Environ Toxicol Chem 37(8):2153–2164įischer JR, MacQuarrie GR, Malven M, Song Z, Rogan G (2020) Dissipation of DvSnf7 RNA from Late-Season Maize Tissue in Aquatic Microcosms.
Sci Total Environ 724:138223įettweis A, De Schamphelaere K, Smolders E (2018) Zinc toxicity toDaphnia magnain a two-species microcosm can be predicted from single-species test data: The effects of phosphorus supply and pH.
Int Biodeterior Biodegradation 134:93–102Įnya O, Heaney N, Iniama G, Lin C (2020) Effects of heavy metals on organic matter decomposition in inundated soils: Microcosm experiment and field examination. Environ Sci Pollut Res 27(27):34398–34411ĭurban N, Rafrafi Y, Rizoulis A, Albrecht A, Robinet J-C, Lloyd JR, Bertron A, Erable B (2018) Nitrate and nitrite reduction at high pH in a cementitious environment by a microbial microcosm. Ecotoxicol Environ Saf 196:110535ĭu Y, Luo B, Han W, Duan Y, Yu C, Wang M, Ge Y, Chang J (2020b) Increasing plant diversity offsets the influence of coarse sand on ecosystem services in microcosms of constructed wetlands. Heliyon 6(2):e03348ĭu X, Zhu N, Xia X, Xu X (2001) “The theory of microcosm and its application in ecotoxicology.” Acta Ecol Sin 21(10):1726-1733ĭu J, Qv M, Zhang Y, Cui M, Zhang H (2020a) Simulated sulfuric and nitric acid rain inhibits leaf breakdown in streams: A microcosm study with artificial reconstituted fresh water. Sci 33(5):1570–1574ĭong X, Rao D, Tian L, Wang Q, Yang K (2020) A slurry microcosm study on the interaction between antibiotics and soil bacterial community. Sci Total Environ 687:1098–1106Ĭhi J, Yang Q (2012) “Removal and Distribution of Phthalate Acid Esters in Potamogeton crispus L. Int J Environ Sci Technol 16(12):7673–7682Ĭhen H, Yan L, Zhao J, Yang B, Huang G, Shi W, Hou L, Zha J, Luo Y, Mu J, Dong W, Ying GG, Xie L (2019) The role of the freshwater oligochaete Limnodrilus hoffmeisteri in the distribution of Se in a water/sediment microcosm. Écoscience 27(2):119–126Ĭarranza CS, Regñicoli JP, Aluffi ME, Benito N, Chiacchiera SM, Barberis CL, Magnoli CE (2019) Glyphosate in vitro removal and tolerance by Aspergillus oryzae in soil microcosms. Biogeosciences 16(23):4601–4612īyun C, Kim S-Y, Kang H (2020) Elevated concentrations of CO2 and nitrogen alter DOC release and soil phenolic content in wetland microcosms. Aquat Bot 120:169–177īuessecker S, Tylor K, Nye J, Holbert KE, Urquiza Muñoz JD, Glass JB, Hartnett HE, Cadillo-Quiroz H (2019) Effects of sterilization techniques on chemodenitrification and N2O production in tropical peat soil microcosms. Appl Biochem Biotechnol 189(4):1223–1244īonanomi G, Senatore M, Migliozzi A, De Marco A, Pintimalli A, Lanzotti V, Mazzoleni S (2015) Decomposition of submerged plant litter in a Mediterranean reservoir: A microcosm study. Biogeochemistry 140(2):217–232īidja Abena MT, Sodbaatar N, Li T, Damdinsuren N, Choidash B, Zhong W (2019) Crude Oil Biodegradation by Newly Isolated Bacterial Strains and Their Consortium Under Soil Microcosm Experiment. “Food consumption of the cockroach species Blaptica dubia Serville (Blattodea: Blaberidae) using three leaf litter types in a microcosm design.” Applied Soil Ecology 150:103460Īrdón M, Helton AM, Bernhardt ES (2018) Salinity effects on greenhouse gas emissions from wetland soils are contingent upon hydrologic setting: a microcosm experiment. J Hazard Mater 380:120863Īhmed N, Amel H, Mohamed A, Badreddine B, Ibtihel S, Mohamed D, Abdel H, Lamjed M, Ezzeddine M, Hamouda B, Fehmi B (2020) “Chronic ecotoxicity of ciprofloxacin exposure on taxonomic diversity of a meiobenthic nematode community in microcosm experiments.” J King Saud Univ - Sci 32(2):1470–1475.Īrdestani MM, Šustr V, Hnilička F and Frouz J (2020). Ahmad M, Yang Q, Zhang Y, Ling J, Sajjad W, Qi S, Zhou W, Zhang Y, Lin X, Zhang Y, Dong J (2019) The distinct response of phenanthrene enriched bacterial consortia to different PAHs and their degradation potential: a mangrove sediment microcosm study.
0 kommentar(er)
