Microbial hotspots and hot moments in soil: Concept & review
暂无分享,去创建一个
[1] P. Baldrian. Microbial enzyme-catalyzed processes in soils and their analysis. A review , 2018 .
[2] R. Vargas,et al. Hot spots, hot moments, and spatio-temporal controls on soil CO2 efflux in a water-limited ecosystem , 2014 .
[3] I. Janssens,et al. Strong stoichiometric resilience after litter manipulation experiments; a case study in a Chinese grassland , 2014 .
[4] S. Blagodatsky,et al. Microbial interactions affect sources of priming induced by cellulose , 2014 .
[5] S. Blagodatsky,et al. Microbial Growth and Carbon Use Efficiency in the Rhizosphere and Root-Free Soil , 2014, PloS one.
[6] Andreas Richter,et al. Microbial community dynamics alleviate stoichiometric constraints during litter decay , 2014, Ecology letters.
[7] J. Rousk,et al. The effects of glucose loading rates on bacterial and fungal growth in soil , 2014 .
[8] Y. Kuzyakov,et al. Spatial and temporal dynamics of hotspots of enzyme activity in soil as affected by living and dead roots—a soil zymography analysis , 2014, Plant and Soil.
[9] S. Scheu,et al. Incorporation of 13C labelled glucose into soil microorganisms of grassland: Effects of fertilizer addition and plant functional group composition , 2014 .
[10] T. Eickhorst,et al. Detection and quantification of native microbial populations on soil-grown rice roots by catalyzed reporter deposition-fluorescence in situ hybridization. , 2014, FEMS microbiology ecology.
[11] X. Raynaud,et al. Spatial Ecology of Bacteria at the Microscale in Soil , 2014, PloS one.
[12] Y. Kuzyakov,et al. Distribution of microbial- and root-derived phosphatase activities in the rhizosphere depending on P availability and C allocation – Coupling soil zymography with 14C imaging , 2013 .
[13] E. Blagodatskaya,et al. Active microorganisms in soil: Critical review of estimation criteria and approaches , 2013 .
[14] L. Ruamps,et al. Regulation of soil organic C mineralisation at the pore scale. , 2013, FEMS microbiology ecology.
[15] Davey L. Jones,et al. Temperature adaptation of bacterial growth and C-14-glucose mineralisation in a laboratory study , 2013 .
[16] T. Eickhorst,et al. Spatio-temporal variability of microbial abundance and community structure in the puddled layer of a paddy soil cultivated with wetland rice (Oryza sativa L.) , 2013 .
[17] P. Lemanceau,et al. Going back to the roots: the microbial ecology of the rhizosphere , 2013, Nature Reviews Microbiology.
[18] Mohsen Zarebanadkouki,et al. Where do roots take up water? Neutron radiography of water flow into the roots of transpiring plants growing in soil. , 2013, The New phytologist.
[19] R. Horn,et al. Root and time dependent soil structure formation and its influence on gas transport in the subsoil , 2013 .
[20] A. Osbourn,et al. Comparative metatranscriptomics reveals kingdom level changes in the rhizosphere microbiome of plants , 2013, The ISME Journal.
[21] Z. Cardon,et al. Better to light a candle than curse the darkness: illuminating spatial localization and temporal dynamics of rapid microbial growth in the rhizosphere , 2013, Front. Plant Sci..
[22] Y. Kuzyakov,et al. Biogeochemical transformations of amino acids in soil assessed by position-specific labelling , 2013, Plant and Soil.
[23] Stephan Blossfeld. Light for the dark side of plant life: —Planar optodes visualizing rhizosphere processes , 2013, Plant and Soil.
[24] M. Zarebanadkouki,et al. Comment on: “neutron imaging reveals internal plant water dynamics” , 2013, Plant and Soil.
[25] S. Oswald,et al. Spatio-temporal mapping of local soil pH changes induced by roots of lupin and soft-rush , 2013, Plant and Soil.
[26] Xingliang Xu,et al. Competition between roots and microorganisms for nitrogen: mechanisms and ecological relevance. , 2013, The New phytologist.
