Historical land use change has lowered terrestrial silica mobilization
about
The Role of Silicon in Higher Plants under Salinity and Drought StressSilicon: Potential to Promote Direct and Indirect Effects on Plant Defense Against Arthropod Pests in AgricultureThe terrestrial silica pumpGrazers: biocatalysts of terrestrial silica cyclingEarly anthropogenic transformation of the Danube-Black Sea systemUptake of Silicon by Sugarcane from Applied Sources May Not Reflect Plant-Available Soil Silicon and Total Silicon Content of Sources.Landscape cultivation alters δ³⁰Si signature in terrestrial ecosystems.Thigmomorphogenetic responses of an aquatic macrophyte to hydrodynamic stressChanges in Structure and Functioning of Protist (Testate Amoebae) Communities Due to Conversion of Lowland Rainforest into Rubber and Oil Palm Plantations.Silica uptake and release in live and decaying biomass in a northern hardwood forest.Enhanced silicon availability leads to increased methane production, nutrient and toxicant mobility in peatlands.Provision of nitrogen as ammonium rather than nitrate increases silicon uptake in sugarcane.Low ratios of silica to dissolved nitrogen supplied to rivers arise from agriculture not reservoirs.Hydrodynamically mediated macrophyte silica dynamics.Silicon Influences Soil Availability and Accumulation of Mineral Nutrients in Various Plant Species.Lack of steady-state in the global biogeochemical Si cycle: emerging evidence from lake Si sequestrationPedogenic and biogenic alkaline-extracted silicon distributions along a temperate land-use gradientChanges in amorphous silica sequestration with eutrophication of riverine impoundmentsEmerging understanding of the ecosystem silica filterGlobal importance, patterns, and controls of dissolved silica retention in lakes and reservoirsLand use change affects biogenic silica pool distribution in a subtropical soil toposequence
P2860
Q26739739-98267B58-F9CC-43D7-BFD4-B6290F78FB5EQ26744543-FFEDB3EA-84E3-4555-BE7A-CCC1BC226028Q28484679-DB81062B-C013-4483-B148-0A65616C754FQ28661950-94021D8B-E183-4B11-8EBF-B49088A97BB5Q28728167-B5F88746-BB9A-4BF2-9A2A-4884C4845E51Q33679377-EEABB3C1-CCCF-440B-A906-9F38F242D169Q34925088-1B2CC2F1-82CA-4957-9FF9-1DE50D79003AQ35564399-D7AFAEF2-F8B1-47FB-9958-60AD73A49339Q36087234-40718C8E-20F7-4E8C-AA49-6730E173D893Q39168631-21105516-424D-420E-B17A-3DB23E805593Q41459148-62DED9B0-AAF6-435D-9DC8-AC0629A872E6Q42374780-ACCFCF99-B21F-46FA-BE11-5A75B64C5F19Q46478391-803C304F-223C-4EC5-B74E-D38E4D8BBB8DQ51565342-EA7F1725-E0D2-48EE-AF64-81EC2CE07946Q55627837-B57A28DC-25DE-426A-AE29-141B9B1C613FQ57059465-AC3C9F8A-502B-4AD6-BB8E-9F603743AB77Q57059468-B9BB92A9-A0DB-401C-A039-57CB53622C4AQ57059499-05E3BA4D-1AF0-4417-B95B-1C2E4F706A9DQ57059506-7EFCE976-D5B4-400E-8DE6-605CCC20FFA4Q57059511-C34531C5-B9BB-4C78-A673-AB3EF6F7A1A6Q57876469-70508FAD-BAE6-4405-81FD-A57C232132CC
P2860
Historical land use change has lowered terrestrial silica mobilization
description
article publié dans Nature Communications
@fr
im November 2010 veröffentlichter wissenschaftlicher Artikel
@de
scientific article published in Nature Communications
@en
wetenschappelijk artikel
@nl
наукова стаття, опублікована в листопаді 2010
@uk
name
Historical land use change has lowered terrestrial silica mobilization
@en
Historical land use change has lowered terrestrial silica mobilization
@nl
type
label
Historical land use change has lowered terrestrial silica mobilization
@en
Historical land use change has lowered terrestrial silica mobilization
@nl
prefLabel
Historical land use change has lowered terrestrial silica mobilization
@en
Historical land use change has lowered terrestrial silica mobilization
@nl
P2093
P50
P356
P1476
Historical land use change has lowered terrestrial silica mobilization
@en
P2093
Adriaan Smis
Christiane Lancelot
Elisabeth Frot
Floor Vandevenne
Josette Garnier
Patrick Meire
Peter Goos
Stefan Van Damme
P2888
P356
10.1038/NCOMMS1128
P407
P577
2010-11-01T00:00:00Z
P6179
1040683588