Publications

Found 399 results
[ Author(Desc)] Title Type Year
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C
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.
Creamer R.E, Stone D., Berry P., Kuiper I..  2016.  Measuring respiration profiles of soil microbial communities across Europe using MicroResp™ method. Applied Soil Ecology. 97:36-43.
Csontos P., Mucsi M., Ragalyi P., Tamas J., Kalapos T., Papay G., Mjazovszky A., Penksza K., Szili-Kovacs T..  2021.  Standing Vegetation Exceeds Soil Microbial Communities in Soil Type Indication: A Procrustes Test of Four Salt-Affected Pastures. Agronomy-Basel. 11:12.
Cui H.Y, Vitousek P.M, Reed S.C, Sokoya B., Bamigboye A.R, Mukherjee A., Penaloza-Bojaca G.FP, Teixido A.L, Trivedi P., He J.Z et al..  2022.  Environmental filtering controls soil biodiversity in wet tropical ecosystems. Soil Biology and Biochemistry. 166:9.
Curlevski N.JA, Artz R.RE, Anderson I.C, Cairney J.WG.  2011.  Response of soil microbial communities to management strategies for enhancing Scots pine (Pinus sylvestris) establishment on heather (Calluna vulgaris) moorland. Plant and Soil. 339:413-424.
Currey P.M, Johnson D., Sheppard L.J, Leith I.D, Toberman H., van der Wal R., Dawson L.A, Artz R.RE.  2010.  Turnover of labile and recalcitrant soil carbon differ in response to nitrate and ammonium deposition in an ombrotrophic peatland. Global Change Biology. 16:2307-2321.
D
D'Hervilly C., Marsden C., Capowiez Y., Beral C., Delapre-Cosset L., Bertrand I..  2021.  Trees and herbaceous vegetation strips both contribute to changes in soil fertility and soil organism communities in an agroforestry system. Plant and Soil. :17.
Dacal M, García-Palacios P, Asensio S, Cano-Díaz C, Gozalo B, Ochoa V, Maestre FT.  2020.  Contrasting mechanisms underlie short- and longer-term soil respiration responses to experimental warming in a dryland ecosystem. Global Change Biology. 26:5254-5266.
Dacal M., Bradford M.A, Plaza C., Maestre F.T, Garcia-Palacios P..  2019.  Soil microbial respiration adapts to ambient temperature in global drylands. Nature Ecology & Evolution. 3:232-+.
Dacal M., Garcia-Palacios P., Asensio S., Wang J.T, Singh B.K, Maestre F.T.  2022.  Climate change legacies contrastingly affect the resistance and resilience of soil microbial communities and multifunctionality to extreme drought. Functional Ecology. 36:908-920.
Dacal M, Delgado-Baquerizo M, Barquero J, Berhe AAsefaw, Gallardo A, Maestre FT, García-Palacios P.  2022.  Temperature Increases Soil Respiration Across Ecosystem Types and Soil Development, But Soil Properties Determine the Magnitude of This Effect. Ecosystems. 25:184-198.
Dalmonech D., Lagomarsino A., Moscatelli M.C, Chiti T., Valentini R..  2010.  Microbial performance under increasing nitrogen availability in a Mediterranean forest soil. Soil Biology and Biochemistry. 42:1596-1606.
Date V., Nwaishi F.C, Price J.S, Andersen R..  2018.  Short-term exposure to Oil Sand Process-Affected Water does not reduce microbial potential activity in three contrasting peatland types. Wetlands. 38:769-778.
Davey RS, McNeill AM, Barnett SJ, Gupta VVSR.  2021.  Potential for suppression of Rhizoctonia root rot is influenced by nutrient (N and P) and carbon inputs in a highly calcareous coarse-textured topsoil. Soil Research. :-.
Davies T.KR, Lovelock C.E, Pettit N.E, Grierson P.F.  2017.  Short-term microbial respiration in an arid zone mangrove soil is limited by availability of gallic acid, phosphorus and ammonium. Soil Biology and Biochemistry. 115:73-81.
Dawson J.JC, Adhikari Y.R, Soulsby C., Stutter M.I.  2012.  The biogeochemical reactivity of suspended particulate matter at nested sites in the Dee basin, NE Scotland. Science of The Total Environment. 434:159-170.
de Dato G., Lagomarsino A., Lellei-Kovacs E., Liberati D., R. Jaoude A, Marabottini R., Stazi S.R, Guidolotti G., Kovacs-Lang E., Kroel-Dulay G. et al..  2017.  The Response of Soil CO2 Efflux to Water Limitation Is Not Merely a Climatic Issue: The Role of Substrate Availability. Forests. 8:22.
de Varennes A., Cunha-Queda C., Qu G.W.  2010.  Amendment of an Acid Mine Soil with Compost and Polyacrylate Polymers Enhances Enzymatic Activities but may Change the Distribution of Plant Species. Water Air and Soil Pollution. 208:91-100.
de Varennes A., Qu G., Cordovil C., Goncalves P..  2011.  Soil quality indicators response to application of hydrophilic polymers to a soil from a sulfide mine. Journal of Hazardous Materials. 192:1836-1841.
de Vries F.T, Williams A., Stringer F., Willcocks R., McEwing R., Langridge H., Straathof A.L.  2019.  Changes in root-exudate-induced respiration reveal a novel mechanism through which drought affects ecosystem carbon cycling. New Phytologist. 224:132-145.
Delgado-Baquerizo M., Trivedi P., Trivedi C., Eldridge D.J, Reich P.B, Jeffries T.C, Singh B.K.  2017.  Microbial richness and composition independently drive soil multifunctionality. Functional Ecology. 31:2330-2343.
Delgado-Baquerizo M., Morillas L., Maestre F.T, Gallardo A..  2013.  Biocrusts control the nitrogen dynamics and microbial functional diversity of semi-arid soils in response to nutrient additions. Plant and Soil. 372:643-654.
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.
Delgado-Baquerizo M., Reich P.B, Trivedi C., Eldridge D.J, Abades S., Alfaro F.D, Bastida F., Berhe A.A, Cutler N.A, Gallardo A. et al..  2020.  Multiple elements of soil biodiversity drive ecosystem functions across biomes. Nature Ecology & Evolution. 4:210-220.
Delgado-Baquerizo M., Garcia-Palacios P., Milla R., Gallardo A., Maestre F.T.  2015.  Soil characteristics determine soil carbon and nitrogen availability during leaf litter decomposition regardless of litter quality. Soil Biology and Biochemistry. 81:134-142.