Rooting depth, water availability, and vegetation cover along an aridity gradient in Patagonia.
about
Reptiles of Chubut province, Argentina: richness, diversity, conservation status and geographic distribution mapsEvaluating ecohydrological theories of woody root distribution in the Kalahari.Resource pulses, species interactions, and diversity maintenance in arid and semi-arid environments.Higher effect of plant species diversity on productivity in natural than artificial ecosystems.Evidence of a universal scaling relationship for leaf CO2 drawdown along an aridity gradient.Global patterns of groundwater table depth.Endemic shrubs in temperate arid and semiarid regions of northern China and their potentials for rangeland restoration.A global budget for fine root biomass, surface area, and nutrient contentsPatterns of ant (Hymenoptera: Formicidae) richness and relative abundance along an aridity gradient in Western Venezuela.Prevalence and magnitude of groundwater use by vegetation: a global stable isotope meta-analysis.Water use efficiency of twenty-five co-existing Patagonian species growing under different soil water availability.Hydraulic responses to extreme drought conditions in three co-dominant tree species in shallow soil over bedrock.Shade affects responses to drought and flooding - acclimation to multiple stresses in bittersweet (Solanum dulcamara L.).Do shallow soil, low water availability, or their combination increase the competition between grasses with different root systems in karst soil?Variation in bulk-leaf 13 C discrimination, leaf traits and water-use efficiency-trait relationships along a continental-scale climate gradient in Australia.Dark septate endophytes isolated from a xerophyte plant promote the growth of Ammopiptanthus mongolicus under drought condition.Pinus ponderosa alters nitrogen dynamics and diminishes the climate footprint in natural ecosystems of PatagoniaCarbon (δ13C) and nitrogen (δ15N) stable isotope composition in plant and soil in Southern Patagonia's native forestsLinks between soil texture and root architecture of Eucalyptus species may limit distribution ranges under future climatesThe responses of grassland plants to experimentally simulated climate change depend on land use and regionAssembly of plant communities in coastal wetlands—the role of saltcedarTamarix chinensisduring early successionINTRA- AND INTERSPECIFIC VARIATION FOR SUMMER PRECIPITATION USE IN PINYON–JUNIPER WOODLANDSdelta13C variation of C3 and C4 plants across an Asian monsoon rainfall gradient in arid northwestern ChinaChloride concentration distribution under oak hedgerow: an indicator of the water-uptake zone of tree roots?A model-based evaluation of woody plant encroachment effects on coupled carbon and water cyclesA shady business: pine afforestation alters the primary controls on litter decomposition along a precipitation gradient in Patagonia, ArgentinaTopographic, edaphic, and vegetative controls on plant-available waterRelating water use to morphology and environment of Nothofagus from the world’s most southern forestsHair of grazing cattle provides an integrated measure of the effects of site conditions and interannual weather variability on delta13C of temperate humid grasslandConsequences of Surface and Subsurface Water Use on Wetland Graminoids of Different Geographic OriginGreen Tongues into the Arid Zone: River Floodplains Extend the Distribution of Terrestrial Bird SpeciesPlant morpho-physiological variation under distinct environmental extremes in restinga vegetation
P2860
Q22676251-372DE7C2-A01E-41CF-B44E-8DEBEC9E104FQ30427528-F42D4B64-6590-474B-8EAE-5A5215ED892FQ30919765-245EFD3C-B6AE-4BA6-9358-D92674A7E23CQ33329759-42449AD5-FB90-4B15-A273-D469B86D193DQ33779448-A49F6474-7787-4632-9FFB-16F9018AD120Q34594782-51F0C7AB-8D84-4BE2-9B1F-2D738EC6A39CQ35894308-EEAC6A0D-89DB-4A2C-B200-D72B5CB0BE97Q36655820-6B40704E-360A-4D89-A0A4-BEAE449A8C4BQ36695261-D0BFD271-19B5-49C0-ADEF-D4280CD8E0ECQ37692391-733FC7BE-2C14-4573-AB6B-63E881AD8EB0Q39026987-2506D6E8-D22A-439F-95B9-1CC9BBFA28F3Q39150486-4B16C89E-52E2-4A47-A572-9F7D1E64953BQ39562985-B249BD91-89AA-4F44-A20A-E963CE42C032Q39629007-3F315E6C-B89E-47DF-AAAA-BBB1D23A18EEQ46300530-304570BA-D9A3-4A84-AA8C-FC9A43B95332Q55070499-EB7FF5F4-79AF-4098-92A9-524879A8CE29Q56452195-A8C9EDD1-5CAC-4260-B2DD-761465478934Q56839261-BFFF69A4-FD3D-48F8-A412-9E73CCD98D8CQ56950664-D7028E12-139B-4CEE-8A82-6E18FD3789E3Q57019871-5964EF42-0534-4A71-B4EA-DCA375573307Q57032557-2255668C-108B-4C3F-B150-170943B0DA47Q57066435-902D4509-5096-4035-AC0A-F39E45D2426BQ57146372-7259EF87-F692-4B62-9AE9-A3B7A4A4DC28Q57774524-1A2B3A8E-1EA3-4BAE-9453-4C222B03F7BFQ57825129-699B2130-E542-426C-874B-860A572A03B3Q57901441-A8E8DCAD-1710-4F9F-AC4D-1F852D5FDB0CQ58262710-3D102CFE-6D24-4CEE-B74C-2CD8A5D4FB09Q58382594-F4347279-4775-4F2C-B93C-3FFE75D10A35Q58408940-799B24AE-E5DB-4D76-A68A-0433C580393DQ58798633-158B5F19-8543-4DFF-97B4-A51635485BA6Q59154654-B6389A22-CCBD-448D-930D-71660B38FB31Q92427027-A089D8BC-9EC3-491D-B5DB-4C4F38D0C388
P2860
Rooting depth, water availability, and vegetation cover along an aridity gradient in Patagonia.
description
1996 nî lūn-bûn
@nan
1996年の論文
@ja
1996年学术文章
@wuu
1996年学术文章
@zh-cn
1996年学术文章
@zh-hans
1996年学术文章
@zh-my
1996年学术文章
@zh-sg
1996年學術文章
@yue
1996年學術文章
@zh
1996年學術文章
@zh-hant
name
Rooting depth, water availabil ...... aridity gradient in Patagonia.
@ast
Rooting depth, water availabil ...... aridity gradient in Patagonia.
@en
type
label
Rooting depth, water availabil ...... aridity gradient in Patagonia.
@ast
Rooting depth, water availabil ...... aridity gradient in Patagonia.
@en
prefLabel
Rooting depth, water availabil ...... aridity gradient in Patagonia.
@ast
Rooting depth, water availabil ...... aridity gradient in Patagonia.
@en
P2093
P356
P1433
P1476
Rooting depth, water availabil ...... aridity gradient in Patagonia.
@en
P2093
E -D Schulze
J Canadell
J R Ehleringer
M Oesterheld
R B Jackson
P2888
P304
P356
10.1007/BF00333727
P407
P577
1996-11-01T00:00:00Z