Balancing the costs of carbon gain and water transport: testing a new theoretical framework for plant functional ecology.
about
Recent pause in the growth rate of atmospheric CO2 due to enhanced terrestrial carbon uptake.How eco-evolutionary principles can guide tree breeding and tree biotechnology for enhanced productivity.Long-term water stress leads to acclimation of drought sensitivity of photosynthetic capacity in xeric but not riparian Eucalyptus speciesA test of the 'one-point method' for estimating maximum carboxylation capacity from field-measured, light-saturated photosynthesis.Morphological and moisture availability controls of the leaf area-to-sapwood area ratio: analysis of measurements on Australian trees.Short-term water stress impacts on stomatal, mesophyll and biochemical limitations to photosynthesis differ consistently among tree species from contrasting climates.Changes in biomass allocation buffer low CO2 effects on tree growth during the last glaciation.Testing the environmental filtering concept in global drylandsThe impact of alternative trait-scaling hypotheses for the maximum photosynthetic carboxylation rate (Vcmax ) on global gross primary production.A novel approach for modelling vegetation distributions and analysing vegetation sensitivity through trait-climate relationships in China.Legumes are different: Leaf nitrogen, photosynthesis, and water use efficiency.Optimal plant water economy.Stomatal CO2 responsiveness and photosynthetic capacity of tropical woody species in relation to taxonomy and functional traits.Drought × CO2 interactions in trees: a test of the low-intercellular CO2 concentration (Ci ) mechanism.Integrating plant hydraulics and gas exchange along the drought-response trait spectrum.Predicting stomatal responses to the environment from the optimization of photosynthetic gain and hydraulic cost.Optimal balance of water use efficiency and leaf construction cost with a link to the drought threshold of the desert steppe ecotone in northern China.Atmospheric evidence for a global secular increase in carbon isotopic discrimination of land photosynthesis.Towards a universal model for carbon dioxide uptake by plants.Trait covariance: the functional warp of plant diversity?New insights into the covariation of stomatal, mesophyll and hydraulic conductances from optimization models incorporating nonstomatal limitations to photosynthesis.Coupled response of stomatal and mesophyll conductance to light enhances photosynthesis of shade leaves under sunflecks.Modeling Stomatal Conductance.Quantifying soil moisture impacts on light use efficiency across biomes.Photosynthetic responses to altitude: an explanation based on optimality principles.Co-regulation of photosynthetic capacity by nitrogen, phosphorus and magnesium in a subtropical Karst forest in China.Improving representation of photosynthesis in Earth System ModelsA probabilistic eco-hydrological model to predict the effects of climate change on natural vegetation at a regional scaleGlobal effects of soil and climate on leaf photosynthetic traits and ratesDrought tolerance as predicted by leaf water potential at turgor loss point varies strongly across species within an Amazonian forestDoes vapor pressure deficit drive the seasonality of δ13 C of the net land-atmosphere CO2 exchange across the United States?Reduced streamflow in water-stressed climates consistent with CO2 effects on vegetationConserved stomatal behaviour under elevated CO2and varying water availability in a mature woodlandOptimal stomatal