The Observable Force of Electromagnetism

A prevalent argument against flat Earth theories is the question of how gravity operates in such a model. The reality is that objects do not fall because of gravity. Gravity serves merely as an explanation for downward acceleration. What can be validated, however, is electromagnetism, which we know to be an electric phenomenon influencing all matter.

Through electrostatics, we can alter an object's weight and its rate of descent. Scientific methods can demonstrate that electrostatics can influence the weight and movement of objects. In contrast, no experiment exists that can isolate gravity to prove its effects.

Consider dropping a denser object in the air. It descends. Now introduce electrostatics using a Van de Graaff generator, and you can make the object levitate or ascend. This illustrates the manipulable nature of electrostatics: it allows for control over an object's movement and weight.

Electromagnetism in Nature

Spiders that "balloon" do so not because their silk generates lift through traditional means, but because they harness atmospheric electricity. Research from the University of Bristol indicates that these spiders can soar to altitudes of 5 kilometers, traveling vast distances.

Observations reveal that spiders can balloon even in minimal wind or rain, challenging the wind hypothesis. The key lies in the difference in electric charge between the ground and the sky, which creates an electric field. When a spider's silk acquires static charge, the electric field can push the silk upwards, potentially launching the spider into the air.

Experiments in controlled environments showed that spiders could spin silk and achieve flight even without wind when subjected to varying electric fields. This suggests that spiders can ascend or descend simply by manipulating the electric field around them.

The researchers noted that spiders tested environmental conditions with their legs before spinning silk and that the hairs on their legs reacted to electric field changes. These spiders are not resisting the concepts of space-time but rather utilizing the electromagnetic properties of their environment for navigation.

The Role of Electromagnetism in Animal Navigation Many animals possess magnetoreception, the ability to sense the Earth's magnetic field. Birds, such as pigeons, have magnetite crystals in their beaks, enabling them to navigate the skies by detecting magnetic fluctuations. Other species, including sea turtles and sharks, utilize the magnetic field to guide their migrations and return to specific locations.

Even terrestrial animals like moles rely on magnetic fields to orient themselves while excavating underground tunnels. Honey bees, too, depend on the Earth's magnetic field to return to their hives. Numerous experiments have confirmed the presence and significance of electromagnetism in nature.

The Electric Nature of Existence

Electromagnetism serves as a fundamental force that unites all matter. Everything strives for equilibrium based on this electric force. On a smaller scale, electrostatic forces are significantly stronger than the claims surrounding gravity, with magnitudes potentially up to 10^(-36) times greater. Every object's behavior, whether it falls or remains suspended, results from its quest for electrostatic balance.

Using a Corona motor, one can demonstrate that manipulating electrostatics can lead to levitation and control over an object's descent speed. In contrast, no experiments have been conducted to manipulate space-time.

When an object falls, it seeks equilibrium, finding balance where charge disperses through the ground. The atmosphere is positively charged while the Earth's surface holds a negative charge. This is why walking barefoot on grass is often termed "grounding."

By introducing positive charge, we can observe how objects return to the ground, emphasizing that falling relates to a search for balance.

Historical Insights into Electromagnetism

Visionaries like Nikola Tesla and the ancient Egyptians recognized that the atmosphere is a vast source of electricity. Many people are unaware that the pyramids were designed to capture this electric energy, strategically placed for optimal absorption. These structures served as energy conductors, a concept grasped by both ancient civilizations and Tesla, yet largely ignored today.

Tesla's vision for harnessing free energy was dismissed, as it posed challenges for profit-driven enterprises. All matter is inherently electrostatic; even in a vacuum, electrostatic forces are present. The Earth's surface carries a negative charge while the sky holds a positive charge.

Unlike gravity, electromagnetism is both predictable and reliably measurable. We rely on faith that gravity operates as described because we are told the mathematical models work on a cosmic scale, yet we lack access to these celestial bodies for verification. Critics of flat Earth theories are often labeled as anti-science for questioning these assumptions.

Do the mathematical models accurately reflect gravity's existence, or are they constructed to fit within the scientific framework? This raises concerns about potential biases in scientific methodologies.

Experts assert that they possess technology to validate their findings, claiming to have explored distant celestial realms. Ironically, these are the same experts who claim to have reached the moon yet purportedly destroyed the technology needed to return.

Ultimately, gravity remains unproven, while the principles of electrostatics have been substantiated through rigorous scientific inquiry.