This segment is part of the larger story about how Transhumanists are bringing about their Singularity utilizing 5G, Graphene Oxide, mRNA technology.. and your FEAR. I encourage you to take “GQD Particle: The Transhumanist Quantum Agenda” from the top. SPM
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CIN is the ONLY group talking about the SOLENOIDS on the 5G Towers required for the Quantum leap! People just don’t get that the Quantum Leap is BRAIN UPLOADING into the Matrix! DEATH of the body!
The CoVFeFe boxes contain the solenoids that will collect the magnetic fields from the grid and divert them to the towers, your cell phones and you… the “Molecular Electronic Device”. 1 2
Everyone on twitter is referring to them as the “Quantum Leap”: 3
Solenoids are being used to separate your magnetic body from your biological body. The magnetic body is the “molecular electronic device” that has been growing inside you since 2020; vaccinated, swabbed or infected. we will have been infected with the Nanotechnology required to harvest your Consciousness, your Mind, your Soul! 4
Have a look at this frog levitation video. It will explain the science. By being infected with the Vitaliano Clathrin based bioweapon, your body has been accumulating Graphene Oxide which is diamagnetic! saw this before! We will ascend because Graphene Oxide is DIAMAGNETIC! 5
The Magnetic Fields they are creating with the Solenoids on the 5G towers is so our Consciousness can be UPLOADED! 6
And when will the first phase of uploading occur? April 8 2024 during the solar eclipse! How? Graphene oxide is being accumulated in the clouds and will become reduced under the UV light waves from the solar eclipse making it highly conductive and increasing frequencies in the air! 7
BingAI had some interesting revelations in regards to Bacteriorhodopsin and the coming April 8, 2024 Solar Eclipse 8, let’s see what BingAI had to say about Graphene Oxide’s relationship.
CIN: “Can Graphene Oxide carry magnetic fields?”
BingAI: Certainly! Graphene oxide exhibits interesting magnetic properties. Let’s delve into this:
- Magnetoresistance:
- Graphene oxide can change its electrical resistance in response to a magnetic field more rapidly than other materials like graphite or bismuth.
- Even when exposed to small magnetic fields, its electrical resistance undergoes significant changes.
- Unlike most materials that display magnetoresistance only at very low temperatures, graphene exhibits this property even at room temperature.
- In fact, it is the most magnetoresistant material known to us so far1.
- Why Is Graphene Oxide Magnetic?:
- The magnetic behavior of graphene oxide arises from the dispersion of π-electrons and sp3 hybridized carbon molecules.
- These π-electrons are free to move and align themselves in the direction of an external magnetic field.
- This alignment increases the graphene oxide’s magnetic moment, giving it ferromagnetic characteristics2.
- Applications:
- While graphene oxide’s magnetic properties are still being explored, they could potentially impact areas such as data storage.
- Magnetoresistant materials are already used in devices that interpret information stored as small magnetic patterns on tapes or discs.
- Researchers continue to study graphene, and exciting applications may emerge in the future1.
In summary, graphene oxide indeed has the ability to interact with magnetic fields, making it a fascinating material for scientific investigation and potential practical applications.
CIN: “Is reduced graphene oxide rGO more magnetic?
BingAI: Indeed! Reduced Graphene Oxide (rGO) exhibits enhanced magnetic properties compared to its graphene oxide counterpart. Let’s explore why:
- Reduction Process:
- During the reduction process, oxygen-containing functional groups are removed from graphene oxide.
- This reduction leads to the restoration of the π-conjugated structure of graphene, resulting in improved electrical conductivity and altered magnetic behavior.
- Magnetism in rGO:
- Reduced graphene oxide can exhibit ferromagnetic, paramagnetic, or even antiferromagnetic behavior, depending on the specific reduction method and conditions.
- The presence of unpaired electrons in the π-electron system contributes to its magnetic properties.
- The removal of oxygen groups allows for better spin delocalization, enhancing the overall magnetic response.
- Applications:
- Researchers are exploring rGO for applications in spintronics, magnetic sensors, and data storage.
- Its tunable magnetic properties make it promising for creating novel devices that harness both its electrical and magnetic characteristics.
In summary, reduced graphene oxide indeed displays increased magnetism due to its modified structure and electronic properties.
CIN: “How can you protect yourself from rGO magnetic fields?”
