Background and aim: Coronavirus disease (COVID-19) public health policy has focused on the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) virus and its effects on human health while environmental factors have been largely ignored. In considering the epidemiological triad (agent-host-environment) applicable to all disease, we investigated a possible environmental factor in the COVID-19 pandemic: ambient radiofrequency radiation from wireless communication systems including microwaves and millimeter waves. SARS-CoV-2, the virus that caused the COVID-19 pandemic, surfaced in Wuhan, China shortly after the implementation of city-wide (fifth generation [5G] of wireless communications radiation [WCR]), and rapidly spread globally, initially demonstrating a statistical correlation to international communities with recently established 5G networks. In this study, we examined the peer-reviewed scientific literature on the detrimental bioeffects of WCR and identified several mechanisms by which WCR may have contributed to the COVID-19 pandemic as a toxic environmental cofactor. By crossing boundaries between the disciplines of biophysics and pathophysiology, we present evidence that WCR may: (1) cause morphologic changes in erythrocytes including echinocyte and rouleaux formation that can contribute to hypercoagulation; (2) impair microcirculation and reduce erythrocyte and hemoglobin levels exacerbating hypoxia; (3) amplify immune system dysfunction, including immunosuppression, autoimmunity, and hyperinflammation; (4) increase cellular oxidative stress and the production of free radicals resulting in vascular injury and organ damage; (5) increase intracellular Ca²⁺ essential for viral entry, replication, and release, in addition to promoting pro-inflammatory pathways; and (6) worsen heart arrhythmias and cardiac disorders.

And this…

The mechanisms by which various biological effects are triggered by exposure to an electromagnetic field are not fully understood and have been the subject of debate. Here, the effects of exposing typical representatives of the major microbial taxa to an 18 GHz microwave electromagnetic field (EMF)were studied. It appeared that the EMF exposure induced cell permeabilisation in all of the bacteria and yeast studied, while the cells remained viable (94% throughout the exposure), independent of the differences in cell membrane fatty acid and phospholipid composition. The resulting cell permeabilisation was confirmed by detection of the uptake of propidium iodine and 23 nm fluorescent silica nanospheres using transmission electron microscopy (TEM) and confocal laser scanning microscopy (CLSM). Upon EMF exposure, the bacterial cell membranes are believed to become permeable through quasi-endocytosis processes. The dosimetry analysis revealed that the EMF threshold level required to induce the uptake of the large (46 nm) nanopsheres was between three and six EMF doses, with a specific absorption rate (SAR) of 3 kW/kg and 5 kW/kg per exposure, respectively, depending on the bacterial taxa being studied. It is suggested that the taxonomic affiliation and lipid composition (e.g. the presence of phosphatidyl-glycerol and/or pentadecanoic fatty acid) may affect the extent of uptake of the large nanospheres (46 nm). Multiple 18 GHz EMF exposures over a one-hour period induced periodic anomalous increases in the cell growth behavior of two Staphylococcus aureus strains, namely ATCC 25923 and CIP 65.8T.

More on this (via comment)

I had a disagreement on bitchute with David Knight about this issue. One of the commenters stated that 5G cannot go above a certain GHz threshold. Then I showed him this…The third sentence clarifies what frequencies are attributable to 5G.

The videos out there indicate an 18GHz transmission to be delivered on Oct.4th. I would not take any chances either. And please forgive me I’m tired and forget your name.

An Exploration of 5G Wireless Network Attenuation Using Finite Element Analysis in COMSOL Multiphysics

1. Abstract:
5G, ultra-high frequency wireless networks face numerous hurdles due to significant
signal attenuation in materials and large path loss. Empirical research on signal attenuation has
been limited to low frequencies or very select high frequencies. This paper utilizes Finite
Element Analysis in COMSOL Multiphysics to analyze signal attenuation in materials over a
range of the frequency spectrum, from 100Mhz to 40Ghz, which is inclusive of 5G wireless
frequencies. The focus of this paper is on glass and dry wood, as well as wet wood
(representative of trees), as these materials are some of the most likely to stand in the way
between users and cellular nodes. Utilizing various finite element mesh sizes, the analysis found
that moderate signal attenuation starts to occur at frequencies above 10GHz, with more severe
attenuation starting to occur in the 20-30GHz range. Glass and wet wood effectively block all
signals above 30GHz, and while dry wood doesn’t lead to attenuation as severe as glass or wet
wood, it is still large enough to make signal reception behind such a material impractical.

Now look at these on Google Scholar concerning EMF frequency warfare.

https://scholar.google.ca/scholar?as_ylo=2019&q=emf+frequency+warfare&hl=en&as_sdt=0,10

And a very explicit video from a few years ago about the U.S. military can actually do. Probably a lot more than we could even imagine.

https://www.youtube.com/watch?v=N02SK9yd60s

Dr. James Giordano: The Brain is the Battlefield of the Future