Tag Archives: Detecting Explosives Remotely

Matching Molecular Magnetic Field of High Explosives in Afghanistan

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High explosive munitions in Afghanistan – 3rdID8487 military videos


The area-specific molecular magnetic field of an assortment of high explosive munitions shown in the photograph was matched from a 2010 video of U.S. Explosive Ordnance Disposal (EOD) technicians of the 717th EOD Company, Fort Campbell, Ky. You can view the video here.

One day in the not too distant future, scientists will acknowledge that the weak magnetic field of molecular structures can be replicated either directly by hand or indirectly via sound recordings. I have written numerous articles at this site on how this can be accomplished and have given examples that can be explored and analyzed. Biological systems can be matched in the same way. This is possible because of a particular pattern recognition ability I have with weak electromagnetic fields. It is a similar process to that of developing the skill of human echolocation but in this case it is the skill of interpreting weak electromagnetic fields and their physiological effect on the body. Eventually researchers will develop the tools to validate what I am sharing with you today.

There is a treasure trove of information that can be gleaned from audio recordings that offers detailed information about area-specific weak molecular fields that can be analyzed by devices tuned into this information. The electromagnetic field from the audio coil in your speaker is replicating this weak field that is frozen in time as an archived audio recording, but there is no reason that a live audio stream cannot be used as a tool for remote real time analysis.

Recorded audio captures area-specific weak magnetic fields in nature. The reason is, it is capturing the background- underlying sound of the atoms vibrating in that area. They are vibrating in a unique way according to how the molecular structures are aligned. In the case of an audio recording, it is the aggregate field that is being captured. The recording when played back not only makes the audible mechanical sounds that we all know about, but also the electromagnetic field emanating from the electrical coil in your speaker is replicating the area specific-weak magnetic field. This replicated field can be extracted and matched. I do it manually.

Here is the molecular field match for the high explosive munitions extracted from the video as a mp3 audio file.

Twitt

Easing Mideast Tensions – Monitoring Iranian Nuclear Fuel Remotely via Audio

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President Mahmoud Ahmadinejad inspecting nuclear fuel rod – released by HOPD / Iranian President’s Office

There may be another method for nuclear weapons inspectors and other government agencies to remotely monitor for the presence of enriched uranium used in nuclear devices. It is my view that one day soon, scientists will recognize the fact that recorded audio captures area-specific weak magnetic fields. The reason is, it is capturing the background, underlying sound of the atoms vibrating in that area. They are vibrating in a unique way according to how the molecular structures are aligned. In the case of an audio recording, it is the aggregate field that is being captured. The recording when played back not only makes the audible mechanical sounds that we all know about, but also the electromagnetic field emanating from the electrical coil in your speaker is replicating the area-specific weak magnetic field. This replicated field can be matched and/or the frequency signature of nuclear fuel, non weapons-grade uranium in this scenario, can be detected in this field.

Playing area-specific audio thru a Mobius coil plugged into audio jack in computer. Screening the electromagnetic field by hand.

This is possible because of a particular pattern recognition ability I have with weak electromagnetic fields. It is a similar process to that of developing the skill of human echolocation but in this case it is the skill of interpreting weak electromagnetic fields and their physiological effect on the body. Eventually researchers will develop the tools to validate what I am sharing with you today.

Audio recordings or live audio feeds offer detailed information about area-specific weak molecular fields that can be analyzed by devices tuned into this information. The electromagnetic field from the audio coil in your speaker is replicating this weak field that is frozen in time as an archived audio recording, but there is no reason that a live audio stream cannot be used as a tool for remote real time analysis. Nuclear fuel has its own unique molecular magnetic field signature. A recorded or real time audio feed of an area that contains this material will also reveal the presence of this molecular material in the electromagnetic field generated by the electrical audio coil.

President Mahmoud Ahmadinejad at nuclear fuel rod presentation 2-15-2012 from video released by Iran.

I have matched the molecular magnetic field of the nuclear fuel rod (non weapons-grade) from the short video segment at the presentation to President Mahmoud Ahmadinejad. The area-specific audio is at the beginning of the video. It is the actual audio recorded at the facility which is key to replicating the field. Monitoring for the presence of weapons-grade U-235 can be performed in the same manner.

