Publications

Found 484 results
Author Title [ Type(Asc)] Year
Journal Article
Pinzari F., Cuadros J., Migliore M., Napoli R., Najorka J..  2018.  Manganese translocation and concentration on Quercus cerris decomposing leaf and wood litter by an ascomycetous fungus: an active process with ecosystem consequences? FEMS Microbiology Ecology. 94:16.
Singh BK, Quince C, Macdonald CA, Khachane A, Thomas N, Al-Soud WAbu, Sørensen SJ, He Z, White D, Sinclair A et al..  2014.  Loss of microbial diversity in soils is coincident with reductions in some specialized functions. Environmental Microbiology. 16:2408-2420.
Zhu D.M, Liu Y., Chen J.H, Jiang P.K.  2023.  Long-term successive rotation affects soil microbial resource limitation and carbon use efficiency in Chinese fir (Cunninghamia lanceolata) monoculture plantations. Forest Ecology and Management. 540:10.
Wakelin S.A, Condron L.M, Gerard E., Dignam B.EA, Black A., O'Callaghan M..  2017.  Long-term P fertilisation of pasture soil did not increase soil organic matter stocks but increased microbial biomass and activity. Biology and Fertility of Soils. 53:511-521.
van der Bom F., Nunes I., Raymond N.S, Hansen V., Bonnichsen L., Magid J., Nybroe O., Jensen L.S.  2018.  Long-term fertilisation form, level and duration affect the diversity, structure and functioning of soil microbial communities in the field. Soil Biology and Biochemistry. 122:91-103.
Orozco-Aceves M., Standish R.J, Tibbett M..  2015.  Long-term conditioning of soil by plantation eucalypts and pines does not affect growth of the native jarrah tree. Forest Ecology and Management. 338:92-99.
Campbell C.D, Cameron C.M, Bastias B.A, Chen C.R, Cairney J.WG.  2008.  Long term repeated burning in a wet sclerophyll forest reduces fungal and bacterial biomass and responses to carbon substrates. Soil Biology and Biochemistry. 40:2246-2252.
Tresch S., Frey D., Le Bayon R.C, Zanetta A., Rasche F., Fliessbach A., Moretti M..  2019.  Litter decomposition driven by soil fauna, plant diversity and soil management in urban gardens. Science of The Total Environment. 658:1614-1629.
Liu S.E, Plaza C., Ochoa-Hueso R., Trivedi C., Wang J.T, Trivedi P., Zhou G.Y, Pineiro J., Martins C.SC, Singh B.K et al..  2023.  Litter and soil biodiversity jointly drive ecosystem functions. Global Change Biology. :10.
Richter A., Huallachain D.O, Doyle E., Clipson N., Van Leeuwen J.P, Heuvelink G.B, Creamer R.E.  2018.  Linking diagnostic features to soil microbial biomass and respiration in agricultural grassland soil: a large-scale study in Ireland. European Journal of Soil Science. 69:414-428.
Zhao Y.Z, Liang C.F, Shao S., Chen J.H, Qin H., Xu Q.F.  2021.  Linkages of litter and soil C:N:P stoichiometry with soil microbial resource limitation and community structure in a subtropical broadleaf forest invaded by Moso bamboo. Plant and Soil. :18.
McIntosh ACS, S. Macdonald E, Quideau SA.  2013.  Linkages between the forest floor microbial community and resource heterogeneity within mature lodgepole pine forests. Soil Biology and Biochemistry. 63:61-72.
Blouin M., Karimi B., Mathieu J., Lerch T.Z.  2015.  Levels and limits in artificial selection of communities. Ecology Letters. 18:1040-1048.
Azziz G., Frade C., Igual J.M, del Pino A., Lezama F., Valverde A..  2023.  Legume Overseeding and P Fertilization Increases Microbial Activity and Decreases the Relative Abundance of AM Fungi in Pampas Natural Pastures. Microorganisms. 11:14.
Hoeffner K, Beylich A, Chabbi A, Cluzeau D, Dascalu D, Graefe U, Guzmán G, Hallaire V, Hanisch J, Landa BB et al..  2021.  Legacy effects of temporary grassland in annual crop rotation on soil ecosystem services. Science of The Total Environment. 780:146140.
Smith T.P, Mombrikotb S., Ransome E., Kontopoulos D.G, Pawar S., Bell T..  2022.  Latent functional diversity may accelerate microbial community responses to temperature fluctuations. ElifeElife. 11:22.
Kostin JE, Cesarz S, Lochner A, Schädler M, Macdonald CA, Eisenhauer N.  2021.  Land-use drives the temporal stability and magnitude of soil microbial functions and modulates climate effects. Ecological Applications. 31:e02325.
MacKenzie M.D, Quideau S.A.  2012.  Laboratory-based nitrogen mineralization and biogeochemistry of two soils used in oil sands reclamation. Canadian Journal of Soil Science. 92:131-142.
Albert J., Munoz K..  2022.  Kinetics of microbial and photochemical degradation of aflatoxin B1 in a sandy loam and clay soil. Scientific Reports. 12:11.
Delgado-Baquerizo M., Reich P.B, Khachane A.N, Campbell C.D, Thomas N., Freitag T.E, W. Al-Soud A, Sorensen S., Bardgett R.D, Singh B.K.  2017.  It is elemental: soil nutrient stoichiometry drives bacterial diversity. Environmental Microbiology. 19:1176-1188.
Zaayman M., Siggins A., Horne D., Lowe H., Horswell J..  2017.  Investigation of triclosan contamination on microbial biomass and other soil health indicators. FEMS Microbiology Letters. 364:6.
Zhang C.J, Delgado-Baquerizo M., Drake J.E, Reich P.B, Tjoelker M.G, Tissue D.T, Wang J.T, He J.Z, Singh B.K.  2018.  Intraspecies variation in a widely distributed tree species regulates the responses of soil microbiome to different temperature regimes. Environmental Microbiology Reports. 10:167-178.
Creamer RE, Bellamy P, Black HIJ, Cameron CM, Campbell CD, Chamberlain P, Harris J, Parekh N, Pawlett M, Poskitt J et al..  2009.  An inter-laboratory comparison of multi-enzyme and multiple substrate-induced respiration assays to assess method consistency in soil monitoring. Biology and Fertility of Soils. 45:623-633.
Bao X.L, Yu J., Liang W.J, Lu C.Y, Zhu J.G, Li Q..  2015.  The interactive effects of elevated ozone and wheat cultivars on soil microbial community composition and metabolic diversity. Applied Soil Ecology. 87:11-18.
Yu X.Q, Polz M.F, Alm E.J.  2019.  Interactions in self-assembled microbial communities saturate with diversity. Isme Journal. 13:1602-1617.