[27] J. Eriksen,et al. Bicarbonate as tracer for assimilated C and homogeneity of 14C and 15N distribution in plants by alternative labeling approaches , 2013, Plant and Soil.
[28] Miriam Athmann,et al. Root growth in biopores—evaluation with in situ endoscopy , 2013, Plant and Soil.
[29] Y. Kuzyakov,et al. Soil zymography – A novel in situ method for mapping distribution of enzyme activity in soil , 2013 .
[30] Y. Kuzyakov,et al. Estimation of rhizodeposition at field scale: upscaling of a 14C labeling study , 2013, Plant and Soil.
[31] M. Schloter,et al. Nutrient acquisition from arable subsoils in temperate climates: A review , 2013 .
[32] J. Marshall. Quorum sensing , 2013, Proceedings of the National Academy of Sciences.
[33] Chu-Lin Cheng,et al. Neutron imaging reveals internal plant water dynamics , 2013, Plant and Soil.
[34] M. Mußmann,et al. Gold-FISH: a new approach for the in situ detection of single microbial cells combining fluorescence and scanning electron microscopy. , 2012, Systematic and applied microbiology.
[35] M. Schloter,et al. Dynamics of microbial communities during decomposition of litter from pioneering plants in initial soil ecosystems , 2012 .
[36] K. Kalbitz,et al. Cycling downwards – dissolved organic matter in soils , 2012 .
[37] S. Marhan,et al. Microscale distribution and function of soil microorganisms in the interface between rhizosphere and detritusphere , 2012 .
[38] Davey L. Jones,et al. Mineralization of low molecular weight carbon substrates in soil solution under laboratory and field conditions , 2012 .
[39] Pete Smith,et al. Soil physics meets soil biology: Towards better mechanistic prediction of greenhouse gas emissions from soil , 2012 .
[40] M. Yli-Halla,et al. Structure and pore system in differently managed clayey surface soil as described by micromorphology and image analysis , 2012 .
[41] J. Hobbie,et al. Amino acid cycling in plankton and soil microbes studied with radioisotopes: measured amino acids in soil do not reflect bioavailability , 2012, Biogeochemistry.
[42] Hans-Jörg Vogel,et al. Three-dimensional visualization and quantification of water content in the rhizosphere. , 2011, The New phytologist.
[43] Y. Kuzyakov,et al. Stem labeling results in different patterns of 14C rhizorespiration and 15N distribution in plants compared to natural assimilation pathways , 2011 .
[44] Caroline A. Masiello,et al. Biochar effects on soil biota – A review , 2011 .
[45] Stephan Blossfeld,et al. The dynamics of oxygen concentration, pH value, and organic acids in the rhizosphere of Juncus spp. , 2011 .
[46] E. Blagodatskaya,et al. Drought effects on microbial biomass and enzyme activities in the rhizosphere of grasses depend on plant community composition , 2011 .
[47] T. Eickhorst,et al. Monitoring of root growth and redox conditions in paddy soil rhizotrons by redox electrodes and image analysis , 2011, Plant and Soil.
[48] Y. Kuzyakov,et al. Photoassimilate allocation and dynamics of hotspots in roots visualized by 14C phosphor imaging , 2011 .
[49] L. Ruamps,et al. Microbial biogeography at the soil pore scale , 2011 .
[50] Ingo Klimant,et al. A novel planar optical sensor for simultaneous monitoring of oxygen, carbon dioxide, pH and temperature , 2011, Analytical and bioanalytical chemistry.
[51] Davey L. Jones,et al. Loss of low molecular weight dissolved organic carbon (DOC) and nitrogen (DON) in H2O and 0.5 M K2SO4 soil extracts , 2010 .
[52] Y. Kuzyakov. Priming effects : interactions between living and dead organic matter , 2010 .
[53] B. Guenet,et al. Charcoal mineralisation potential of microbial inocula from burned and unburned forest soil with and without substrate addition , 2010 .
[54] Y. Kuzyakov,et al. Microbial uptake of low‐molecular‐weight organic substances out‐competes sorption in soil , 2010 .
