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1.
Hua Wang Ping Zhao Quan Wang Xian Cai Ling Ma Xingquan Rao Xiaoping Zeng 《Frontiers of Forestry in China》2008,3(1):72-78
In this paper, we studied the nocturnal stem water recharge of Acacia mangium. It is helpful to improve the precision of canopy transpiration estimation and canopy stomatal conductance, and to further
understand the lag time of canopy transpiration to stem sap flow. In this study, the whole-tree sap flow in an A. mangium forest was measured by using Granier’s thermal dissipation probe for over two years in the hilly land of South China. The
environmental factors, including relative humidity (RH), precipitation, vapor pressure deficit (VPD), photosynthetically active radiation (PAR), and air temperature (T
a) were recorded simultaneously. The stem water recharge of A. mangium was analyzed on both daily and monthly scales. Sap flux density was lower at night than during the day. The time range of
nighttime sap flux density was longer in the dry season than in the wet season. The water recharging mainly occurred from
sunset to midnight. No significant differences were observed among inter-annual nighttime water recharges. Nighttime water
recharge had no significant correlation with environmental factors, but was well correlated with the diameter at breast height,
tree height, and crown size. In the dry season the contribution of nighttime water recharge to total transpiration had significant
correlations with daytime transpiration, total transpiration, VPD, PAR and T
a, while in the wet season it was significantly correlated with daily transpiration and total transpiration.
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Translated from Chinese Journal of Ecology, 2007, 26(4): 476–482 [译自: 生态学杂志] 相似文献
2.
Hua Wang Ping Zhao Xi’an Cai Ling Ma Xingquan Rao Xiaoping Zeng Quan Wang 《Frontiers of Forestry in China》2009,4(2):191-200
We analyzed the partition of nocturnal sap flow into refilling of internal water storage and transpiration in Acacia mangium. Sap flow of trees was monitored continuously with Granier’s sensors for estimating the whole-tree transpiration. Possible
night transpiration and stomatal conductance at the leaf level in the canopy were measured with a LI-6400 photosynthesis measuring
system. For nocturnal leaf transpiration and stomatal conductance were weak, nocturnal sap flow of mature A. mangium trees was mainly associated with water recharge in the trunk. No significant change in night water recharge of the trunk
was found at both seasonal and inter-annual scales. Morphological features of trees including diameter at the breast height
(DBH), tree height, and canopy size could explain variances of night water recharge. Furthermore, although the contribution
of nocturnal sap flow to the total transpiration varied among seasons and DBH classes, the error caused by night water recharge
on wholetree transpiration was negligible.
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Translated from Journal of Plant Ecology (Chinese Version), 2007, 31 (5): 777–786 [译自: 植物生态学报] 相似文献
3.
Linking leaf and tree water use with an individual-tree model 总被引:2,自引:0,他引:2
We tested the ability of a model to scale gas exchange from leaf level to whole-tree level by: (1) measuring leaf gas exchange in the canopy of 10 trees in a tall Eucalyptus delegatensis RT Baker forest in NSW, Australia; (2) monitoring sap flow of the same 10 trees during the measurement week; and (3) using an individual-tree-based model (MAESTRA) to link the two sets of measurements. Photosynthesis and stomatal conductance components of the model were parameterized with the leaf gas exchange data, and canopy structure was parameterized with crown heights, dimensions and leaf areas of each of the measurement trees and up to 45 neighboring trees. Transpiration of the measurement trees was predicted by the model and compared with sap flow data. Leaf gas exchange parameters were similar for all 10 trees, with the exception of two smaller trees that had relatively low stomatal conductances. We hypothesize that these trees may have experienced water stress as a result of competition from large neighboring trees. The model performed well, and in most cases, was able to replicate the time course of tree transpiration. Maximum rates of transpiration were higher than measured rates for some trees and lower than measured rates for others, which may have been a result of inaccuracy in estimating tree leaf area. There was a small lag (about 15-30 minutes) between sap flow and modeled transpiration for some trees in the morning, likely associated with use of water stored in stems. The model also captured patterns of variation in sap flow among trees. Overall, the study confirms the ability of models to estimate forest canopy transpiration from leaf-level measurements. 相似文献
4.
