Scientific Experiments & Observations

Don’t just take our word for it—test it for yourself! This section covers simple but effective experiments you can conduct to verify Flat Earth concepts. From laser tests over water to gyroscope and pendulum experiments, these hands-on investigations allow you to challenge mainstream claims with real-world observations.

Moonlight Experiment

Moonlight is strange—it behaves differently than sunlight. Unlike the Sun, which provides heat, the Moon’s light appears to have a cooling effect. To test this, place a thermometer in direct moonlight and another in the moon’s shadow. You’ll find that objects exposed to moonlight tend to be colder than those in the shade. This contradicts the idea that the Moon simply reflects sunlight and suggests that moonlight may have properties we are not being told about.

Water Surface Level Test

One of the simplest ways to test the shape of the Earth is by examining large bodies of water. If the Earth were a globe, standing water should curve according to the accepted calculations of Earth’s circumference (8 inches per mile squared). Using a high-zoom camera, laser tests, or a telescope over a long, flat body of water, you can observe that there is no measurable curvature—the water remains flat as far as the eye can see.

Long-Distance Visibility Test

According to the globe model, objects should begin disappearing beyond the horizon at a certain distance due to the curvature of the Earth. However, with modern high-zoom cameras like the Nikon P1000, we can bring back into view objects that should be hidden. This phenomenon suggests that the horizon is not the curve of a sphere but instead a limit of human vision and atmospheric conditions.

Lighthouse Visibility Experiment

Many lighthouses have official visibility ranges published by organizations like Trinity House, yet their light can be seen from distances that contradict the expected curvature of a globe. By using the standard 8 inches per mile squared formula, these observations suggest that the Earth’s surface does not curve as expected.

Tourist Town Island Sightings

Coastal tourist towns often boast about islands visible on clear days from their shores. However, using official curvature calculations, many of these islands should be completely hidden below the horizon. This contradiction raises questions about the true shape of the Earth.

Airplane Spirit Level Experiment

Take a spirit level with you on a plane. If the Earth were a sphere, an airplane should constantly adjust its nose downward to compensate for curvature. Yet, over long-haul flights such as London to California, a spirit level remains steady, indicating that the aircraft is flying over a level surface rather than continuously adjusting for a curved one.

Gyroscope Experiment

A mechanical gyroscope is designed to maintain its orientation regardless of movement. If the Earth were spinning at 1,000 mph, a gyroscope should gradually drift due to this motion. However, when tested, high-precision gyroscopes remain fixed, showing no evidence of Earth’s rotation. This absence of movement challenges the claim that the Earth is constantly spinning.

Airplane Flight Path Analysis

If the Earth were a spinning globe, airplanes traveling in different directions should have to account for this motion. Pilots, however, do not make constant adjustments for curvature or rotation. Additionally, flight paths, particularly in the Southern Hemisphere, often take strange and seemingly illogical routes when plotted on a globe—but make perfect sense when laid out on a Flat Earth map.

The Vacuum Problem: Earth’s Atmosphere vs. Space

NASA claims that the Earth exists in a vacuum next to the vast emptiness of space. However, nature tells us that pressure systems require a barrier. If space is a vacuum and the Earth’s atmosphere is under pressure, why doesn’t the vacuum of space pull the atmosphere away? This contradiction in physics raises serious questions about the mainstream model.

These experiments offer hands-on ways to test the reality of the world around us. No special equipment is needed—just an open mind and a willingness to challenge assumptions.

Polaris (Pole Star) Line of Sight Experiment

Set up a fixed line of sight method pointing at the Pole Star—using a telescope, a camera, or even just a cardboard tube. Come back the next night and see that it's still there. It will be. Ask yourself: how is that possible if, between last night and tonight, your vantage point has moved due to the Earth supposedly spinning around the “universe” at the following speeds which assuming an example line of sight position in the Northern Hemisphere at the Greenwich Prime Meridian amounts to:- 45 million miles every single day

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1. Earth's Rotation at Prime Meridian Latitude (51.5° N, Greenwich)

• Speed at Equator: ~1,037.6 mph

• At 51.5° latitude:
  Use speed = equatorial speed × cos(latitude)
  → 1,037.6 × cos(51.5°) ≈ 647.2 mph

• Daily distance:
  647.2 × 24 ≈ 15,532.8 miles

☀️ 2. Earth’s Orbit Around the Sun

• Speed: ~67,000 mph

• Daily distance:
  67,000 × 24 = 1,608,000 miles

🌌 3. Sun’s Orbit Around the Centre of the Milky Way

• Speed: ~514,000 mph

• Daily distance:
  514,000 × 24 = 12,336,000 miles

🌀 4. Milky Way’s Motion Through the Universe (Local Group / Cosmic Web)

• Estimated speed: ~1.3 million mph

• Daily distance:
  1,300,000 × 24 = 31,200,000 miles

📊 5. Total Hypothetical Distance Travelled in 24 Hours

(Adding all 4 motions linearly, though directions vary)

• Total miles/day:
  15,532.8 + 1,608,000 + 12,336,000 + 31,200,000 =
  → ~45,159,533 miles

🧭 Summary

An observer standing still at Greenwich is, according to official cosmology, hurtling through space in four different directions at once, covering a combined distance of over 45 million miles every single day — and yet Polaris remains perfectly fixed in your line of sight, night after night.