[55] T. Cajthaml,et al. Small-scale distribution of extracellular enzymes, fungal, and bacterial biomass in Quercus petraea forest topsoil , 2010, Biology and Fertility of Soils.
[56] Stephen D. Sebestyen,et al. Hot Spots and Hot Moments in Riparian Zones: Potential for Improved Water Quality Management 1 , 2010 .
[57] L. Bakken,et al. Phosphorus limitation in a Ferralsol: Impact on microbial activity and cell internal P pools , 2010 .
[58] F. Buscot,et al. Laccases: toward disentangling their diversity and functions in relation to soil organic matter cycling , 2010, Biology and Fertility of Soils.
[59] Xavier Raynaud,et al. Soil properties are key determinants for the development of exudate gradients in a rhizosphere simulation model , 2010 .
[60] A. Mentler,et al. Microbial community composition and activity in different Alpine vegetation zones , 2010 .
[61] D. Murphy,et al. In Situ Mapping of Nutrient Uptake in the Rhizosphere Using Nanoscale Secondary Ion Mass Spectrometry1[OA] , 2009, Plant Physiology.
[62] D. Goldberg,et al. Community-level consequences of species interactions in an annual plant community. , 2009 .
[63] Guido Rademaker,et al. Detection of soil water in macropores of undisturbed soil using microfocus X-ray tube computerized tomography (μCT) , 2009 .
[64] K. Klumpp,et al. Grazing triggers soil carbon loss by altering plant roots and their control on soil microbial community , 2009 .
[65] A. V. Bruggen,et al. Daily dynamics of cellulase activity in arable soils depending on management practices , 2009 .
[66] Hans-Jörg Vogel,et al. When Roots Lose Contact , 2009 .
[67] B. Nowack,et al. Sampling, defining, characterising and modeling the rhizosphere—the soil science tool box , 2009, Plant and Soil.
[68] E. Baggs,et al. Biochemical cycling in the rhizosphere having an impact on global change , 2009, Plant and Soil.
[69] P. Brookes,et al. Substrate inputs and pH as factors controlling microbial biomass, activity and community structure in an arable soil , 2009 .
[70] H. Griffiths,et al. Soil priming by sugar and leaf-litter substrates: A link to microbial groups , 2009 .
[71] Y. Kuzyakov,et al. Contrasting effects of glucose, living roots and maize straw on microbial growth kinetics and substrate availability in soil , 2009 .
[72] N. Nadkarni,et al. Growth measurements of saprotrophic fungi and bacteria reveal differences between canopy and forest floor soils , 2009 .
[73] W. Borken,et al. Reappraisal of drying and wetting effects on C and N mineralization and fluxes in soils , 2009 .
[74] M. Simpson,et al. Temperature and substrate controls on microbial phospholipid fatty acid composition during incubation of grassland soils contrasting in organic matter quality. , 2009 .
[75] E. Bååth,et al. Effects of sulfamethoxazole on soil microbial communities after adding substrate. , 2009 .
[76] Y. Kuzyakov. Hotspots in the rhizosphere , 2009 .
[77] F. Makeschin,et al. Rhizosphere soil microbial community structure and microbial activity in set-aside and intensively managed arable land , 2009, Plant and Soil.
[78] L. Ranjard,et al. Impact of wheat straw decomposition on successional patterns of soil microbial community structure , 2009 .
[79] Iain M. Young,et al. Rhizosphere: biophysics, biogeochemistry and ecological relevance , 2009, Plant and Soil.
[80] Arthur J. Gold,et al. Challenges to incorporating spatially and temporally explicit phenomena (hotspots and hot moments) in denitrification models , 2009 .
[81] W. Otten,et al. Microbial distribution in soils: physics and scaling , 2008 .
[82] Rudolf Amann,et al. A single-cell view on the ecophysiology of anaerobic phototrophic bacteria , 2008, Proceedings of the National Academy of Sciences.
[83] Y. Steinberger,et al. Role of perennial plants in determining the activity of the microbial community in the Negev Desert ecosystem , 2008 .
