maple the least (0.18 Mg m−2). The production efficiency of fine roots per unit of leaf biomass also increased with elevation and ranged from 1.13 g g−1 leaf mass year−1 in cappadocian maple forest to 1.28 g g−1 leaf mass year−1 in Bell rhododendron forest. Present fine root turnover estimates showed a decline towards higher elevations (0.72 year−1 in cappadocian maple and 0.58 year−1 in Bell rhododendron forest) and are higher than global estimates (0.52). 相似文献
15.
F. S. Carevic M. Fernández R. Alejano J. Vázquez-Piqué R. Tapias E. Corral J. Domingo 《Agroforestry Systems》2010,78(3):299-308
Acorn production patterns and the annual evolution of water relations parameters of Quercus ilex ssp. ballota (Desf.) Samp. in a dehesa (an open woodland forest) subject to various soil treatments (ploughing, ploughing + sowing, control)
were studied in southwest Spain from June 2006 to December 2008. The effects of soil water holding capacity and effective
soil depth on soil and plant water status and acorn production were also investigated. Water parameters showed significant
differences between the ploughing treatment and the control, and there were also significant temporal differences. Xylem water
potential ranged from −3.4 ± 0.1 to −0.7 ± 0.2 MPa, and cuticular transpiration was 62.4–192.9 mmol H2O kg−1 s−1. Acorn production did not differ significantly according to soil treatment, and showed large intra-specific variability.
Individual values ranged from 0 to 1,220 g m−2 (fresh weight). Positive relationships were found between xylem water potential, cuticular transpiration and relative water
content measured at midsummer, and acorn production during the three studied years. These results suggest that climatic conditions
and soil water availability have a strong influence on plant water status, and therefore on acorn development during summer.
The results also reflect the ability of this species to adapt to the Mediterranean climate by preserving water during dry
periods, which to a large extent can be attributed to stomatal closure at high relative water content levels, and low cuticular
transpiration during these periods. 相似文献
16.
Asia Khamzina John P. A. Lamers Christopher Martius Martin Worbes Paul L. G. Vlek 《Agroforestry Systems》2006,68(2):151-165
This paper evaluates the potential of nine multipurpose tree species for afforestation of degraded land in the Khorezm region, Central Asia, particularly their suitability for biodrainage i.e., lowering the elevated groundwater table through the transpirative capacity of plantations. For this purpose water use (WU), water use efficiency (WUE) and tree physiological factors influencing transpiration were assessed during two consecutive years. Mean daily leaf transpiration differed significantly among the species and ranged during the seasons from 4.5–5.2 mmol m−2 s−1 for Prunus armeniaca L. to 4.5–10 mmol −2 s−1 for Elaeagnus angustifolia L. WU differences were triggered by species physiological features such as capability of water uptake by roots. Transpiration rates and the length of fine roots correlated highly (r = 0.7). Correlations of leaf transpiration rates with leaf area were weaker (r = 0.6). No correlations were found between salt content in plants and water uptake under conditions of slight-to-moderate rootzone soil salinity. Values of WUE per root and shoot DM were similar averaging, respectively, 0.2 and 0.3 g DM g−1 water for two-year-old trees, and decreased with age. In addition to WU characteristics, also salinity tolerance, growth rate and the ability to produce fodder and fuelwood must be considered during species selection. Regarding these features, the N-fixing E. angustifolia ranked the highest, combining high WU, fast growth and production of nutritious feed. Examined Populus spp. and Ulmus pumila L. ranked lower but still represented potential candidates for biodrainage purposes. Typical fruit species in the region such as P. armeniaca and Morus alba, showed low biodrainage potential. 相似文献
17.
Laura Rose Christoph Leuschner Benjamin Köckemann Holger Buschmann 《European Journal of Forest Research》2009,128(4):335-343
Due to the expected increases of number and intensity of summer droughts in Central Europe the identification of drought tolerant
ecotypes becomes more important in future forestry. A common garden experiment with seedlings of Fagus sylvatica provenances from the center (Germany) and eastern margin (Poland) of the species’ distribution range was conducted. Responses
of morphological, physiological, chemical and growth parameters to three drought treatments were analyzed. Relative growth
rates of the marginal provenance were lower as compared to the central provenance. The marginal seedlings showed a tendency
to higher total biomasses because of higher seed masses. In both provenances drought decreased biomass production and root/shoot
ratio which was lower in the central provenance. A lower specific root area of the marginal provenance indicated a better
adaptation to low xylem water potentials. Under moderate drought, lower leaf δ13C signatures may indicate lower stomatal limitation (or a reduced rate of CO2 assimilation) in the marginal provenance. We conclude that marginal beech provenances may exhibit a better drought adaptation. 相似文献
18.
