Numerical dosimetry of specific absorption rate of insects exposed to far-field radiofrequency electromagnetic fields.

International journal of radiation biology Pub Date : 2025-01-02 DOI:10.1080/09553002.2024.2442693

Vera Jeladze, Tamar Nozadze, Besarion Partsvania, Arno Thielens, Levan Shoshiashvili, Teimuraz Gogoladze

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Abstract

Purpose: This paper reports a study of electromagnetic field (EMF) exposure of several adult insects: a ladybug, a honey bee worker, a wasp, and a mantis at frequencies ranging from 2.5 to 100 GHz. The purpose was to estimate the specific absorption rate (SAR) in insect tissues, including the brain, in order to predict the possible biological effects caused by EMF energy absorption.

Method: Numerical dosimetry was executed using the finite-difference time-domain (FDTD) method. Insects were modeled as 3-tissue heterogeneous dielectric objects, including the cuticle, the inner tissue, and the brain tissue. The EMF source was modeled as sinusoidal plane waves at a single frequency (far-field exposure).

Results: The whole-body averaged, tissue averaged, and 1 milligram SAR values were determined in insects for all considered frequencies for 10 different incident plane waves. SAR values were normalized to the incident power density of 1 mW/cm². Maximal EMF absorption in the inner and brain tissues was observed at 6, 12, and 25 GHz for the considered insects, except the brain tissue of a ladybug (max at 60 GHz).

Conclusion: The paper presented the first estimation of the SAR for multiple insects over a wide range of RF frequencies using 3-tissue heterogenous insect 3D models created for this specific research. The selection of tissues' dielectric properties was validated. The obtained results showed that EMF energy absorption in insects highly depends on frequency, polarization, and insect morphology.

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暴露于远场射频电磁场的昆虫特定吸收率的数值剂量学。

目的：本文报道了几种成虫（瓢虫、工蜂、黄蜂和螳螂）在2.5至100 GHz频率下的电磁场暴露研究。目的是估计昆虫组织（包括大脑）的比吸收率（SAR），以预测EMF能量吸收可能引起的生物效应。方法：采用时域有限差分法（FDTD）进行数值剂量测定。将昆虫建模为3组织非均匀介质物体，包括角质层、内部组织和脑组织。电磁场源被建模为单频的正弦波平面波（远场暴露）。结果：在10种不同的入射平面波的所有考虑频率下，测定了昆虫的全身平均值、组织平均值和1毫克的SAR值。SAR值归一化为1 mW/cm2的入射功率密度。除瓢虫的脑组织（最大吸收频率为60 GHz）外，在所考虑的昆虫体内和脑组织中观察到的最大电磁场吸收频率为6、12和25 GHz。结论：本文首次利用为此特定研究创建的3组织异质昆虫3D模型，在广泛的射频频率范围内估计了多种昆虫的SAR。对组织介电性能的选择进行了验证。结果表明，昆虫对电动势能的吸收高度依赖于频率、极化和昆虫形态。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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International journal of radiation biology

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