[84] Rainer Schulin,et al. Quantitative Imaging of Infiltration, Root Growth, and Root Water Uptake via Neutron Radiography , 2008 .
[85] Rainer Horn,et al. Three-dimensional quantification of intra-aggregate pore-space features using synchrotron-radiation-based microtomography , 2008 .
[86] T. Eickhorst,et al. Improved detection of soil microorganisms using fluorescence in situ hybridization (FISH) and catalyzed reporter deposition (CARD-FISH) , 2008 .
[87] S. Marhan,et al. Dynamics of litter carbon turnover and microbial abundance in a rye detritusphere , 2008 .
[88] T. Eickhorst,et al. Detection of microorganisms in undisturbed soil by combining fluorescence in situ hybridization (FISH) and micropedological methods , 2008 .
[89] A. M. Semenov,et al. Wave-like Distribution Patterns of Gfp-marked Pseudomonas fluorescens Along Roots of Wheat Plants Grown in Two Soils , 2008, Microbial Ecology.
[90] J. Rousk,et al. Fungal and bacterial growth in soil with plant materials of different C/N ratios. , 2007, FEMS microbiology ecology.
[91] E. Blagodatskaya,et al. Priming effects in chernozem induced by glucose and N in relation to microbial growth strategies , 2007 .
[92] P. Marschner,et al. Chemical changes and phosphorus release during decomposition of pea residues in soil , 2007 .
[93] R. B. Jackson,et al. Toward an ecological classification of soil bacteria. , 2007, Ecology.
[94] H. Flühler,et al. Infiltration through series of soil aggregates: Neutron radiography and modeling , 2007 .
[95] S. Schrader,et al. Assessment of soil structural differentiation around earthworm burrows by means of X-ray computed tomography and scanning electron microscopy , 2007 .
[96] W. Oechel,et al. Erratum to “Microbial activity in soils frozen to below −39 °C”: [Soil Biology & Biochemistry 38(4) (2006) 785–794] , 2006 .
[97] D. Tilman,et al. Resource availability controls fungal diversity across a plant diversity gradient. , 2006, Ecology letters.
[98] Davey L. Jones,et al. Dissolved organic nitrogen dynamics in a Mediterranean vineyard soil , 2006 .
[99] F. Bastida,et al. Microbiological activity in a soil 15 years after its devegetation , 2006 .
[100] L. Barthès,et al. Rapid effects of plant species diversity and identity on soil microbial communities in experimental grassland ecosystems , 2006 .
[101] P. Leffelaar,et al. Oscillating dynamics of bacterial populations and their predators in response to fresh organic matter added to soil: The simulation model 'BACWAVE-WEB' , 2006 .
[102] D. Sauer,et al. Spatial distribution of root exudates of five plant species as assessed by 14C labeling , 2006 .
[103] P. Hallett,et al. Three-dimensional Microorganization of the Soil–Root–Microbe System , 2006, Microbial Ecology.
[104] R. Joergensen,et al. Microbial colonisation of roots as a function of plant species , 2006 .
[105] Anton Hartmann,et al. In situ quantitation of the spatial scale of calling distances and population density-independent N-acylhomoserine lactone-mediated communication by rhizobacteria colonized on plant roots. , 2006, FEMS microbiology ecology.
[106] P. Hugenholtz,et al. Numbers and locations of native bacteria on field-grown wheat roots quantified by fluorescence in situ hybridization (FISH). , 2006, Environmental microbiology.
[107] L. Landi,et al. Microbial activity and hydrolase activities during decomposition of root exudates released by an artificial root surface in Cd-contaminated soils , 2006 .
[108] J. Six,et al. Do growth yield efficiencies differ between soil microbial communities differing in fungal : bacterial ratios? reality check and methodological issues , 2006 .
[109] W. Oechel,et al. Microbial activity in soils frozen to below −39 °C , 2006 .
[110] C. Tebbe,et al. Diversity and phylotype consistency of bacteria in the guts of three bee species (Apoidea) at an oilseed rape field. , 2006, Environmental microbiology.