Recently, canopy transpiration (Ec) has been often estimated by xylem sap-flow measurements. However, there is a significant time lag between sap flow measured at the base of the stem and canopy transpiration due to the capacitive exchange between the transpiration stream and stem water storage. Significant errors will be introduced in canopy conductance (gc) and canopy transpiration estimation if the time lag is neglected. In this study, a cross-correlation analysis was used to quantify the time lag, and the sap flow-based transpiration was measured to parameterize Jarvis-type models of gc and thus to simulate Ec of Populus cathayana using the Penman–Monteith equation. The results indicate that solar radiation (Rs) and vapor pressure deficit (VPD) are not fully coincident with sap flow and have an obvious lag effect; the sap flow lags behind Rs and precedes VPD, and there is a 1-h time shift between Ec and sap flow in the 30-min interval data set. A parameterized Jarvis-type gc model is suitable to predict P. cathayana transpiration and explains more than 80% of the variation observed in gc, and the relative error was less than 25%, which shows a preferable simulation effect. The root mean square error (RMSEs) between the predicted and measured Ec were 1.91 × 10?3 (with the time lag) and 3.12 × 10?3 cm h?1 (without the time lag). More importantly, Ec simulation precision that incorporates time lag is improved by 6% compared to the results without the time lag, with the mean relative error (MRE) of only 8.32% and the mean absolute error (MAE) of 1.48 × 10?3 cm h?1. 相似文献
5.
Responses of leaf conductance (g
L) to variation in environmental and plant hydraulic factors were examined on intact and detached shoots of little-leaf linden
(Tilia cordata Mill.) with respect to branch position in the crown. Using detached shoots, we manipulated leaf water supply and light availability
in order to separate the effects of insufficient hydraulic supply and low irradiance. The intact upper-crown leaves demonstrated
2.0–2.2 times higher (P < 0.001) daily maxima of g
L compared to the lower-crown leaves growing in the shadow of upper branches. Mean soil-to-leaf conductance (G
T) was 1.9 times higher (P < 0.001) for the upper-crown foliage compared to that of the lower crown. The total hydraulic resistance was distributed:
soil to distal shoots—41–51%, 25-cm distal shoots—10–15% and leaves—39–44%. In lower branches, g
L was constrained by both low light availability and limited water supply; in upper branches, only by irradiance. Artificial
reduction of hydraulic constraints raised bulk leaf water potential (Ψ
L) and made g
L less sensitive to changes in both atmospheric and plant factors. Stomatal responses to leaf-to-air vapour pressure difference
(VPD) were significantly modified by leaf water status: high Ψ
L seemingly inverted the g
L versus VPD relationship. Enhanced water supply increased g
L and transpiration rate (E) in the lower-crown foliage, but not in the upper-crown foliage. The results support the idea that leaves in the lower canopy
are hydraulically more constrained than those in the upper canopy. 相似文献
6.
Four-year-oldPinus sylvestriformis were exposed for four growing seasons in open top chambers to ambient CO2 concentration (approx. 350 μmol·mol−1) and high CO2 concentrations (500 and 700 μmol·mol−1) at Research Station of Changbai Mountain Forest Ecosystems, Chinese Academy of Sciences at Antu Town, Jilin Province, China
(42°N, 128°E). Stomatal response to elevated CO2 concentrations was examined by stomatal conductance (g
s), ratio of intercellular to ambient CO2 concentration (c
i/c
a) and stomatal number. Reciprocal transfer experiments of stomatal conductance showed that stomatal conductance in high-[CO2]-grown plants increased in comparison with ambient-[CO2]-grown plants when measured at their respective growth CO2 concentration and at the same measurement CO2 concentration (except a reduction in 700 μmol·mol−1 CO2. grown plants compared with plants on unchambered field when measured at growth CO2 concentration and 350 μmol·mol−1CO2). High-[CO2]-grown plants exhibited lowerc
i/c
a ratios than ambient-[CO2]-grown plants when measured at their respective growth CO2 concentration. However,c
i/c
a ratios increased for plants grown in high CO2 concentrations compared with control plants when measured at the same CO2 concentration. There was no significant difference in stomatal number per unit long needle between elevated and ambient CO2. However, elevated CO2 concentrations reduced the total stomatal number of whole needle by the decline of stomatal line and changed the allocation
pattern of stomata between upper and lower surface of needle.
Foundation Item: This research was supported by National Basic Research Program of China (2002CB412502), Project of Key program of the National
Natural Science Foundation of China (90411020) and National Natural Science Foundation of China (30400051).