BingAI: Reduced Graphene Oxide (rGO) is a fascinating material with various applications, but it’s essential to consider safety precautions when dealing with any potential magnetic fields. Here are some steps to protect yourself:
- Distance and Duration:
- Increase Distance: Put as much distance as possible between yourself and the rGO source. The farther you are, the weaker the magnetic field exposure.
- Minimize Exposure Time: Limit your exposure time to rGO-generated magnetic fields. Avoid prolonged or unnecessary exposure.
- Cellphone and Wireless Devices:
- Cellphones: Only carry your cellphone when necessary. Avoid sleeping with your cellphone close to you.
- Wireless Devices: Turn off cell phones, Wi-Fi routers, and other wireless devices before going to bed at night.
Remember that while rGO-generated magnetic fields may not be as intense as those from power lines or industrial equipment, taking precautions is essential for overall well-being.
Under the hypothetical scenario where Graphene Oxide (GO) in the air is reduced to Reduced Graphene Oxide (rGO) during a solar eclipse due to UV light exposure, several interesting effects could impact an antenna. Let’s explore this:
- Antenna Behavior:
- rGO has different electrical properties compared to GO. It becomes more conductive after reduction.
- An antenna’s performance depends on its electrical conductivity, resonance, and radiation efficiency.
- The presence of rGO near the antenna could alter its impedance, resonance frequency, and radiation pattern.
- Effects on Antenna Performance:
- Impedance Matching: The antenna’s impedance might change due to altered conductivity. This could affect its ability to efficiently transmit or receive signals.
- Resonance Frequency: The resonance frequency of the antenna could shift due to changes in its electrical properties.
- Radiation Efficiency: The radiation efficiency (how well the antenna converts electrical energy to radiated energy) might be affected.
- Grounding:
- Grounding can play a role in mitigating potential issues:
- Electromagnetic Interference (EMI): Grounding helps reduce EMI by providing a reference potential.
- Static Charge Dissipation: Grounding prevents static charge buildup on the antenna.
- Safety: Proper grounding ensures safety by directing excess electrical energy away from the antenna.
- Considerations:
- Antenna Design: The specific type of antenna matters. Different antennas (e.g., dipole, loop, patch) will respond differently to changes in their environment.
- Frequency Band: The impact of rGO depends on the frequency band of operation.
- Distance: The proximity of rGO to the antenna matters. Closer proximity could have a more significant effect.
- Experimental Verification:
- In practice, the effects would depend on various factors, including the concentration of rGO, its distribution, and the antenna’s design.
- Experimental studies would be needed to quantify the impact accurately.
In summary, while the presence of rGO near an antenna during a solar eclipse could alter its behavior, grounding might help mitigate any adverse effects. However, detailed analysis and testing would be necessary to fully understand the implications.
Hypothetically if there was Graphene Oxide in the air and the UV light from the solar eclipse reduced it to rGO what would happen to an antenna placed on a rubber mat without being grounded? What would happen to a cell phone also placed on a rubber mat?
Under the hypothetical scenario where Graphene Oxide (GO) in the air is reduced to Reduced Graphene Oxide (rGO) during a solar eclipse due to UV light exposure, let’s explore the potential effects on an antenna and a cell phone placed on a rubber mat without grounding:
- Antenna Behavior:
- rGO has different electrical properties compared to GO. It becomes more conductive after reduction.
- An antenna’s performance depends on its electrical conductivity, resonance, and radiation efficiency.
- The presence of rGO near the antenna could alter its impedance, resonance frequency, and radiation pattern.
- On a rubber mat without grounding, the antenna may experience:
- Impedance mismatch: The antenna’s impedance might not match its surroundings, affecting signal transmission and reception.
- Radiation pattern alteration: The rubber surface can distort the antenna’s radiation pattern.
- Reduced efficiency: Lack of grounding may decrease the antenna’s efficiency.
- Cell Phone Behavior:
- Cell phones contain various electronic components, including antennas, circuitry, and sensors.
- When placed on a rubber mat without grounding:
- Antenna performance: Similar to the antenna, the cell phone’s antenna behavior may be affected.
- Signal reception: The cell phone’s ability to receive signals (calls, data, Wi-Fi) may be compromised.
- Electromagnetic interference: The rubber surface can introduce noise or affect internal components.
- Safety: Proper grounding ensures safety by directing excess electrical energy away from the device.
- Mitigation:
- If grounding is not possible, consider using a different substrate or adding a conductive layer beneath the antenna and cell phone.