[111] Sébastien Barot,et al. Size and functional diversity of microbe populations control plant persistence and long‐term soil carbon accumulation , 2005 .
[112] K. Ekschmitt,et al. Strategies used by soil biota to overcome soil organic matter stability — why is dead organic matter left over in the soil? , 2005 .
[113] S. Cuttle,et al. Rapid intrinsic rates of amino acid biodegradation in soils are unaffected by agricultural management strategy , 2005 .
[114] Donald L. Smith,et al. Intracellular and extracellular PGPR: commonalities and distinctions in the plant–bacterium signaling processes , 2005 .
[115] R. Raffa,et al. Bacterial Communication (“Quorum Sensing”) via Ligands and Receptors: A Novel Pharmacologic Target for the Design of Antibiotic Drugs , 2005, Journal of Pharmacology and Experimental Therapeutics.
[116] J. Lynch,et al. Spatial mapping of phosphorus influx in bean root systems using digital autoradiography. , 2004, Journal of experimental botany.
[117] A. Hodge,et al. Plant and mycorrhizal regulation of rhizodeposition. , 2004, The New phytologist.
[118] Matthias C. Rillig,et al. Arbuscular mycorrhizae and terrestrial ecosystem processes , 2004 .
[119] T. Reinthaler,et al. Combining Catalyzed Reporter Deposition-Fluorescence In Situ Hybridization and Microautoradiography To Detect Substrate Utilization by Bacteria and Archaea in the Deep Ocean , 2004, Applied and Environmental Microbiology.
[120] T. Kosaki,et al. Biotic and abiotic processes of nitrogen immobilization in the soil-residue interface , 2004 .
[121] I M Young,et al. Interactions and Self-Organization in the Soil-Microbe Complex , 2004, Science.
[122] B. Lindahl,et al. Carbon allocation to ectomycorrhizal roots and mycelium colonising different mineral substrates. , 2004, The New phytologist.
[123] M. Kimura,et al. Linking microbial community dynamics to rhizosphere carbon flow in a wetland rice soil. , 2004, FEMS microbiology ecology.
[124] T. Vogel,et al. A novel method for characterizing the microscale 3D spatial distribution of bacteria in soil , 2003 .
[125] P. Nannipieri,et al. Microbial diversity and soil functions , 2003 .
[126] Y. Kuzyakov,et al. Turnover and distribution of root exudates of Zea mays , 2003, Plant and Soil.
[127] William H. McDowell,et al. Biogeochemical Hot Spots and Hot Moments at the Interface of Terrestrial and Aquatic Ecosystems , 2003, Ecosystems.
[128] A. Mariotti,et al. The priming effect of organic matter: a question of microbial competition? , 2003 .
[129] J. Crawford,et al. Spatial distribution of bacterial communities and their relationships with the micro-architecture of soil. , 2003, FEMS microbiology ecology.
[130] Joshua P. Schimel,et al. The implications of exoenzyme activity on microbial carbon and nitrogen limitation in soil: a theoretical model , 2003 .
[131] J. Crawford,et al. In Situ Spatial Patterns of Soil Bacterial Populations, Mapped at Multiple Scales, in an Arable Soil , 2002, Microbial Ecology.
[132] David A. Wardle,et al. Linkages between plant litter decomposition, litter quality, and vegetation responses to herbivores , 2002 .
[133] G. Kowalchuk,et al. Effects of above-ground plant species composition and diversity on the diversity of soil-borne microorganisms , 2002, Antonie van Leeuwenhoek.
[134] R. Redfield. Is quorum sensing a side effect of diffusion sensing? , 2002, Trends in microbiology.
[135] C. Nguyen,et al. A carbon-14-glucose assay to compare microbial activity between rhizosphere samples , 2002, Biology and Fertility of Soils.
[136] Ingrid Kögel-Knabner,et al. The macromolecular organic composition of plant and microbial residues as inputs to soil organic matter , 2002 .
[137] G. Grundmann,et al. Spatial Modeling of Nitrifier Microhabitats in Soil , 2001 .
