Fan Zhang
Promovendus / contract
- Naam
- Dr. F. Zhang
- Telefoon
- +31 71 527 5615
- f.zhang@cml.leidenuniv.nl
- ORCID iD
- 0000-0003-1709-7788
Zie voor meer informatie de Engelse versie.
Promovendus / contract
- Wiskunde en Natuurwetenschappen
- Centrum voor Milieuwetenschappen Leiden
- CML/Environmental Biology
- Zhang F. (7 november 2023), Modelling the interactions of advanced micro- and nanoparticles with novel entities (Dissertatie. Institute of Environmental Sciences (CML), Faculty of Science, Leiden University). Promotor(en): Vijver M.G. & Peijnenburg W.J.G.M.
- Zhang F., Wang Z., Peijnenburg W.J.G.M. & Vijver M.G. (2023), Machine learning-driven QSAR models for predicting the mixture toxicity of nanoparticles, Environment International 177: 108025.
- Zhang F., Wang Z., Peijnenburg W.J.G.M. & Vijver M.G. (2022), Review and prospects on the ecotoxicity of mixtures of nanoparticles and hybrid nanomaterials, Environmental Science and Technology 56(22): 15238-15250.
- Zhang F., Wang Z., Vijver M.G. & Peijnenburg W.J.G.M. (2022), Theoretical investigation on the interactions of microplastics with a SARS-CoV-2 RNA fragment and their potential impacts on viral transport and exposure, Science of the Total Environment 842: 156812.
- Yu Q., Wang Z., Zhai Y., Zhang F., Vijver M.G. & Peijnenburg W.J.G.M. (2021), Effects of humic substances on the aqueous stability of cerium dioxide nanoparticles and their toxicity to aquatic organisms, Science of the Total Environment 781: 146583.
- Zhang F., Wang Z., Vijver M.G. & Peijnenburg W.J.G.M. (2021), Probing nano-QSAR to assess the interactions between carbon nanoparticles and a SARS-CoV-2 RNA fragment, Ecotoxicology and Environmental Safety 219: 112357.
- Zhang F., Wang Z., Vijver M.G. & Peijnenburg W.J.G.M. (2021), Prediction of the joint toxicity of multiple engineered nanoparticles: the integration of classic mixture models and in silico methods, Chemical Research in Toxicology 34(2): 176-178.
- Wang Z., Zhang F., Vijver M.G. & Peijnenburg W.J.G.M. (2021), Graphene nanoplatelets and reduced graphene oxide elevate the microalgal cytotoxicity of nano-zirconium oxide, Chemosphere 276: 130015.