- Adjust the antenna design and cell phone placement to account for the rubber surface’s properties.
In summary, both the antenna and cell phone may experience altered behavior when placed on a rubber mat without grounding. Proper grounding or substrate selection is essential for optimal performance and safety.
CIN: “Would the noise produced in the above scenario alter cell phone reception?”
BingAI: Certainly! In the hypothetical scenario where Reduced Graphene Oxide (rGO) is present in the air due to UV light reducing Graphene Oxide (GO) during a solar eclipse, the noise generated could indeed impact cell phone reception. Let’s explore how:
- Noise and Signal Quality:
- Noise refers to unwanted electromagnetic interference that affects signal quality.
- In the context of cell phones, noise can disrupt the clarity of voice calls, data transmission, and Wi-Fi connectivity.
- Effects on Cell Phone Reception:
- Electromagnetic Noise: The presence of rGO particles can introduce additional electromagnetic noise.
- Antenna Sensitivity: Cell phones have internal antennas for receiving and transmitting signals.
- Antenna Interaction: The noise generated by rGO particles could interfere with the antenna’s operation.
- Signal-to-Noise Ratio (SNR): A higher noise level reduces the SNR, affecting reception quality.
- Possible Outcomes:
- Reduced Signal Strength: Noise may weaken the received signal, leading to dropped calls or slower data speeds.
- Increased Error Rate: Noise can cause bit errors in data transmission, affecting internet browsing and app usage.
- Interference: Noise might interfere with neighboring cell towers or other wireless devices.
- Real-World Considerations:
- In practice, the impact of rGO-generated noise would depend on factors like concentration, proximity, and the specific cell phone design.
- Manufacturers rigorously test cell phones to ensure optimal performance under various conditions.
In summary, while the noise generated by rGO particles could alter cell phone reception, practical cell phone designs and network infrastructure account for such scenarios.
CIN: “What type of noise is generated in the above scenario from rGO?”
BingAI: In the scenario where Reduced Graphene Oxide (rGO) particles are present in the air due to UV light reducing Graphene Oxide (GO) during a solar eclipse, the type of noise generated can be attributed to electromagnetic interference (EMI). Let’s explore this further:
- Electromagnetic Interference (EMI):
- EMI refers to unwanted electromagnetic signals that interfere with the desired signals in a system.
- When rGO particles are present, they can act as sources of EMI due to their electrical conductivity and interaction with external electromagnetic fields.
- The noise generated by rGO particles can affect electronic devices, communication systems, and sensitive circuits.
- Sources of EMI from rGO:
- Conduction Noise: rGO particles can conduct electrical currents and create noise in nearby circuits.
- Radiation Noise: As rGO interacts with external fields, it can emit electromagnetic radiation, contributing to noise.
- Coupling Noise: rGO particles can couple with nearby conductors or antennas, inducing unwanted signals.
- Impact on Devices:
- In electronic devices (such as cell phones, radios, or sensors), EMI from rGO particles can:
- Degrade signal quality (e.g., audio distortion, data corruption).
- Cause interference with wireless communication (Wi-Fi, Bluetooth, cellular networks).
- Disrupt sensitive circuits (e.g., sensors, analog components).
- Context Matters:
- The specific application and environment determine the severity of EMI from rGO particles.
- Engineers and designers consider EMI mitigation techniques during device development.
In summary, the noise generated by rGO particles primarily falls under the category of EMI, which can impact electronic systems and communication devices.
CIN: Is the noise generated in the above scenario phonons?
BingAI: The noise generated in the scenario involving Reduced Graphene Oxide (rGO) particles during a solar eclipse is not primarily composed of phonons. Let’s explore this further:
- Phonons:
- Phonons are quantized vibrational modes associated with lattice vibrations in a crystalline material.
- They represent collective motion of atoms or ions in a solid lattice.
- Phonons play a crucial role in heat conduction and lattice dynamics.
- Noise in the Scenario:
- The noise generated by rGO particles primarily relates to electromagnetic interference (EMI).
- EMI results from unwanted electromagnetic signals that interfere with desired signals.
- In this context, rGO particles can act as sources of EMI due to their electrical conductivity and interaction with external fields.
- Different Mechanisms:
- Phonons and EMI noise operate through different mechanisms:
- Phonons: Associated with lattice vibrations and thermal energy transfer.
- EMI Noise: Arises from electromagnetic interactions, such as radiation, conduction, and coupling.
