胎儿在怀孕期间暴露于2.45至5 GHz电磁波的调查。

IF 0.7 4区环境科学与生态学 Q4 ENVIRONMENTAL SCIENCES

Radiation protection dosimetry Pub Date : 2025-09-25 DOI:10.1093/rpd/ncaf110

Niyazi İl, Kayhan Ateş, Şükrü Özen

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引用次数: 0

摘要

在本文中，我们评估了人体暴露于射频电磁场（RF-EMF）的孕中期胎儿脑和肺的特定吸收率（SAR）。在垂直和水平极化频率范围为2.45 - 5 GHz的入射电磁波下，对正面和侧向入射进行了SAR计算。采用一个真实的孕妇肚脐穿孔模型，对非电离剂量学进行了数值模拟。仿真结果表明，在有肚脐穿刺的情况下，SAR有上升的趋势。胎儿肺部记录的最高SAR10g在2.45 GHz频率下为16 mW/kg。同样，胎儿大脑的最大SAR10g值为14毫瓦/千克，发生在2.45 GHz的频率上。结果表明，金属物体可导致SAR值升高。然而，所获得的数值仍低于电气和电子工程师学会和国际非电离辐射防护委员会等国际组织设定的限值。

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Investigation of fetal exposure to electromagnetic waves between 2.45 and 5 GHz during pregnancy.

In this paper, we have assessed the specific absorption rate (SAR) in fetal brain and lungs during the second trimester of pregnancy conditions of body exposure to radiofrequency electromagnetic field (RF-EMF). SAR calculations were performed for frontal and lateral incidences, with both vertical and horizontal polarization of the incident electromagnetic (EM) waves at frequencies ranging from 2.45 to 5 GHz. A realistic pregnant human model with a belly button piercing was implemented for numerical simulation for nonionizing dosimetry. The simulation results reveal that SAR tends to rise in the presence of belly-button piercing. The highest SAR10g recorded on the fetus's lungs was 16 mW/kg at a frequency of 2.45 GHz. Similarly, the maximum SAR10g value on the fetus's brain was measured 14 mW/kg, occurring at a frequency of 2.45 GHz. Results indicate that metal objects can lead to an increase in SAR values. However, obtained values remain below limits set by international organizations like the Institute of Electrical and Electronics Engineers and the International Commission on Non-Ionizing Radiation Protection.

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来源期刊

Radiation protection dosimetry 环境科学-公共卫生、环境卫生与职业卫生

CiteScore

1.40

自引率

10.00%

发文量

223

审稿时长

6-12 weeks

期刊介绍： Radiation Protection Dosimetry covers all aspects of personal and environmental dosimetry and monitoring, for both ionising and non-ionising radiations. This includes biological aspects, physical concepts, biophysical dosimetry, external and internal personal dosimetry and monitoring, environmental and workplace monitoring, accident dosimetry, and dosimetry related to the protection of patients. Particular emphasis is placed on papers covering the fundamentals of dosimetry; units, radiation quantities and conversion factors. Papers covering archaeological dating are included only if the fundamental measurement method or technique, such as thermoluminescence, has direct application to personal dosimetry measurements. Papers covering the dosimetric aspects of radon or other naturally occurring radioactive materials and low level radiation are included. Animal experiments and ecological sample measurements are not included unless there is a significant relevant content reason.