PUBLICATIONS

Citations – 591; h-index – 15; i10-index – 17
Source: https://scholar.google.com/citations?user=JIlVCLcAAAAJ&hl=en

In preparation

  1. Ma, Y., Jetten. M., Welte, C., Glodowska, M., 2024. Interference of Heavy Metals with Nitrate-Dependent Anaerobic
    Methane Oxidation (N-DAMO) – a case study of chromium. In prep.
  2. Struik, Q., Paranaíba, J.R., Veraart, A., Meulenpas, B., Glodowska, M., Waaijen, G., Kosten, S., 2023. Fe(II)Cl2 mitigates eutrophication and greenhouse gas production, through iron-dependent anaerobic oxidation of methane.
    Submitted to Geoderma
  3. Wissink, M., Glodowska, M., van der Kolk, M., Jetten, M., Welte, C. 2023. Probing Denitrifying Anaerobic Methane Oxidation via Antimicrobial Intervention: Implications for Innovative Wastewater Management. Under revision in ES&T

Published

  1. Legierse, A., Struik, Q., Smith, G., Echeveste Medrano, M.J., Weideveld, S., van Dijk, G., Smolders, A.J., Jetten, M.,
    Veraart, A.J., Welte, C.U. and Glodowska, M., 2023. Nitrate-dependent anaerobic methane oxidation (N-DAMO) as a bioremediation strategy for waters affected by agricultural runoff. FEMS Microbiology Letters, 370, p.fnad041.  
  2. Glodowska, M., Ma, Y., Smith, G., Kappler, A., Jetten, M. and Welte, C.U., 2023. Nitrate leaching and its implication for Fe and As mobility in a Southeast Asian aquifer. FEMS Microbiology Ecology, 99(4), p.fiad025.
  3. Glodowska, M., Welte, C.U. and Kurth, J.M., 2022. Metabolic potential of anaerobic methane-oxidizing archaea for a broad spectrum of electron acceptors. Advances in microbial physiology, 80, pp.157-201.
  4. Lightfoot, A.K., Brennwald, M.S., Prommer, H., Stopelli, E., Berg, M., Glodowska, M., Schneider, M. and Kipfer, R. Noble gas constraints on the fate of arsenic in groundwater. Water Research, 214, p.118199.
  5. Glodowska, M., Pienkowska, A., Mansor, M., Buchner, D., Straub, D., Kleindienst, S. and Kappler, A., 2021. Isotopic Labeling Reveals Microbial Methane Oxidation Coupled to Fe (III) Mineral Reduction in Sediments from an As-Contaminated Aquifer. Environmental Science & Technology Letters, 8(9), pp.832-837.
  6. Stopelli, E., Duyen, V.T., Prommer, H., Glodowska, M., Kappler, A., Schneider, M., Eiche, E., Lightfoot, A.K., Schubert, C.J., Trang, P.K. and Viet, P.H., 2021.
    Carbon and methane cycling in arsenic-contaminated aquifers. Water research, 200, p.117300
  7. Glodowska, M., Schneider, M., Eiche, E., Kontny, A., Neumann, T., Straub, D., Kleindienst, S. and Kappler, A., 2021. Microbial transformation of biogenic and abiogenic Fe minerals followed by in-situ incubations in an As-contaminated vs. non-contaminated aquifer. Environmental Pollution, 281, p.117012.
  8. Glodowska, M., Schneider, M., Eiche, E., Kontny, A., Neumann, T., Straub, D., Berg, M., Prommer, H., Bostick, B.C., Nghiem, A.A. and Kleindienst, S., 2021. Fermentation, methanotrophy and methanogenesis influence sedimentary Fe and As dynamics in As-affected aquifers in Vietnam. Science of the Total Environment, 779, p.146501.
  9. Kontny, A., Schneider, M., Eiche, E., Stopelli, E., Glodowska, M., Rathi, B., Göttlicher, J., Byrne, J.M., Kappler, A., Berg, M. and Thi, D.V., 2021.
    Iron mineral transformations and their impact on As (im)mobilization at redox interfaces in As-contaminated aquifers. Geochimica et Cosmochimica Acta, 296, pp.189-209.
  10. Glodowska, M., Stopelli, E., Straub, D., Thi, D.V., Trang, P.T., Viet, P.H., Berg, M., Kappler, A. and Kleindienst, S., Arsenic behavior in groundwater in Hanoi (Vietnam) influenced by a complex biogeochemical network of iron, methane, and sulfur cycling. Journal of Hazardous Materials, 407, p.124398.
  11. Glodowska, M., Stopelli, E., Schneider, M., Rathi, B., Straub, D., Lightfoot, A., Kipfer, R., Berg, M., Jetten, M., Kleindienst, S. and Kappler, A., 2020.
    Arsenic mobilization by anaerobic iron-dependent methane oxidation.
    Communications Earth & Environment, 1(1), pp.1-7
  12. Glodowska, M., Stopelli, E., Schneider, M., Lightfoot, A., Rathi, B., Straub, D., Patzner, M., Duyen, V.T., AdvectAs Team Members, Berg, M. and Kleindienst, S., 2020. Role of in situ natural organic matter in mobilizing as during microbial reduction of feiii-mineral-bearing aquifer sediments from Hanoi (Vietnam). Environmental Science & Technology, 54(7), pp.4149-4159.
  13. Glodowska, M. and Wozniak, M., 2019. Changes in soil microbial activity and community composition as a result of selected agricultural practices. Agricultural Sciences, 10(3), pp.330-351.
  14. Glodowska, M. and Krawczyk, J., 2019. Difference in the Concentration of Macro Elements between Organically and Conventionally Grown Vegetables. Agricultural Sciences, 10(3), pp.267-277.
  15. Woźniak, M., Gałązka, A., Grządziel, J. and Glodowska, M., 2018. The identification and genetic diversity of endophytic bacteria isolated from selected crops. The Journal of Agricultural Science, 156(4), pp.547-556.
  16. Glodowska, M. and Krawczyk, J., 2017. Heavy metals concentration in conventionally and organically grown vegetables. Quality Assurance and Safety of Crops & Foods, 9(4), pp.497-503.
  17. Glodowska, M., Schwinghamer, T., Husk, B. and Smith, D., 2017. Biochar-based inoculants improve soybean growth and nodulation. Agricultural Sciences, 8(9), pp.1048-1064.
  18. Glodowska, M., Husk, B., Schwinghamer, T. and Smith, D., 2016. Biochar is a growth-promoting alternative to peat moss for the inoculation of corn with a pseudomonad. Agronomy for sustainable development, 36(1), pp.1-10.

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