Publications

Found 399 results
Author [ Title(Desc)] Type Year
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C
Zhang K., Wang S., Guo P.H, Guo S.H.  2021.  Characteristics of organic carbon metabolism and bioremediation of petroleum-contaminated soil by a mesophilic aerobic biopile system. Chemosphere. 264:11.
Squartini A, Fusaro S, Concheri G.  2018.  Cheap and portable lab-free respiration assay. Applied Soil Ecology. 123:797-801.
McDaniel M.D, Kaye J.P, Kaye M.W, Bruns M.A.  2014.  Climate change interactions affect soil carbon dioxide efflux and microbial functioning in a post-harvest forest. Oecologia. 174:1437-1448.
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.
Astacio L.MD, Prabhakara K.H, Li Z.Q, Mickalide H., Kuehn S..  2021.  Closed microbial communities self-organize to carbon. Proceedings of the National Academy of Sciences of the United States of America. 118:9.
Juárez MFernández, Prähauser B, Walter A, Insam H, Franke-Whittle IH.  2015.  Co-composting of biowaste and wood ash, influence on a microbially driven-process. Waste Management. 46:155-164.
Holatko J., Hammerschmiedt T., Kintl A., Mustafa A., Naveed M., Baltazar T., Latal O., Skarpa P., Ryant P., Brtnicky M..  2022.  Co-composting of cattle manure with biochar and elemental sulphur and its effects on manure quality, plant biomass and microbiological characteristics of post-harvest soil. Frontiers in Plant ScienceFrontiers in Plant Science. 13:14.
Fritz A.L, Jannoura R., Beuschel R., Steiner C., Buerkert A., Joergensen R.G.  2022.  The combined application of nitrogen and biochar reduced microbial carbon limitation in irrigated soils of West African urban horticulture. Chemical and Biological Technologies in Agriculture. 9:12.
Xu Y.G, Yu W.T, Ma Q., Wang J., Zhou H., Jiang C.M.  2016.  The combined effect of sulfadiazine and copper on soil microbial activity and community structure. Ecotoxicology and Environmental Safety. 134:43-52.
Drage S., Engelmeier D., Bachmann G., Sessitsch A., Mitter B., Hadacek F..  2012.  Combining microdilution with MicroResp (TM): Microbial substrate utilization, antimicrobial susceptibility and respiration. Journal of Microbiological Methods. 88:399-412.
Adapa L.M, Azimi Y., Singh S., Porcelli D., Thompson I.P.  2016.  Comparative study of chemical and physical methods for distinguishing between passive and metabolically active mechanisms of water contaminant removal by biofilms. Water Research. 101:574-581.
Vinten A.JA, Artz R.RE, Thomas N., Potts J.M, Avery L., Langan S.J, Watson H., Cook Y., Taylor C., Abel C. et al..  2011.  Comparison of microbial community assays for the assessment of stream biofilm ecology. Journal of Microbiological Methods. 85:190-198.
Ujvari G., Borsodi A.K, Megyes M., Mucsi M., Szili-Kovacs T., Szabo A., Szalai Z., Jakab G., Marialigeti K..  2020.  Comparison of Soil Bacterial Communities from Juvenile Maize Plants of a Long-Term Monoculture and a Natural Grassland. Agronomy-Basel. 10:15.
Mustafa A., Holatko J., Hammerschmiedt T., Kucerik J., Skarpa P., Kintl A., Racek J., Baltazar T., Malicek O., Brtnicky M..  2022.  Comparison of the Responses of Soil Enzymes, Microbial Respiration and Plant Growth Characteristics under the Application of Agricultural and Food Waste-Derived Biochars. Agronomy-BaselAgronomy-Basel. 12:14.
Lalor B.M, Cookson W.R, Murphy D.V.  2007.  Comparison of two methods that assess soil community level physiological profiles in a forest ecosystem. Soil Biology and Biochemistry. 39:454-462.
Foster KR, Bell T.  2012.  Competition, Not Cooperation, Dominates Interactions among Culturable Microbial Species. Current Biology. 22:1845-1850.
Chodak M., Klimek B., Niklinska M..  2016.  Composition and activity of soil microbial communities in different types of temperate forests. Biology and Fertility of Soils. 52:1093-1104.
Wacker T.S, Jensen L.S, Thorup-Kristensen K..  2022.  Conservation agriculture affects soil organic matter distribution, microbial metabolic capacity and nitrogen turnover under Danish field conditions. Soil & Tillage ResearchSoil & Tillage Research. 224:13.
Bittleston L.S, Gralka M., Leventhal G.E, Mizrahi I., Cordero O.X.  2020.  Context-dependent dynamics lead to the assembly of functionally distinct microbial communities. Nature Communications. 11:10.
Garcia-Palacios P., Shaw E.A, Wall D.H, Hattenschwiler S..  2017.  Contrasting mass-ratio vs. niche complementarity effects on litter C and N loss during decomposition along a regional climatic gradient. Journal of Ecology. 105:968-978.
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.
Oren A., Steinberger Y..  2008.  Coping with artifacts induced by CaCO3–CO2–H2O equilibria in substrate utilization profiling of calcareous soils. Soil Biology and Biochemistry. 40:2569-2577.
Nunes I., Jacquiod S., Brejnrod A., Holm P.E, Johansen A., Brandt K.K, Prieme A., Sorensen S.J.  2016.  Coping with copper: legacy effect of copper on potential activity of soil bacteria following a century of exposure. FEMS Microbiology Ecology. 92:12.
Schoffer J.T, Aponte H., Neaman A., De la Fuente L.M, Arellano E.C, Gil P.M, Ginocchio R..  2022.  Copper content in soils and litter from fruit orchards in Central Chile and its relationship with soil microbial activity. Plant Soil and Environment. 68:115-128.
Polain K., Joice G., Jones D., Pereg L., Nachimuthu G., Knox O.GG.  2019.  Coring lubricants can increase soil microbial activity in Vertisols. Journal of Microbiological Methods. 165:5.