par Regrain, Corentin;Caudeville, Julien;De Seze, René;Guedda, Mohammed;Chobineh, Amirezza;De Doncker, Philippe 
;Petrillo, Luca ;Chiaramello, Emma;Parazzini, Marta;Joseph, Wout;Aerts, Sam;Huss, Anke;Wiart, Joe JW
Référence International Journal of Environmental Research and Public Health, 17, 5339
Publication Publié, 2020-07-24
;Petrillo, Luca ;Chiaramello, Emma;Parazzini, Marta;Joseph, Wout;Aerts, Sam;Huss, Anke;Wiart, Joe JWRéférence International Journal of Environmental Research and Public Health, 17, 5339
Publication Publié, 2020-07-24
Article révisé par les pairs
| Résumé : | Nowadays, information and communication technologies (mobile phones, connectedobjects) strongly occupy our daily life. The increasing use of these technologies and the complexity ofnetwork infrastructures raise issues about radiofrequency electromagnetic fields (Rf-Emf) exposure.Most previous studies have assessed individual exposure to Rf-Emf, and the next level is to assesspopulational exposure. In our study, we designed a statistical tool for Rf-Emf populational exposureassessment and mapping. This tool integrates geographic databases and surrogate models tocharacterize spatiotemporal exposure from outdoor sources, indoor sources, and mobile phones.A case study was conducted on a 100 x 100 m grid covering the 14th district of Paris to illustratethe functionalities of the tool. Whole-body specific absorption rate (SAR) values are 2.7 times higherthan those for the whole brain. The mapping of whole-body and whole-brain SAR values showsa dichotomy between built-up and non-built-up areas, with the former displaying higher values.Maximum SAR values do not exceed 3.5 and 3.9 mW/kg for the whole body and the whole brain,respectively, thus they are significantly below International Commission on Non-Ionizing RadiationProtection (ICNIRP) recommendations. Indoor sources are the main contributor to populationalexposure, followed by outdoor sources and mobile phones, which generally represents less than 1%of total exposure. |