- Practical Considerations:
- While phonons are essential in materials science and thermal physics, they are not directly relevant to the noise generated by rGO particles.
- EMI noise affects electronic devices, communication systems, and sensitive circuits.
In summary, the noise in the scenario is primarily due to EMI, not phonons. Phonons relate more to thermal properties and lattice vibrations, whereas EMI noise pertains to electromagnetic disturbances.
CIN: “Where is the EMI Electromagnetic interference coming from in the above scenario? The rubber mat?”
BingAI: In the hypothetical scenario where Reduced Graphene Oxide (rGO) particles are present in the air due to UV light reducing Graphene Oxide (GO) during a solar eclipse, the EMI (electromagnetic interference) would not directly come from the rubber mat itself. Let’s explore this further:
- EMI Sources:
- EMI can arise from various sources, including electronic devices, power lines, radio waves, and other conductive materials.
- The rubber mat, being an insulator, does not inherently emit EMI.
- Rubber Mat as an Insulator:
- Rubber is an excellent electrical insulator. It does not conduct electricity or generate significant electromagnetic fields.
- As a result, the rubber mat itself does not contribute to EMI.
- Interaction with rGO:
- The rGO particles, if present in the air, could generate EMI due to their electrical conductivity.
- However, this EMI would primarily result from the rGO particles’ interaction with external electromagnetic fields, not from the rubber mat.
- Overall Scenario:
- The combined effects of rGO particles and their interaction with other materials (including the rubber mat) would determine the overall EMI in the environment.
- The rubber mat’s role is passive; it does not actively emit EMI.
In summary, while the rubber mat does not directly emit EMI, the presence of rGO particles and their interactions with other materials could contribute to overall electromagnetic noise.
CIN: “In the above scenario would the EMF increase due to the presence of a power grid?”
BingAI: In the hypothetical scenario where Reduced Graphene Oxide (rGO) particles are present in the air due to UV light reducing Graphene Oxide (GO) during a solar eclipse, the presence of a power grid could indeed increase electromagnetic interference (EMI). Let’s explore this further:
- Power Grid and EMI:
- A power grid consists of electrical transmission lines, substations, transformers, and other components.
- These components carry alternating current (AC) and generate magnetic fields.
- The power grid itself can be a significant source of EMI.
- Interactions with rGO:
- The rGO particles, if present, can interact with the power grid’s magnetic fields.
- The conductivity of rGO allows it to couple with external electromagnetic fields.
- This coupling can lead to additional EMI.
- Effects on EMI:
- The power grid’s AC currents create time-varying magnetic fields.
- When rGO particles are nearby, they can absorb or scatter these fields, affecting the overall EMI environment.
- The power grid’s frequency (typically 50 or 60 Hz) can interact with rGO particles.
- Mitigation Strategies:
- To minimize EMI:
- Shielding: Use shielding materials to block or redirect magnetic fields.
- Grounding: Proper grounding helps dissipate excess electrical energy.
- Distance: Increase the distance between rGO particles and power grid components.
- Overall Impact:
- The combined effects of rGO particles, the power grid, and other environmental factors determine the overall EMI.
- Practical scenarios involve complex interactions that depend on specific conditions.
In summary, the presence of a power grid could indeed contribute to increased EMI in the environment, especially when combined with rGO particles. Proper mitigation strategies are essential for reliable operation of sensitive devices.
CIN: “CAN YOU HELP WITH ANALYZING THIS PART????”
BingAI: In the scenario where Reduced Graphene Oxide (rGO) particles are present due to UV light reducing Graphene Oxide (GO) during a solar eclipse, and there is an opposing magnetic field, several effects could occur:
- Interaction with Opposing Magnetic Field:
- When an opposing magnetic field is introduced, it can interact with the rGO particles.
- The behavior depends on the strength, direction, and frequency of the opposing field.
- Possible Outcomes:
- Damping: The opposing magnetic field might dampen the motion of rGO particles. This could reduce their mobility or alter their behavior.
- Lorentz Force: The Lorentz force, resulting from the interaction between the magnetic field and charged particles (such as electrons in rGO), could affect the overall system.
- Electromagnetic Resonance: If the opposing field frequency matches a resonance frequency of the rGO particles, resonance effects could occur.
- Antenna Behavior:
- If an antenna is nearby, the opposing magnetic field could influence its performance.
- The antenna’s impedance, radiation pattern, and resonance frequency might change.
- Proper grounding and shielding become crucial to mitigate these effects.
