Rhizosphere geometry and heterogeneity arising from root-mediated physical and chemical processes.
about
Specificity of plant-microbe interactions in the tree mycorrhizosphere biome and consequences for soil C cyclingFungal association and utilization of phosphate by plants: success, limitations, and future prospectsCan transgenic maize affect soil microbial communities?Quantitative imaging of rhizosphere pH and CO2 dynamics with planar optodesRates of root and organism growth, soil conditions, and temporal and spatial development of the rhizosphereLinking plant nutritional status to plant-microbe interactions.Changes in pH, dissolved organic matter and Cd species in the rhizosphere soils of Cd phytostabilizer Athyrium wardii (Hook.) Makino involved in Cd tolerance and accumulation.Root foraging elicits niche complementarity-dependent yield advantage in the ancient 'three sisters' (maize/bean/squash) polycultureGenome-wide survey of two-component signal transduction systems in the plant growth-promoting bacterium AzospirillumMapping the Centimeter-Scale Spatial Variability of PAHs and Microbial Populations in the Rhizosphere of Two Plants.Field evaluation of arbuscular mycorrhizal fungal colonization in Bacillus thuringiensis toxin-expressing (Bt) and non-Bt maize.Lateral root emergence: a difficult birth.Phosphorus dynamics: from soil to plant.Glomalin: an arbuscular mycorrhizal fungal soil protein.Synthesis and modeling perspectives of rhizosphere priming.Taxonomic and functional shifts in the beech rhizosphere microbiome across a natural soil toposequenceThe nitrogen-potassium intersection: Membranes, metabolism, and mechanism.The effects of plant nutritional strategy on soil microbial denitrification activity through rhizosphere primary metabolites.Biochemical characterization of a nitrogen-type phosphotransferase system reveals that enzyme EI(Ntr) integrates carbon and nitrogen signaling in Sinorhizobium meliloti.Fungal Communities in Rhizosphere Soil under Conservation Tillage Shift in Response to Plant Growth.A mechanistic model for understanding root-induced chemical changes controlling phosphorus availability.High-resolution synchrotron imaging shows that root hairs influence rhizosphere soil structure formation.A multi-imaging approach to study the root-soil interface.Disentangling who is who during rhizosphere acidification in root interactions: combining fluorescence with optode techniques.Fine root dynamics in lodgepole pine and white spruce stands along productivity gradients in reclaimed oil sands sitesEffects of root exudates of woody species on the soil anti-erodibility in the rhizosphere in a karst region, China.Ammonium triggers lateral root branching in Arabidopsis in an AMMONIUM TRANSPORTER1;3-dependent manner.High resolution synchrotron imaging of wheat root hairs growing in soil and image based modelling of phosphate uptake.Reduction in Root Secondary Growth as a Strategy for Phosphorus Acquisition.Cadmium-induced rhizospheric pH dynamics modulated nutrient acquisition and physiological attributes of maize (Zea mays L.).Roles of rhizosphere and root-derived organic acids in Cd accumulation by two hot pepper cultivars.Draft genome sequence of Bacillus velezensis 2A-2B strain: a rhizospheric inhabitant of Sporobolus airoides (Torr.) Torr., with antifungal activity against root rot causing phytopathogens.Is there genetic variation in mycorrhization of Medicago truncatula?An Explicit Structural Model of Root Hair and Soil Interactions Parameterised by Synchrotron X-ray Computed Tomography.Isolation and characterization of Staphylococcus sp. strain NBRIEAG-8 from arsenic contaminated site of West Bengal.Plant Phylogeny and Life History Shape Rhizosphere Bacterial Microbiome of Summer Annuals in an Agricultural Field.A boundary-layer solution for flow at the soil-root interface.A novel non-invasive optical method for quantitative visualization of pH dynamics in the rhizosphere of plants.Enhanced root exudation induces microbial feedbacks to N cycling in a pine forest under long-term CO2 fumigation.Development and Validation of a SPME-GC-MS Method for In situ Passive Sampling of Root Volatiles from Glasshouse-Grown Broccoli Plants Undergoing Below-Ground Herbivory by Larvae of Cabbage Root Fly, Delia radicum L.