Biography: ZHOU Yu-mei (1973-), female, Ph. Doctor, assistant research fellow, Institute of Applied Ecology, Chinese Academy of Sciences,
Shenyang 110016, P. R. China.
Responsible editor: Song Funan 相似文献
7.
Pinus sylvestriformis is an important species as an indicator of global climate changes in Changbai Mountain, China. The water use efficiency (WUE)
of this species (11-year old) was studied on response to elevated CO2 concentration at 500±100 μL·L−1 by directly injecting CO2 into the canopy under natural condition in 1998–1999. The results showed that the elevated CO2 concentration reduced averagely stomatal opening, stomatal conductance and stomatal density to 78%, 80% and 87% respectively,
as compared to normal ambient. The elevated CO2 reduced the transpiration and enhances the water use efficiency (WUE) of plant.
The project was supported by Chinese Academy of Sciences
Responsible editor: Chai Ruihai 相似文献
8.
M. L. Lopez C. T. Shirota G. Iwahana T. Koide T. C. Maximov M. Fukuda H. Saito 《Journal of Forest Research》2010,15(6):365-373
Sap flow measurements, from July to August 2004, were coupled with micrometeorological, soil moisture, and soil temperature
measurements to analyze forest water dynamics in irrigated and undisturbed (control) larch (Larix cajanderi) forest plots in eastern Siberia. Plots were irrigated with 120 mm (20 mm day−1) of water from 17 to 22 July. Sap flow measurements of ten trees at each plot were scaled up to daily stand canopy transpiration
(E
c
). Canopy transpiration at the irrigation and control plots was similar before irrigation. Forest evapotranspiration (E
a
) was obtained from Ohta et al. (Agric For Meteorol 148:1941–1953, 2008) while E
a
in the irrigation plot was estimated based on the E
c_irrig/E
c_cont ratio. Rainfall during July–August was 63.4 mm but, after including water from thawing soil layers, the actual water input
was 109.9 and 218.5 mm in the control and irrigation plots, respectively. Despite this large difference, a corresponding difference
in E
c
(and E
a
) was not observed [42.6 (61.5) mm and 46.4 (71.8) mm in control and irrigation plots, respectively]. Daily canopy conductance
(g
c
) increased as long as moisture was well supplied in the upper soil layers and evaporative demand was high. Soil moisture
and rainfall contribution to E
a
was 36.9 and 24.6 mm in the control plot and 34.5 and 37.3 mm in the irrigation plot, respectively. Water supply from soil
thawing layers in the control plot and high runoff (105.6 mm) rates in the irrigation plot accounted for the similarity in
water dynamics. Under increased precipitation, the forest used less soil water stored from previous growing seasons. 相似文献
9.
Philip J. Alcorn Jürgen Bauhus Dane S. Thomas Ryde N. James R. Geoff B. Smith Adrienne B. Nicotra 《Forest Ecology and Management》2008,255(11):3827-3838
The loss of foliage through pruning of live branches may reduce tree growth or it may be compensated by photosynthetic up-regulation of the remaining crown. Here, the changes in light-saturated photosynthesis following pruning to remove 50% of green crown length were examined in 4-year-old Eucalyptus pilularis Sm. and Eucalyptus cloeziana F. Muell. trees. The objectives of the study were to: (1) compare leaf-level physiological (light-saturated photosynthesis (Amax), stomatal conductance (g), transpiration (T), dark respiration (Rd), quantum yield (Φ), light compensation point (Γ), water-use efficiency (WUE), nitrogen-use efficiency (NUE)) traits in species with contrasting crown dynamics and structure, (2) examine the effect of crown position on these traits, and (3) examine the effect of pruning on Amax, g, T, WUE, NUE, leaf N and P concentrations and specific leaf area (SLA). Prior to pruning there were no differences in Rd, Γ and Φ between E. pilularis and E. cloeziana but differences in Amax, T, g, leaf N, leaf P, WUE, NUE and SLA. Whereas the rate of physiological processes (Amax, T, and g) and leaf N and P concentrations increased with crown height, Rd, Γ, Φ and SLA declined along this vertical gradient, except in the upper crown of E. cloeziana where Amax, T and g were not different to the lower crown. No up-regulation of photosynthesis or changes in leaf physiology occurred between 6 and 13 months after pruning in either species. The results provide an important basis for modelling pruning effects in process-based tree growth models. 相似文献
10.
