Nanoparticulate mineral UV filters, such as titanium dioxide (TiO 2) nanocomposites, are being increasingly used in sunscreens as an alternative to organic UV filters. However, there is still a lack of understanding regarding their fate and behavior in aquatic environments and potential environmental impacts after being released from a bather's skin during recreational activities. In this work, we assessed the release, fate, and transformation of two commercial nanocomposite TiO 2 UV filters, one hydrophobic and one hydrophilic, in ultrapure water and simulated fresh-and seawater. The hydrophobic TiO 2 nanocomposite, T-SA, was coated with a primary Al 2 O 3 photopassivation layer and a secondary stearic acid layer, while the hydrophilic TiO 2 nanocomposite, T-SiO 2 , was coated with a single SiO 2 photopassivation layer. The influence of the sunscreen formulation was examined by dispersing the TiO 2 nanocomposites in their typical continuous phase (i.e., oil for T-SA and water for T-SiO 2) before introduction into the aqueous system. After 48 h of aqueous aging and 48 h of settling, 88e99% of the hydrophobic T-SA remained floating on top of the water column in all aqueous systems. On the other hand, 100% of the hydrophilic T-SiO 2 settled out of the water column in the fresh-and seawaters. With respect to the photopassivation coatings, no loss of the T-SA Al 2 O 3 layer was detected after aqueous aging, but 99e100% dissolution of the SiO 2 layer on the T-SiO 2 nanocomposite was observed after 48 h in the fresh-and seawaters. This dissolution left behind T-SiO 2 by-products exhibiting a photocatalytic activity similar to that of bare rutile TiO 2. Overall, the results demonstrated that the TiO 2 surface coating and sunscreen formulation type drive environmental behavior and fate and that loss of the passivation layer can result in potentially harmful, photoactive by-products. These insights will help guide regulations and assist manufacturers in developing more environmentally safe sunscreens.