[138] J. Crawford,et al. Quantification of the in situ distribution of soil bacteria by large‐scale imaging of thin sections of undisturbed soil , 2001 .
[139] P. Brookes,et al. Soil microbial biomass is triggered into activity by trace amounts of substrate , 2001 .
[140] Gerard B. M. Heuvelink,et al. Modelling soil variation: past, present, and future , 2001 .
[141] B. Strobel. Influence of vegetation on low-molecular-weight carboxylic acids in soil solution—a review , 2001 .
[142] Richard Webster,et al. Is soil variation random , 2000 .
[143] B. Griffiths,et al. Microbial-faunal interactions in the rhizosphere and effects on plant growth 1 Paper presented at , 2000 .
[144] G. Brown,et al. Regulation of soil organic matter dynamics and microbial activityin the drilosphere and the role of interactionswith other edaphic functional domains , 2000 .
[145] A. Hodge,et al. Are microorganisms more effective than plants at competing for nitrogen? , 2000, Trends in plant science.
[146] B. Griffiths,et al. Substrate heterogeneity and microfauna in soil organic ‘hotspots’ as determinants of nitrogen capture and growth of ryegrass , 2000 .
[147] S. Scheu,et al. Microbial biomass, biovolume and respiration in Lumbricus terrestris L. cast material of different age , 2000 .
[148] S. Scheu,et al. Microbial respiration, biomass, biovolume and nutrient status in burrow walls of Lumbricus terrestris L. (Lumbricidae) , 1999 .
[149] J. Magid,et al. Xylanase, invertase and protease at the soil-litter interface of a loamy sand , 1999 .
[150] N. Talbot. Fungal biology: Coming up for air and sporulation , 1999, Nature.
[151] S. Blagodatsky,et al. Microbial growth in soil and nitrogen turnover: Model calibration with laboratory data , 1998 .
[152] E. Blagodatskaya,et al. Interactive effects of pH and substrate quality on the fungal-to-bacterial ratio and QCO2 of microbial communities in forest soils , 1998 .
[153] A. Hodge,et al. Characterisation and microbial utilisation of exudate material from the rhizosphere of Lolium perenne grown under CO2 enrichment , 1998 .
[154] R. Conrad,et al. Soil microorganisms as controllers of atmospheric trace gases (H2, CO, CH4, OCS, N2O, and NO). , 1996, Microbiological reviews.
[155] J. Prosser,et al. The role of the earthworm Lumbricus terrestris in the transport of bacterial inocula through soil , 1996, Biology and Fertility of Soils.
[156] S. Scheu,et al. Protozoa, Nematoda and Lumbricidae in the rhizosphere of Hordelymus europeaus (Poaceae): faunal interactions, response of microorganisms and effects on plant growth , 1996, Oecologia.
[157] G. Salmond,et al. Multiple N-acyl-L-homoserine lactone signal molecules regulate production of virulence determinants and secondary metabolites in Pseudomonas aeruginosa. , 1995, Proceedings of the National Academy of Sciences of the United States of America.
[158] N. Panikov,et al. Microbial Growth Kinetics , 1995 .
[159] D. Coleman,et al. A hierarchical approach to evaluating the significance of soil biodiversity to biogeochemical cycling , 1995, Plant and Soil.
[160] T. Parkin,et al. Spatial Variability of Microbial Processes in Soil—A Review , 1993 .
[161] C. Price. Fluorescence in situ hybridization. , 1993, Blood reviews.
[162] J. Oades. The role of biology in the formation, stabilization and degradation of soil structure , 1993 .
[163] D. Focht. DIFFUSIONAL CONSTRAINTS ON MICROBIAL PROCESSES IN SOIL , 1992 .
[164] M. Firestone,et al. Metabolic Status of Bacteria and Fungi in the Rhizosphere of Ponderosa Pine Seedlings , 1991, Applied and environmental microbiology.
[165] J. Lynch,et al. Substrate flow in the rhizosphere , 1990, Plant and Soil.