behaviour around the worldFrom plant functional types to plant functional traitsLeaf nitrogen from first principles: field evidence for adaptive variation with climateLeaf trait adaptations of xylem-tapping mistletoes and their hosts in sites of contrasting aridityA global analysis of water and nitrogen relationships between mistletoes and their hosts: broad-scale tests of old and enduring hypotheses20th century changes in carbon isotopes and water-use efficiency: tree-ring-based evaluation of the CLM4.5 and LPX-Bern modelsConvergence in resource use efficiency across trees with differing hydraulic strategies in response to ecosystem precipitation manipulation
P2860
Q28595930-480AD605-ADF3-4B87-93E5-F7D918DC055FQ30881998-388A54FE-00CF-4E78-A182-47C3FA63FB1EQ31009901-59CCFAA4-9740-48C5-9D0E-3EF292444607Q31034593-D80348B2-7066-48D5-8CE0-71B250022AAAQ35226368-5A4831B8-080F-4D74-8C06-5402D494E862Q35240261-8BCDC10E-AE8A-49F3-9129-2746E8CAEE6DQ36289242-E8FF1F0F-B358-4B14-8001-2255FEEFBC4EQ36412947-CBB2FE1A-1FDB-4F7B-8401-2863FF7F7B0AQ36413229-40CE192D-18B3-46EE-A88C-6923D3ED8B9FQ36773936-43802680-E204-47BC-A4B9-50D9A5830EFCQ36821317-5689200E-4B16-493C-BA49-F7E3EBEFA4C4Q38819805-8A70E7CD-7A61-44A4-A201-A08D447AECC5Q38929184-1A8F6BA7-8D63-4DB0-A179-96919179B955Q39127537-FB17809D-06EA-4557-96FD-935E33DBE31FQ39213185-CB67C80C-943D-4FF1-9EB2-A6E1711DD84DQ39482873-AA9C2E12-7A89-4BE1-B81C-F847E9BEC865Q39575421-1F45ED75-A1EC-41FA-AC00-5BAD44189C27Q44588907-ACB4FC0E-E2EE-4D7A-B6C5-5FC182F56D7DQ46259244-631F53BA-7996-4A61-A82C-6130B3B562B1Q46267213-DA4B746A-C9E2-48BC-8ADA-95F033AADF29Q47819666-6C3EACA7-7037-4FFA-B3E2-C324AD707895Q48308790-90ADA0AE-4606-4F91-BB63-E650071A8C6FQ48375706-5C413CE3-9845-4640-92CB-E39BBA55ED32Q51731761-9C998552-195D-487E-82F0-3D2DEA23CBDBQ53131642-83137344-776D-41EE-B0D7-EEAC01864ED4Q55383667-67EE498C-79D6-4480-83BD-F6B29DC59FBAQ56959073-DEB32AB1-69B5-4F15-948E-C4A92C25DB77Q56963993-676379D1-AB0D-41C6-BA68-14683EC77A80Q56964027-B1B9C875-04E4-443D-A15B-189FAC36128FQ56973799-019028AC-523A-4057-A5D9-A77C2F641F35Q57020431-FA134097-3910-487C-802F-C7412846F8C1Q57159697-C0BD7473-0735-4CE0-AFEF-01BD23379A72Q57191633-F012C057-F5EC-490D-B544-26116612E8B4Q57191654-FFC12A06-DF7E-40E6-96BF-3837635DE4E1Q57194801-02807DCE-A840-42C6-ACA5-A72617D744E5Q57234453-5EFF1C3B-332C-4E3D-95EF-C4B7272BDF65Q57234456-323FE7C1-2B31-4B1E-AC74-A000BDD33C78Q57234473-F7071BE2-3292-4EB7-9C56-E8CD8493C7A2Q57890448-6DC7F8AF-5466-4CF6-98A0-FA3E936F8265Q58053448-9324E9EC-77CE-4376-84F0-D7B26DEEA0D3
P2860
Balancing the costs of carbon gain and water transport: testing a new theoretical framework for plant functional ecology.
description
2013 nî lūn-bûn
@nan
2013 թուականի Նոյեմբերին հրատարակուած գիտական յօդուած
@hyw
2013 թվականի նոյեմբերին հրատարակված գիտական հոդված
@hy
2013年の論文
@ja
2013年論文
@yue
2013年論文
@zh-hant
2013年論文
@zh-hk
2013年論文
@zh-mo
2013年論文
@zh-tw
2013年论文
@wuu
name
Balancing the costs of carbon ...... for plant functional ecology.
@ast
Balancing the costs of carbon ...... for plant functional ecology.
@en
type
label
Balancing the costs of carbon ...... for plant functional ecology.
@ast
Balancing the costs of carbon ...... for plant functional ecology.
@en
prefLabel
Balancing the costs of carbon ...... for plant functional ecology.
@ast
Balancing the costs of carbon ...... for plant functional ecology.
@en
P2093
P2860
P356
P1433
P1476
Balancing the costs of carbon ...... for plant functional ecology.
@en
P2093
I Colin Prentice
Sean M Gleason
Vincent Maire
P2860
P356
10.1111/ELE.12211
P407
P577
2013-11-11T00:00:00Z