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June 25, 2026- by Steven Greer

In the fractured battlefields of Venezuela, where U.S.-led forces press an incomplete invasion amid a collapsing government and streets thick with chaos, two powerful magnitude 7 earthquakes hammered the region last night. The twin shocks reduced entire city blocks of towering buildings to rubble and left what officials fear could be hundreds of thousands dead or missing in the rubble. The disasters struck at a moment of global peril. Iranian-backed forces, acting as surrogates for China and Russia, appear to be routing Israeli and American positions across the Middle East. These seismic events have only deepened the sense of a world tipping into uncontrolled turmoil.

Seismologists note that Venezuela does not sit on the kind of hyperactive plate boundary that defines California or the Pacific Ring of Fire. The country lies in a more stable intraplate zone where large earthquakes are uncommon. The last significant major event dates back to the 1967 Caracas quake, which caused widespread damage but was far less destructive than what unfolded overnight. Against this backdrop, whispers are already spreading about whether human hands could have played a role in the timing and power of the strikes.

Military analysts have long studied ways to influence seismic activity. The most straightforward method remains underground nuclear explosions. These can produce seismic signatures akin to moderate or larger quakes while leaving localized devastation that might blend into the fog of war.

One line of more sophisticated research traces back to Cold War-era Soviet programs code-named Mercury and Volcano. These reportedly explored remote electromagnetic manipulation to trigger faults. Alleged tests were conducted in Kyrgyzstan during the late 1980s and early 1990s. The aim was setting off distant earthquakes through targeted energy waves.

Building on similar principles, physicist Bernard Eastlund’s 1980s patents described using high-frequency radio transmitters to heat and modify the upper atmosphere. In theoretical extensions, such systems could turn the ionosphere into a vast steerable giant antenna. This would generate extremely low frequency ELF waves capable of propagating through the Earth’s crust. The waves could create standing waves or resonant frequencies that match natural fault-line vibrations. This might induce piezoelectric effects in stressed rocks or amplify subtle pressures to release tectonic strain.

Radio-frequency arrays represent another avenue discussed in these concepts. These could deliver rhythmic impulses deep underground. They function much like industrial seismic vibrators used in oil exploration but scaled for precision targeting. Modulated energy beams from such arrays could potentially synchronize with crustal resonances.

Fluid injection techniques offer yet another documented pathway. This involves pumping vast volumes of liquid into boreholes to lubricate faults. The method has already triggered smaller quakes in energy-producing regions. It could be adapted for covert operations in a conflict zone.

While these technologies originated in scientific and industrial contexts, their potential weaponization in dicey conflict zones like Venezuela raises sobering questions. The invisible hands shaping not just battles but the very ground beneath them remain a source of speculation amid the unfolding crisis.

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This is how HAARP can cause earthquakes.

By Grok and Greer:

HAARP is a large research facility in Alaska featuring an array of powerful radio antennas spread across an area roughly the size of about 30 football fields, all pointing upward. It transmits high-frequency (HF) radio waves straight into the sky to heat a small patch of the ionosphere — the electrically charged upper layer of the atmosphere that begins roughly 50–60 miles (about 80–100 km) above the ground.

By rapidly turning this heating on and off or varying its strength (a process called modulation), the facility disturbs the natural electric currents already flowing in the ionosphere. This disturbance “translates” the original high-frequency energy into much lower-frequency electromagnetic waves known as ELF and VLF (Extremely Low Frequency and Very Low Frequency).

These longer-wavelength waves are then able to propagate efficiently downward and sideways through the natural “pipe” or waveguide formed between the Earth’s surface and the ionosphere.

Because these low-frequency waves can travel long distances and penetrate seawater and soil better than ordinary radio signals, they have well-known military applications:

A) They are used to send simple one-way messages to deeply submerged submarines (which can receive them without surfacing) and

B) have been explored for detecting or communicating with underground or buried targets.

C) The more speculative theory about triggering earthquakes builds on the same low-frequency capability.

According to researchers who wrote an open letter on the topic, tectonic fault lines under stress are already vibrating and naturally emitting their own weak electromagnetic signals at specific low frequencies as tiny cracks begin to form in the rock.

If an external source (such as HAARP-style heating) generates matching low-frequency waves and those waves reach the fault through the Earth-ionosphere waveguide, they can add energy to the fault’s natural vibration through a process called resonance.

This is similar to how a singer can shatter a crystal glass by singing a sustained note at exactly the right frequency — the glass absorbs the sound energy and vibrates until it breaks — or how striking one tuning fork causes an identical nearby tuning fork to start vibrating on its own without being touched.

In the earthquake scenario, the added resonant energy from the external waves is said to push an already critically stressed fault past its breaking point, causing it to slip suddenly and release a quake.

The idea is that the fault acts like a resonant system that can absorb and amplify energy at its natural frequency, turning a small external push into a large geological effect.