Natalia S. A. Feijó Marcelo S. Mielke Fabio P. Gomes Solange Fran?a Alyne O. Lavinsky 《Agroforestry Systems》2009,77(1):49-58
We analyzed the growth and photosynthetic behavior of Gallesia integrifolia (‘pau-d’alho’) and Schinus terebinthifolius (‘aroeirinha’) under shade, seeking to obtain ecophysiological information for introducing seedlings of those species in
previously established cacao agroforestry systems. Considering that light intensity under the shade of cacao trees varied
between 5 and 10% daylight, 5 months old seedlings were exposed to four irradiance levels (25, 17, 10 and 5% daylight) for
92 days. With shade increase both species displayed trends of decrease leaf mass per unit leaf area, leaf area per plant (LA),
relative growth rate (RGR) and net assimilation rate (NAR), and increase leaf area ratio (LAR). The mean values of light-saturated
net photosynthetic rate (P
nmax) in 25 and 5% daylight were 12.8 and 8.0 μmol CO2 m−2 s−1 for G. integrifolia and 17.9 and 7.4 μmol CO2 m−2 s−1, respectively, for S. terebinthifolius. Based on the measurements of photosynthetic photon flux density and estimated values of photosynthetic saturated irradiance
(Is) we concluded that, in all shaded conditions, the leaves of both species were under sub optimal light conditions to reach
P
nmax. In spite of the lowest P
nmax values, RGR and NAR were significantly higher for G. integrifolia in all irradiance levels. Differences in growth rates can be explained by the higher values of LA, LAR and leaf mass ratio
(LMR), as well as by the lower values of Is, photosynthetic compensation irradiance and dark respiration rates observed for
G. integrifolia. Even though seedlings of G. integrifolia presented higher capacity to adapt under conditions of dense shade, we concluded that both species were under stress conditions
induced by shade in light environments below 25% daylight. On a practical point of view it is possible to conclude that seedlings
of both species should be introduced in light gaps, formed after the fall of big trees, or in places in which cacao trees
are cultivated using large plant spacing. 相似文献
19.
Variations in several growth, gas exchange and leaf traits among greenhouse-grown black locust (Robinia pseudoacacia L.) seedlings from 11 half-sib families were investigated. Three weeks after germination, early growth rates ranged from a minimum of 1 cm d(-1) in the slowest growing family, to a maximum of 3 cm d(-1) in the fastest growing family. Significant family variation in net photosynthetic rate per unit leaf area (P(N)), stomatal conductance, chlorophyll content, height, diameter, stem dry weight and total dry weight was observed. Net photosynthetic rate declined with seedling age. Net photosynthetic rate per unit leaf area was significantly correlated (r < 0.4) with specific leaf area, total chlorophyll, root dry weight, foliage dry weight and total dry weight. The correlation coefficients were higher (r >/= 0.55) between P(N) x total leaf area and growth traits (height, stem dry weight, foliage dry weight and total dry weight). The study indicated that variation in leaf area among the families was one reason for the lack of a strong relationship between P(N) and growth. 相似文献
20.
Conventional reforestation in the tropics often results in stands with low tree species and functional diversities. A different approach to reforestation, the so-called rainforestation, has been developed in the Philippines. It emphasizes mixed stands and the preferential use of native species supplemented by fruit trees. In such stands, we studied several functional leaf traits (stomatal conductance for water vapour, leaf morphology and chemistry) with the objectives (1) of assessing the species-specific variation of leaf traits and in particular that of maximal leaf stomatal conductance (gsmax), (2) of determining relationships between gsmax and other tree variables, and (3) of assessing whether leaf traits group the species studied. Sixteen broad-leaved species were studied, using five individual trees per species and ten fully expanded sunlit leaves per individual tree. Species-specific gsmax differed fivefold (165–772 mmol m−2 s−1). Among studied leaf traits, only the carbon isotope ratio δ13C exhibited a simple linear correlation with gsmax. A separate analysis for dipterocarp species indicated a strong negative relationship between gsmax and specific leaf area (SLA) (r2 = 0.96, P < 0.001, n = 5). For all 16 species, a multiple linear regression with the combinations leaf size/tree height and leaf size/canopy projection area also resulted in significant relationships, which partly explained the variability in gsmax. A multivariate approach (principal component analysis) combining the leaf traits provided an explanation of 75% of the variability along the first two axes. All native dipterocarps species, a native Guttiferae and the durian tree (Durio zibethinus) were associated with more depleted δ13C, small leaves and a low leaf width to length ratio. Two exotic species frequently used for reforestation (Gmelina arborea and Swietenia macrophylla) and the native early successional Terminalia microcarpa were differentiated by their high SLA and high leaf nitrogen content per leaf area (Narea). Both species of Artocarpus (A. blancoi and A. odoratissima) were also differentiated and had large leaves with low SLA and low Narea. These associations of species with leaf traits as variables indicate that species have different leaf investment strategies, which may imply that there are differences in whole plant performance. We conclude that rainforestation creates substantial variation in leaf traits, which is based on the combination of species with different leaf trait groupings. This can be seen as an important step towards – partly – restoring the functional diversity which characterizes many natural tropical rainforests. 相似文献