Seasonal changes in carbon isotope discrimination (Δ) and gas exchange traits were assessed in four Populus×euramericana clones differing in growth potential. Measurements were made during the second year after establishment in the field under
two watering regimes, which were defined by the time-span between flood irrigations, hence resulting in different dry-down
cycles: high irrigation (conservative schedule currently applied in the Ebro Valley, Spain) and low irrigation (equivalent
to about a one-fourth reduction in water inputs). Net CO2 assimilation rate (A), stomatal conductance (gs), intrinsic water-use efficiency (A/gs) and other related photosynthetic traits (leaf nitrogen concentration, leaf greenness and leaf mass per area) were measured
prior to watering, and Δ was analysed in water-soluble leaf extracts (Δs) and bulk leaves (Δl). Stem growth was monitored over 3 years starting at the year of establishment (1998). Data were subjected to a repeated
measures ANOVA over time for a randomised block split-plot design across watering regimes. Significant differences between
watering regimes were detected using a long-term estimate of photosynthetic performance such as Δl, in agreement with changes in soil water status and evapotranspirative demand. However, the lack of significant genotype×watering
regime interactions for gas exchange traits and Δs suggested that water shortage imposed by low irrigation was not sufficient to reveal physiological adaptations to drought.
In this regard, the reduction in water inputs brought about by low irrigation did not reduce tree growth for any of the clones,
suggesting that the current irrigation scheme employed in the region is superfluous to the water consumption needs of poplars.
Genotypic variation was detected in gas exchange traits, Δs, Δl and stem growth under both watering treatments. Significant correlations with stem volume for Δs (r = −0.60, p<0.05) and A (r = + 0.61, p<0.05) suggested that growth was improved by higher water-use efficiency (the ratio of carbon fixed to water lost, as inferred
by Δs) due to variation in A rather than in gs. This observation corroborated the expectation derived from current theories that a lower Δ is related to higher stem volume,
as a result of changes in net CO2 assimilation rates. 相似文献
11.
Patricia Brito Jose R. Lorenzo Águeda Mª. González-Rodríguez Domingo Morales Gerhard Wieser Maria S. Jimenez 《European Journal of Forest Research》2014,133(3):491-500
Canopy transpiration (E c) of a 50-year-old Pinus canariensis Chr. Sm. Ex DC. stand at tree line in Tenerife, Canary Islands, was estimated continuously throughout a year from March 1, 2008, to February 28, 2009, by means of xylem sap flow measurements. E c varied markedly throughout the entire year generally following the seasonal trends in soil water availability and varied between 0.89 mm day?1 under the conditions of non-limiting soil water availability and close to zero under soil drought. This is because canopy conductance declined significantly with increasing evaporative demand and thus significantly reduced tree water loss, and this decrease was more pronounced during the soil drought. Total annual E c was 79.6 mm, which is significantly below the values estimated for other Mediterranean forest ecosystems and even 70 % lower than the value estimated for a P. canariensis forest at 1,650 m a.s.l. where the soil water content was higher than at the tree line site. Therefore, these results highlighted the importance of drought stress in tree line ecotone and should be taken more into account in semiarid tree lines. 相似文献
12.
Xuanran Li Qijing Liu Yongrui Chen Lile Hu Fengting Yang 《Frontiers of Forestry in China》2008,3(1):16-23
Regressive models of the aboveground biomass for three conifers in subtropical China—slash pine (Pinus elliottii), Masson pine (P. massoniana) and Chinese fir (Cunninghamia lanceolata)—were established. Regression analysis of leaf biomass and total biomass of each branch against branch diameter (d), branch length (L), d
3 and d
2
L was conducted with functions of linear, power and exponent. A power law equation with a single parameter (d) was proved to be better than the rest for Masson pine and Chinese fir, and a linear equation with parameter (d
3) is better for slash pine. The canopy biomass was derived by adopting the regression equations to all branches of each individual
tree. These kinds of equations were also used to fit the relationship between total tree biomass, branch biomass, foliage
biomass and tree diameter at breast height (D), tree height (H), D
3 and D
2
H, respectively. D
2
H was found to be the best parameter for estimating total biomass. However, for foliage biomass and branch biomass, both parameters
and equation forms showed some differences among species. Correlations were highly significant (P<0.001) for foliage biomass, branch biomass and total biomass, among which the equation of the total biomass was the highest.