[166] H. Marschner. Mineral Nutrition of Higher Plants , 1988 .
[167] Timothy B. Parkin,et al. Soil Microsites as a Source of Denitrification Variability1 , 1987 .
[168] D. Focht,et al. Conservation in Soil of H2 Liberated from N2 Fixation by Hup- Nodules , 1983, Applied and environmental microbiology.
[169] W. S. Silver. Microbial ecology. , 1967, Science.
[170] E. Griffiths,et al. The use of thin soil sections for the study of soil micro-organisms , 1964, Plant and Soil.
[171] W. Parton,et al. Synthesis and modeling perspectives of rhizosphere priming. , 2014, The New phytologist.
[172] Miriam Athmann,et al. Contribution of anecic earthworms to biopore formation during cultivation of perennial ley crops , 2014 .
[173] Seunghoon Lee,et al. Organic Layer Serves as a Hotspot of Microbial Activity and Abundance in Arctic Tundra Soils , 2012, Microbial Ecology.
[174] C. Keel,et al. Persistence of a biocontrol Pseudomonas inoculant as high populations of culturable and non-culturable cells in 200-cm-deep soil profiles , 2012 .
[175] P. Hallett,et al. Root elongation, water stress, and mechanical impedance: a review of limiting stresses and beneficial root tip traits. , 2011, Journal of experimental botany.
[176] A. Ventosa,et al. Systematic and Applied Microbiology , 2011 .
[177] K. Butterbach‐Bahl,et al. Microclimate and forest management alter fungal-to-bacterial ratio and N2O-emission during rewetting in the forest floor and mineral soil of mountainous beech forests , 2010 .
[178] C. Poll,et al. Small-scale Diversity and Succession of Fungi in the Detritusphere of Rye Residues , 2009, Microbial Ecology.
[179] G. Grundmann,et al. From the micro-scale to the habitat: Assessment of soil bacterial community structure as shown by soil structure directed sampling , 2009 .
[180] M. Adams,et al. Rewetting and litter addition influence mineralisation and microbial communities in soils from a semi-arid intermittent stream , 2009 .
[181] P. Lootens,et al. Microbial community composition and rhizodeposit-carbon assimilation in differently managed temperate grassland soils , 2009 .
[182] C. Rice,et al. Tillage Effects on Microbial and Carbon Dynamics during Plant Residue Decomposition , 2009 .
[183] E. Kandeler,et al. Flooding forested groundwater recharge areas modifies microbial communities from top soil to groundwater table. , 2009, FEMS microbiology ecology.
[184] T. Addiscott,et al. Mineralization of native soil organic matter is not regulated by the size, activity or composition of the soil microbial biomass-a new perspective , 2008 .
[185] S. Morris,et al. THE ECOLOGY OF SOIL ORGANISMS , 2007 .
[186] E. Kandeler,et al. Microbial community composition and functional diversity in the rhizosphere of maize , 2004, Plant and Soil.
[187] S. Scheu,et al. Carbon availability controls the growth of detritivores (Lumbricidae) and their effect on nitrogen mineralization , 2003, Oecologia.
[188] A. Tiunov,et al. Fungal and bacterial communities in Lumbricus terrestris burrow walls: a laboratory experiment , 2002 .
[189] J. Stenström,et al. KINETICS OF SUBSTRATE-INDUCED RESPIRATION (SIR) : THEORY , 1998 .
[190] P. Sale,et al. Initial soil pH affects the pH at which nitrification ceases due to self-induced acidification of microbial microsites , 1997 .
[191] W. Fischer,et al. Redoxprozesse in der Rhizosphäre von Land- und Sumpfpflanzen , 1992 .
[192] J. Prosser. Autotrophic nitrification in bacteria. , 1989, Advances in microbial physiology.
[193] N. Claassen,et al. Phosphatverarmung des wurzelnahen Bodens und Phosphataufnahme von Mais und Raps , 1981 .
[194] D. Sauerbeck,et al. Kurzmitteilung Ein Verfahren zur Trennung von Bodenzonen unterschiedlicher Wurzelnähe , 1981 .