Iranian Nuclear Fuel Rod as mp3 audio file

Twitt

Weapons Grade Uranium 235 – Passive detection of its molecular magnetic frequency

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Enriched Uranium 235 by wikipedia

There may be another method for nuclear weapons inspectors and other government agencies to remotely monitor for the presence of enriched uranium used in nuclear devices. It is my view that one day soon, scientists will recognize the fact that recorded audio captures area-specific weak magnetic fields. The reason is, it is capturing the background, underlying sound of the atoms vibrating in that area. They are vibrating in a unique way according to how the molecular structures are aligned. In the case of an audio recording, it is the aggregate field that is being captured. The recording when played back not only makes the audible mechanical sounds that we all know about, but also the electromagnetic field emanating from the electrical coil in your speaker is replicating the area-specific weak magnetic field. This replicated field can be matched and/or the frequency signature of uranium-235 can be detected in this field.

This is possible because of a particular pattern recognition ability I have with weak electromagnetic fields. It is a similar process to that of developing the skill of human echolocation but in this case it is the skill of interpreting weak electromagnetic fields and their physiological effect on the body. Eventually researchers will develop the tools to validate what I am sharing with you today.

Audio recordings or live audio feeds offer detailed information about area-specific weak molecular fields that can be analyzed by devices tuned into this information. The electromagnetic field from the audio coil in your speaker is replicating this weak field that is frozen in time as an archived audio recording, but there is no reason that a live audio stream cannot be used as a tool for remote real time analysis. Uranium-235 has its own unique molecular magnetic field signature. A recorded or real time audio feed of an area that contains this material will also reveal the presence of uranium-235 in the electromagnetic field generated by the electrical audio coil.

This same dynamic also applies to people carrying this material. A novel way to screen for weapons grade uranium at port terminals and other check points is through real time monitoring by audio. The key to detection is not in the mechanical sound waves, but in the electromagnetic field generated by the electrical coil that is upstream of the sound making process. One only needs the audio signal, an electrical coil and the frequency signature of uranium-235 to detect in the field.

Twitt

Screening for Explosives Passively- Detecting their molecular magnetic field frequency

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One day in the not too distant future, scientists will acknowledge that the weak magnetic field of molecular structures can be replicated either directly by hand or indirectly via sound recordings. I have written numerous articles at this site on how this can be accomplished and have given examples that can be explored and analyzed. Biological systems can be matched in the same way. This is possible because of a particular pattern recognition ability I have with weak electromagnetic fields. It is a similar process to that of developing the skill of human echolocation but in this case it is the skill of interpreting weak electromagnetic fields and their physiological effect on the body. Eventually researchers will develop the tools to validate what I am sharing with you today.

There is a treasure trove of information that can be gleaned from audio recordings that offers detailed information about area-specific weak molecular fields that can be analyzed by devices tuned into this information. The electromagnetic field from the audio coil in your speaker is replicating this weak field that is frozen in time as an archived audio recording, but there is no reason that a live audio stream cannot be used as a tool for remote real time analysis.

Recorded audio captures area-specific weak magnetic fields in nature. The reason is, it is capturing the background- underlying sound of the atoms vibrating in that area. They are vibrating in a unique way according to how the molecular structures are aligned. In the case of an audio recording, it is the aggregate field that is being captured. The recording when played back not only makes the audible mechanical sounds that we all know about, but also the electromagnetic field emanating from the electrical coil in your speaker is replicating the area specific-weak magnetic field. This replicated field can be extracted and matched. I do it manually.

Airport Screening by wikipedia

Explosives have their own unique molecular magnetic field signature. A recorded or real time audio feed of an area that contains explosives will also reveal the presence of the explosive material in the electromagnetic field generated by the electrical audio coil. This same dynamic also applies to people carrying or wearing explosives. A novel way to screen for explosives at terminals and other check points is through real time monitoring of voice signatures, but the key to detection is not in the mechanical sound waves, but in the electromagnetic field generated by the electrical coil that is upstream of the sound making process. One only needs the audio signal, an electrical coil and the frequency signature of the explosive to detect in the field.

Twitt