Journal of Radiation Research and Radiation Processing, Volume. 41, Issue 1, 010302(2023)
Variations and uncertainty in electromagnetic dose caused by weight differences of experimental animals
[1] A Hirata, Y L Diao, T Onishi et al. Assessment of human exposure to electromagnetic fields: review and future directions. IEEE Transactions on Electromagnetic Compatibility, 63, 1619-1630(2021).
[2] J Kim, K Lee, B Kim et al. Numerical and experimental assessments of focused microwave thermotherapy system at 925 MHz. ETRI Journal, 41, 850-862(2019).
[3] Yanping LIN, Mai LU, Xi LIU et al. Study on electromagnetic field and temperature field distribution in animal model during magnetic induction hyperthermia. Journal of Biomedical Engineering Research, 38, 16-21(2019).
[4] J Chakarothai, J J Shi, J Q Wang et al. Numerical techniques for SAR assessment of small animals in reverberation chamber. IEEE Electromagnetic Compatibility Magazine, 4, 57-66(2015).
[5] A Bamba, W Joseph, G Vermeeren et al. A formula for human average whole-body SARwb under diffuse fields exposure in the GHz region. Physics in Medicine and Biology, 59, 7435-7456(2014).
[6] J Chakarothai, K Wake, S Watanabe. Convergence of a single-frequency FDTD solution in numerical dosimetry. IEEE Transactions on Microwave Theory and Techniques, 64, 707-714(2016).
[7] Jiakai TONG, Hongxin QI, Xianghui WANG et al. Simulation calculation of electric field distribution in rats irradiated using broadband electromagnetic pulse. Journal of Radiation Research and Radiation Processing, 40, 020702(2022).
[8] E A Rashed, J Gomez-Tames, A Hirata. Human head skin thickness modeling for electromagnetic dosimetry. IEEE Access, 7, 46176-46186.
[9] S Dahdouh, N Varsier, M A Nunez Ochoa et al. Infants and young children modeling method for numerical dosimetry studies: application to plane wave exposure. Physics in Medicine and Biology, 61, 1500-1514(2016).
[10] N Kuster, V B Torres, N Nikoloski et al. Methodology of detailed dosimetry and treatment of uncertainty and variations for in vivo studies. Bioelectromagnetics, 27, 378-391(2006).
[11] P Gajsek, W D Hurt, J M Ziriax et al. Parametric dependence of SAR on permittivity values in a man model. IEEE Transactions on Biomedical Engineering, 48, 1169-1177(2001).
[12] E Conil, A Hadjem, A Gati et al. Influence of plane-wave incidence angle on whole body and local exposure at 2100 MHz. IEEE Transactions on Electromagnetic Compatibility, 53, 48-52(2011).
[13] S Iskra, R McKenzie, I Cosic. Factors influencing uncertainty in measurement of electric fields close to the body in personal RF dosimetry. Radiation Protection Dosimetry, 140, 25-33(2010).
[14] X H Wang, C J Xia, L Lu et al. Electromagnetic exposure dosimetry study on two free rats at 1.8 GHz via numerical simulation. Frontiers in Public Health, 9, 721166(2021).
[15] K K Kesari, J Behari, S Kumar. Mutagenic response of 2.45 GHz radiation exposure on rat brain. International Journal of Radiation Biology, 86, 334-343(2010).
[16] R Kitchen. RF andmicrowave radiation safety, 60-62(2001).
[17] J C Lin. Electromagnetic fields in biological systems, 24(2012).
Get Citation
Copy Citation Text
Yichen SUN, Dan DU, Jing LI, Jiajin LIN. Variations and uncertainty in electromagnetic dose caused by weight differences of experimental animals[J]. Journal of Radiation Research and Radiation Processing, 2023, 41(1): 010302
Category: Research Articles
Received: Oct. 27, 2022
Accepted: Dec. 5, 2022
Published Online: Mar. 6, 2023
The Author Email: