Absorption of 5G sub-6 GHz electromagnetic radiation from base station to male reproduction system.

Jiajin Lin, Jing Li, Guirong Ding
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Abstract

Background: The impact of electromagnetic radiation from communication on the male reproductive system has emerged as a significant concern in public health. A notable distinction of the 5G sub-6 GHz band, compared to traditional 2G, 3G, and 4G frequency bands, is the inclusion of higher frequency bands. This has raised public concerns regarding the potential effects of these higher frequencies on organisms, particularly their reproductive systems. While it is imperative to investigate the biological effects and potential risks associated with these new frequency bands in laboratory settings, comparing and evaluating differences between various frequency bands remain challenging due to the absence of standardized parameters such as exposure conditions and duration. In contrast, dose assessment offers a simpler and more reliable approach.

Materials and methods: The dose assessment method was employed in this study to investigate the risks associated with sub-6 GHz electromagnetic radiation from 5G base stations on the male reproductive system. A classical human body model (Duke) was utilized, and an electromagnetic simulation environment was established based on the actual polarization direction of the exposed base stations and various body postures. This research explored the effects of field direction, posture, public population, and frequency on the specific absorption rate of the reproductive system.

Results and conclusions: While maintaining the same level of exposure, a higher frequency results in a reduced dosage on reproductive system. Further analysis reveals that, considering the public exposure threshold, the employment of higher frequency bands in 5G sub-6 GHz does not present a greater dosage on reproductive system compared to lower frequency bands. Consequently, with regard to dosage, there is no need for excessive concern among the general public regarding the impact of electromagnetic radiation emitted by 5G base stations operating below 6 GHz on male reproductive health.

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从基站到男性生殖系统对 5G sub-6 GHz 电磁辐射的吸收。
背景:通信电磁辐射对男性生殖系统的影响已成为公共卫生领域的一个重大问题。与传统的 2G、3G 和 4G 频段相比,5G sub-6 GHz 频段的一个显著特点是包含了更高的频段。这引起了公众对这些较高频率对生物,尤其是其生殖系统的潜在影响的担忧。虽然必须在实验室环境中研究这些新频段的生物效应和潜在风险,但由于缺乏标准化参数(如暴露条件和持续时间),比较和评估不同频段之间的差异仍然具有挑战性。相比之下,剂量评估提供了一种更简单、更可靠的方法:本研究采用剂量评估法来调查 5G 基站产生的 6 GHz 以下电磁辐射对男性生殖系统的相关风险。利用经典人体模型(Duke),并根据暴露基站的实际极化方向和各种身体姿势建立电磁模拟环境。这项研究探讨了电场方向、姿势、公共人群和频率对生殖系统特定吸收率的影响:在保持相同暴露水平的情况下,频率越高,对生殖系统的剂量越小。进一步的分析表明,考虑到公众的暴露阈值,在 5G sub-6 GHz 中使用较高的频段与较低的频段相比,不会对生殖系统产生更大的剂量。因此,在剂量方面,公众无需过分担心 6 千兆赫以下 5G 基站发出的电磁辐射对男性生殖健康的影响。
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