With these equations, the aboveground biomass of Masson pine forest, slash pine forest and Chinese fir forest were estimated,
in addition to the allocation of aboveground biomass. The above-ground biomass of Masson pine forest, slash pine forest and
Chinese fir forest was 83.6, 72.1 and 59 t/hm2 respectively, and the stem biomass was more than the foliage biomass and the branch biomass. The underground biomass of these
three forests which estimated with others’ research were 10.44, 9.42 and 11.48 t/hm2, and the amount of carbon-fixed were 47.94, 45.14 and 37.52 t/hm2, respectively.
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Translated from Chinese Journal of Applied Ecology, 2006, 17(8): 1382–1388 [译自: 应用生态学报] 相似文献
13.
The sap flow of the sampled Populus euphratica stems at different radial depths and directions had been studied in Ejina Oasis, in the lower reaches of the Heihe River.
Based on sap flow measurements, the transpiration of the entire canopy was calculated. Results showed a linear correlation
between the sap flow and the sapwood area of the P. euphratica. Through the analysis of the diameter at breast height in the sample plot, it was found that the distribution of the diameters
and the corresponding sapwood area was exponentially correlated, with the coefficient of correlation being 0.976,7. The calculated
transpiration of the Populus euphratica canopy was 214.9 mm based on the specific conductivity method.
Translated from Scientia Silvae Sinicae, 2006, 42(7): 28–32 [译自: 林业科学] 相似文献
14.
In 2000, one-year-old seedlings of pyrenean oak (Quercus pyrenaica Willd.) and sessile oak (Quercus petraea [Matt.] Liebl) were planted in a thinned and an unthinned plot in a pinewood (Pinus sylvestris), and in a nearby clearing. In summer 2002 and 2003, water relations and gas exchange parameters were measured to address the impact of drought on the seedlings. Chlorophyll a fluorescence was also measured to explore leaf photochemistry and a possible non-stomatal limitation to photosynthesis (A). Reduction in stomatal conductance (g) in response to the decrease of predawn water potential (Ψpd) resulted the main cause affecting net carbon uptake. Water potential at midday (Ψmd) was similar in both species but Quercus petraea was more sensitive to soil water deployment occurred along summer, showing slightly lower Ψpd because worse recover of water potential during night. Rate of photosynthesis was higher in Q.␣pyrenaica probably in relation to its greater leaf mass per area (LMA) and nitrogen content per leaf area (Na). Mortality was highest in the clearing and lowest in the thinned pinewood. Throughout the summer, soil moisture was higher in the thinned area, possibly because of the reduction in tree transpiring surface and interception of rainfall. Accordingly, Ψpd of both species was higher in the thinned site. 相似文献
15.
Fude Liu Ming Zhang Wenjin Wang Shuning Chen Jianwei Zheng Wenjie Yang Fengqin Hu Shuqing An 《Frontiers of Forestry in China》2009,4(1):75-84
In order to make clear the relationships between photosynthesis and leaf N, leaf P and SLA of tropical trees, and test the
differences in the relationships among life-form groups (trees, shrub-like trees and shrubs), seedlings and saplings of 101
species from a tropical montane rain forest, located in the Diaoluo Mountain of Hainan Island, were selected. The net photosynthesis
based on area and mass (A
area and A
mass), leaf nitrogen content based on area and mass (N
area and N
mass), leaf phosphorus content based on area and mass (P
area and P
mass) and specific leaf area (SLA) were measured and/or calculated. The results showed that A
area and A
mass tended to follow the order of shrubs > trees > shrub-like trees. One-way ANOVA showed that the difference in A
area between shrubs and shrub-like trees was significant (p<0.05), and for A
mass there were significant differences between shrubs and shrub-like trees and between shrubs and tree species (p<0.05). The relationships between A
area and N
mass were highly significant in all three life-form groups and for all species (p<0.0001). The correlation between A
area and P
mass was highly significant in shrubs (p = 0.0038), shrub-like trees (p < 0.0002) and for all species (p<0.0001), but not significant in trees (p>0.05). The relationship between A
area and SLAwas highly significant in shrubs (p = 0.0006), trees (p<0.0001) and for all species (p<0.0001), however this relation was not significant in shrub-like trees (p>0.05). The relationships between A
mass and leaf N and SLA were highly significant in all three life-form groups and for all species (p<0.0001). For A
mass and leaf P, there were significant correlations in tree groups (p = 0.0377) and highly significant correlations in shrub groups (p = 0.0004), shrub-like tree groups (p = 0.0018) and for all species (p < 0.0001). Stepwise regression showed that predicted A
mass values were closer to the observed values than those for predicted A
area values. Thus, it can be concluded that the relationships obtained from seedling and sapling measurements are close to those
from mature individuals; correlations between photosynthesis and N
mass, P
mass and SLA traits are significant and the relationships are stronger and more stable for A
mass than for A
area.
