Occupational exposure dataset for TiO2, carbon black and TiO2 and Ag;X
Creators
- 1. NovaMechanics Ltd
- 2. Det Nationale Forskningscenter for Arbejdsmiljø
- 3. University of Birmingham
Description
The size-resolved emission rate distributions of the nanomaterials supported by occupational exposure web application (https://aerosol.cloud.nanosolveit.eu/) hosted on NanoSolveIT Cloud Platform. distributions are based on experimental data from:
A. J. Koivisto, T. Hussein, R. Niemelä, T. Tuomi and K. Hämeri, Impact of particle emissions of new laser printers on modeled office room, Atmos. Environ., 2010, 44(17), 2140–2146.
V. Gomez, M. Levin, A. T. Saber, S. Irusta, M. Dal Maso and R. Hanoi, et al., Comparison of Dust Release from Epoxy and Paint Nanocomposites and Conventional Products during Sanding and Sawing, Ann. Occup. Hyg., 2014, 58(8), 983–994.
A. J. Koivisto, A. C. Ø. Jensen, K. I. Kling, J. Kling, H. C. Budtz and I. K. Koponen, et al., Particle emission rates during electrostatic spray deposition of TiO2 nanoparticlebased photoactive coating, J. Hazard. Mater., 2018, 341, 218–227.
1 A. J. Koivisto, K. I. Kling, A. S. Fonseca, A. B. Bluhme, M. Moreman and M. Yu, et al., Dip coating of air purifier ceramic honeycombs with photocatalytic TiO2 nanoparticles: A case study for occupational exposure, Sci. Total Environ., 2018, 630, 1283–1291.
Details for the usage of the database can be found in:
P. Tsiros, N. Cheimarios, A. Tsoumanis, A.C.O. Jensen, G. Melagraki, I. Lynch, H. Sarimveis, A. Afantitis, “Towards an in silico Integrated Approach for Testing and Assessment of nanomaterials: from predicted indoor air concentrations to lung dose and biodistribution”, Environmental Science: Nano, 9, 1282, (2022).
https://pubs.rsc.org/en/content/articlelanding/2022/en/d1en00956g