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Microwave radiofrequencies, 5G, 6G, graphene nanomaterials: Technologies used in neurological warfare.
Surg Neurol Int
November 2024
Independent Researcher, Ronchin, France.
Background: Scientific literature, with no conflicts of interest, shows that even below the limits defined by the International Commission on Non-Ionizing Radiation Protection, microwaves from telecommunication technologies cause numerous health effects: neurological, oxidative stress, carcinogenicity, deoxyribonucleic acid and immune system damage, electro-hypersensitivity. The majority of these biological effects of non-thermal microwave radiation have been known since the 1970s.
Methods: Detailed scientific, political, and military documents were analyzed.
Ultralight Three-Layer Gradient-Structured MXene/ Reduced Graphene Oxide Composite Aerogels with Broadband Microwave Absorption and Dynamic Infrared Camouflage.
Small
September 2024
Institute of Modern Industrial Technology of SCUT, Zhongshan, Guangdong, 528405, China.
Article Synopsis
- Infrared and radar detectors challenge weapon systems by constantly monitoring, necessitating better stealth technologies than traditional single-band devices.
- A novel gradient-structured MXene/reduced graphene oxide aerogel (GMXrGA) was developed to enhance microwave absorption and dynamic infrared camouflage through a specialized three-layered design.
- GMXrGA boasts an ultralow density, impressive resistance to compression, excellent microwave absorption with a significant reflection loss, low thermal conductivity, and rapid concealment abilities, offering prospects for applications in various high-tech fields.
Directional energy weapons such as high-power microwaves and high-energy lasers pose a huge threat to optoelectronic detection systems. With that in mind, we designed an infrared optical window that has a nonlinear optical response to high-energy lasers and electromagnetic shielding to microwaves. By constructing a periodic metal circular hole array structure at the subwavelength scale, surface plasmons resonance is excited and its local field enhanced characteristics are utilized to form information transmission compatibility in the infrared band.
View Article and Find Full Text PDFMIC: Microwave Imaging Curtain for Dynamic and Automatic Detection of Weapons and Explosive Belts.
Sensors (Basel)
November 2023
Fraunhofer SCAI, D-53757 Sankt Augustin, Germany.
DEXTER (detection of explosives and firearms to counter terrorism) is a project funded by NATO's Science for Peace and Security (SPS) program with the goal of developing an integrated system capable of remotely and accurately detecting explosives and firearms in public places without impeding the flow of pedestrians. While body scanner systems in secure areas of public places are becoming more and more efficient, the attack at Brussels airport on 22 March 2016, upstream of these systems, in the middle of the crowd of passengers, demonstrated the lack of discreet and real-time security against threats of mass terrorism. The NATO-SPS international and multi-year DEXTER project aims to provide new technical and strategic solutions to fill this gap.
View Article and Find Full Text PDFArticle Synopsis
- The U.S. military faces a growing threat from neuroweapons, with medical personnel currently unprepared to diagnose and treat associated health issues.
- Incidents involving U.S. diplomats in Havana, Cuba, and similar reports from China and Russia highlight the difficulty in understanding and addressing unexplained neurological symptoms.
- It's crucial for Special Operations medical teams to be educated about neuroweapons and incorporate relevant training into existing protocols to better respond to these potential threats.
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