__________
Translated from Acta Ecologica Sinica, 2007, 27(11): 4651–4661 [译自:生态学报] 相似文献
16.
Feng An Jing Cai Zaimin Jiang Yuanying Zhang Pingjuan Zhao Shuoxin Zhang 《Frontiers of Forestry in China》2007,2(2):198-203
The relationship between xylem embolism and eco-physiology indices (i.e. photosynthetic available radiation, temperature,
relative humidity, photosynthetic rate, transpiration rate, stomatal conductance and water use efficiency) in eight tree species
was investigated in situ. The species studied, Robinia pseudoacacia L., Acer truncatum Bge., Hippophae rhamnoides L., Ulmus pumila L., Pinus tabulaeformis Carr., Pinus bungeana Zucc.ex Endl., Ligustrum lucidum Ait., and Salix matsudana Koidz. f. pendula Schneid, grow well on the Xilin campus of Northwest A&F University. Results indicated that photosynthetic available radiation,
air temperature and relative humidity can affect xylem embolism by daily adjustment of stomatal conductance, transpiration
rate and water relations of a tree. Embolism was a common case in the daily growth of the plants, and there was some correlation
between xylem embolism and photosynthetic rate, transpiration rate, stomatal conductance, and water use efficiency. Embolism
may thus be an adaptive mechanism by some tree species to water stress.
__________
Translated from Journal of Northwest Forestry University, 2006, 21(1): 37–42 [译自: 西北林学院学报] 相似文献
17.
Drought periods are becoming more extreme worldwide and the ability of plants to contribute towards atmospheric flux is being compromised. Properly functioning stomata provide an exit for water that has been absorbed by the roots, funneled into various cell parts, and eventually released into the atmosphere via transpiration. By observing the effects that weather conditions such as climate change may have on stomatal density, distribution, and functioning, it may be possible to elucidate a portion of the mechanisms trees use to survive longer periods of water stress. This study analyzed stomatal density (SD), stomatal conductance (gs ), CO2 assimilation (A), instantaneous water-use efficiency (WUEi ), and transpiration (E) rates in six native tree species in the Midwestern USA and showed that trees within the same ecotype followed similar trends, but that trees within the same family did not when exposed to identical greenhouse conditions. Naturally drought tolerant tree species demonstrated lower g s and higher WUEi , while intolerant species had higher SD. This study showed negative or no correlation between SD and g s , A, E, and WUEi and positive correlations between E and A and gs and E. 相似文献
18.
Virginia Hernndez-Santana Jordi Martínez-Vilalta Jos Martínez-Fernndez Mathew Williams 《Forest Ecology and Management》2009,258(7):1719-1730
Under climate change, severe and recurrent droughts can reduce forest production and cause widespread tree dieback. The response of different vegetation types to climate change can vary greatly and, therefore, must be individually assessed. This study was carried out in a Mediterranean oak forest (Quercus pyrenaica) subject to seasonal summer drought. To examine the response of the forest to the climate conditions predicted under climate change, a Soil–Vegetation–Atmosphere Transfer model [SPA, Williams, M., Rastetter, E.B., Fernandes, D.N., Goulden, M.L., Wofsy, S.C., Shaver, G.R., Melillo, J.M., Munger, J.W., Fan, S.M., Nadelhoffer, K.J. 1996. Modelling the soil-plant-atmosphere continuum in a Quercus–Acer stand at Harvard Forest: the regulation of stomatal conductance by light, nitrogen and soil/plant hydraulic properties. Plant, Cell, Environment 19, 911–927] was used. The model was parameterized using mostly local measurements (independent of the verification data) and tested against in situ sap flow measurements obtained during year 2007. The predictions of the model were broadly consistent with the observed dynamics of sap flow (the model explained 71% of the variance in daily transpiration and 75% of half-hourly sap flow), leaf water potentials and soil water content. Once the model had been validated, simulations were carried out under warmer and dryer conditions. Predicted warmer conditions (4 °C) caused a moderate increase in total simulated transpiration. Less frequent precipitation (40% longer dry periods between rainfall events) had very little effect on transpiration. In contrast, transpiration was reduced by 17% when the soil water reserves at the beginning of the summer were lower than in 2007, corresponding to those measured in a very dry year (2005). The reduction was exacerbated when changes in temperature and rainfall were also considered (up to 28% decline in transpiration). The higher atmospheric CO2 concentrations (712 ppm) simulated together with climate change, did not prevent the decline in tree water use or soil water storage at the end of the summer. All scenarios caused the soil water storage to reach extremely low values at the end of the dry season (a minimum of 25 mm). It is concluded that climate change is likely to have a negative impact on tree water use and soil water resources in the study area, increasing the water deficit by as much as 30%. 相似文献
19.