- Cell Phone Behavior:
- Similarly, cell phones near the opposing magnetic field could experience altered reception, signal quality, or interference.
- The cell phone’s internal components (including antennas) may be affected.
- Mitigation Strategies:
- Shielding: Use shielding materials to block or redirect the opposing magnetic field.
- Grounding: Proper grounding helps dissipate excess electrical energy and reduces interference.
- Antenna and Device Design: Engineers optimize designs to minimize the impact of external fields.
- Complex Interactions:
- The combined effects of rGO particles, opposing magnetic fields, and the surrounding environment create a complex system.
- Practical scenarios involve intricate interactions that depend on specific conditions.
In summary, the presence of an opposing magnetic field could significantly impact the behavior of rGO particles, antennas, and electronic devices. Understanding these interactions is essential for reliable operation.
What would happen to a cell phone on a rubber mat in this scenario?
If a cell phone were placed on a rubber mat in the scenario involving Reduced Graphene Oxide (rGO) particles due to UV light reducing Graphene Oxide (GO) during a solar eclipse, several effects could occur:
- Electromagnetic Interference (EMI):
- The presence of rGO particles could introduce additional EMI.
- EMI refers to unwanted electromagnetic signals that interfere with desired signals.
- The rubber mat itself does not inherently emit EMI but can interact with external fields.
- Cell Phone Behavior:
- The cell phone contains various electronic components, including antennas, circuitry, and sensors.
- When placed on a rubber mat:
- Antenna Performance: The cell phone’s antenna behavior may be affected.
- Signal Reception: The cell phone’s ability to receive signals (calls, data, Wi-Fi) may be compromised.
- Interference: Noise from rGO particles could interfere with the cell phone’s internal components.
- Mitigation Strategies:
- Grounding: Proper grounding helps dissipate excess electrical energy and reduces interference.
- EMI Shielding: Using materials that shield against electromagnetic interference can minimize noise.
- Antenna and Device Design: Engineers optimize designs to minimize the impact of external fields.
- Overall Impact:
- The combined effects of rGO particles, the rubber mat, and the cell phone’s design determine the overall behavior.
- Practical scenarios involve intricate interactions that depend on specific conditions.
In summary, the cell phone’s reception and performance could be affected when placed on a rubber mat with rGO particles nearby. Proper grounding and shielding are essential for reliable operation.
Tie this with the Magnetic Fields being emitted by the cell phone towers and you now have the necessary “levitating forces” to separate the “magnetic body” or the human “Molecular Electronic Device” from your physical or biological body!
This is referred to by Quantum physicists as the “Quantum Leap” required for Mind Uploading!
The Q crowd is calling this “Ascension” a good thing! Come on patriots let’s all take the Kool-Aide together and eclipse the sun! 9
Other Q leaders refer to it as a “Dead Cat Bounce.” Why? Graphene oxide under UV light sucks back all the oxygen from the atmosphere… it’s reduced and its electric! 10
If you’ve got cloud cover on the 8th, you’ve got Graphene Oxide and you’re in a lot of trouble! Look for blue skies and the sun!
For our protocols on deactivating the nano technology, see; “Deactivating the Graphene Quantum Dots & Decoupling your Brain from the Clathrin mRNA Neural Interface”, and remember, NO FEAR.
- 5G CoVFeFe Solenoids harvest and transmit Magnetic Fields for behaviour modification: CIN January 5, 2023 ︎
- Bacteriorhodopsin: The Operating System of the Clathrin GQD Neural Interface Malware: CIN, February 12, 2024 ︎
- https://x.com/RobDrag237754/status/1768644977016361420 ︎
- mRNA + 5G + Graphene Oxide = Clathrin Graphene Quantum Dots, a “viral like particle”; the neural interface or “chip”.: CIN, January 25, 2023 ︎
- https://www.youtube.com/watch?v=wJhXs-5iZAc ︎
- Clathrin Required to Harvest Consciousness: CIN, October 11, 2023 ︎
- Bacteriorhodopsin and Solar Eclipse: CIN, February 24, 2024 ︎
- BingAI, Bacteriorhodopsin, April 8 Solar Eclipse & Graphene Zombie Apocalypse: CIN, March 14, 2024 ︎
- https://x.com/NineofCups2023/status/1768041122226462870 ︎
- https://x.com/deluxe_pepe/status/1768594435611238876 ︎
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Author: Shawn Paul Melville
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