P2860
Q21131092-4113641F-6A5B-4217-8313-E47B75F489C8Q26777224-760DCF69-1648-4FAC-915A-BCDA724D83A8Q28469050-116A45FD-10FA-4015-B3C2-681BCF0171CFQ30541082-1A343789-4403-4543-A6C8-80FE4D996105Q33342235-E163C592-A3EA-40FD-A803-46E0E2B13EC5Q34849334-7721806B-EEE5-4AF5-A148-E5BD9BC588AFQ35066834-F8177B64-0821-49D2-9B54-CFC41B74E0F9Q35558855-99FE4D62-901D-4911-903E-8991F31CDDD0Q35816553-B99F78BE-DAF1-42E5-88D1-487B3A3F6472Q35850098-FFBDD6C3-D1D6-4679-8761-934AB5BFC4AAQ36970663-82061F90-33A8-46A8-AB14-F4A4335BCB11Q37563774-34DFFC01-DBA0-4DA6-93A2-9ACE0992A2E9Q37875582-7B317AAD-B749-4275-8D18-BE98B8C86A54Q38044656-A12345A0-8591-47BE-8A69-62BFA0FC4789Q38129434-43B3B2C7-2B71-460B-88F8-FE55CFDDB3A0Q38603099-F6065A6D-99E3-4D56-A0FE-62CE5830B2ADQ38622505-CA8389E8-531E-4DDB-AB02-459F4E3B56EEQ38882995-3A16892A-C9F1-4024-8507-F651BC870BAAQ39260685-7D728E78-C35D-4F1E-AF6E-018824E739D5Q40975517-BD010BA7-5DB2-4D34-BA83-CDC60AB41F7BQ41126821-7AEC86C4-2B57-46CF-A612-723157DA6A8FQ41877755-E04CFA80-6169-43D7-A88D-FB69D6C04787Q42117249-46ED77F3-96CE-48D9-9FCE-F63E0197B26CQ42119993-69861396-814A-4B5F-90DC-3FDABFF4F802Q42143438-6BFAAD5E-E7D0-413B-BF89-D2CFF04F1325Q42318644-42F50472-B8B1-459E-B7E5-84064DC0DBB0Q42789689-B97895C3-6587-45DC-9829-335B43E8FFA0Q45330429-851034A5-1E77-406D-969D-0140F90D8B8BQ46265470-AFED98FA-A66C-445E-BF83-C88A779DCCFAQ46786916-5A9CF63D-11DD-497B-9810-D287C1FC0F6EQ46812838-67C9ECC3-BFCD-47A4-BFBB-F72041358780Q47128446-9A6DC983-6BBC-4644-B8C6-B36C67D30874Q47134461-766F457A-9F6E-4766-9D2B-BE7179DC8945Q47145563-025F1502-2AAA-4E61-9C00-41B5615560A6Q48051346-B252593F-B79E-4C81-B994-E672B3ED81E2Q48542540-B82D653C-0996-4B33-8FDF-5D4643C94243Q51068765-FE6D5F8D-2A36-4701-A0AE-C33666FC6734Q51082309-565A7F05-FF49-4335-AC31-3E87ED3E227AQ51156413-96B37604-166E-455F-8EB0-A9E87A4C4EE4Q51256552-D8832D92-E8DD-4415-863F-0C76EE4395F1
P2860
Rhizosphere geometry and heterogeneity arising from root-mediated physical and chemical processes.
description
2005 nî lūn-bûn
@nan
2005 թուականի Նոյեմբերին հրատարակուած գիտական յօդուած
@hyw
2005 թվականի նոյեմբերին հրատարակված գիտական հոդված
@hy
2005年の論文
@ja
2005年論文
@yue
2005年論文
@zh-hant
2005年論文
@zh-hk
2005年論文
@zh-mo
2005年論文
@zh-tw
2005年论文
@wuu
name
Rhizosphere geometry and heter ...... ysical and chemical processes.
@ast
Rhizosphere geometry and heter ...... ysical and chemical processes.
@en
Rhizosphere geometry and heter ...... ysical and chemical processes.
@nl
type
label
Rhizosphere geometry and heter ...... ysical and chemical processes.
@ast
Rhizosphere geometry and heter ...... ysical and chemical processes.
@en
Rhizosphere geometry and heter ...... ysical and chemical processes.
@nl
prefLabel
Rhizosphere geometry and heter ...... ysical and chemical processes.
@ast
Rhizosphere geometry and heter ...... ysical and chemical processes.
@en
Rhizosphere geometry and heter ...... ysical and chemical processes.
@nl
P2093
P1433
P1476
Rhizosphere geometry and heter ...... hysical and chemical processes
@en
P2093
George R Gobran
Philippe Hinsinger
Walter W Wenzel
P304
P356
10.1111/J.1469-8137.2005.01512.X
P407
P577
2005-11-01T00:00:00Z