Measurements made by remote sensing can characterize the leaf area density and nitrogen/chlorophyll content of forest canopies, as well as maximum photosynthetic capacity and above-ground structure and biomass. Combining these with climate data estimated from relationships based on temperature measurements and using an appropriate process-based model, it is possible to calculate, with useful accuracy, carbon sequestration and wood production by different forest types covering large land areas. To broaden its application and reduce the need for detailed information on stand characteristics, a satellite-driven version of the model 3-PG, was developed. The 3-PGS model incorporates the major first-order physiological processes that determine forest growth, and the biophysical factors that affect and govern those processes. It incorporates remotely sensed estimates of seasonal variation in canopy light interception (fPAR) and includes physiological variables (stomatal conductance and canopy quantum efficiency) that can be estimated by remote-sensing measurements of factors that influence those variables. 3-PGS therefore provides a useful framework within which to evaluate how data from the array of airborne and satellite-borne sensors now available might be used to initialize, drive, and test process-based growth models across regions with diverse soils and climates. We address the question: to what extent might additional remote-sensing techniques improve 3-PGS predictions?Sensitivity analyses indicate that model accuracy would be most improved through better estimates of seasonal changes in canopy photosynthetic capacity (α) and canopy conductance (Gc). Canopy photosynthetic capacity depends on the amount of light absorbed by the canopy, estimated as a fraction of photosynthetically active radiation (fPAR), and on foliage nitrogen or chlorophyll content, which can be estimated using multi-spectral imagery. Gc depends on canopy leaf area index (L) and stomatal conductance of the foliage (gs), which is affected by the vapor pressure deficit of the air and soil water content. The onset and effects of drought can be determined from changes in canopy reflectance and fPAR identified from sequential measurements; the same measurements, coupled with calculations of evapotranspiration using climatic data and standard formulae, provide estimates of total available water in forest root zones. Periodic surveys with Light Detection and Ranging (LiDAR) and interferometric RADAR may serve to validate model predictions of above-ground growth (NPPA), while progressive reduction in light-use efficiency (NPPA/APAR) may identify forests with declining vigor that are likely to succumb to attack from insects and pathogens. 相似文献
20.
Xiaowei Ma Fengwang Ma Cuiying Li Yinfa Mi Tuanhui Bai Huairui Shu 《Agroforestry Systems》2010,80(2):283-294
Variations in biomass productivity, plant water-use efficiency (WUEp), and carbon isotope composition (δ13C) were investigated among 10 Malus rootstocks. In the semi-controlled environmental of a greenhouse, plants were watered to either 75% or 50% of field capacity.
For each treatment, significant differences were found in dry matter accumulation and allocation, δ13C, and WUEp. Relative growth rate (RGR) was correlated with WUEp but not with allocation pattern. Variations in whole-plant transpiration were a result of fluctuations in the rate of transpiration
per unit leaf area rather than from differences in leaf area or root weight per plant. Values for transpiration per unit leaf
area or root weight were lower when the proportion of either leaf area or root weight per unit plant weight was larger. Rootstock
differences in δ13C were related to changes in stomatal conductance rather than in net photosynthesis. Finally, δ13C was significantly correlated with WUEp and rootstock rankings based on both of those parameters were maintained regardless of watering treatment. 相似文献