Harvard Professor claims aliens likely travelled to Earth through ‘curled dimensions’

Harvard professor Avi Loeb, known for investigating aliens claims that aliens are likely present 300 feet below Earth’s surface, created by CERN’s particle accelerator.

The accelerator, The Large Hardon Collider (LHC), blasts particles at the speed of light to recreate a situation like the Big Bang, hoping to find hidden dimensions that would further reveal the universe’s existence.

CERN recently launched high-energy proton collisions at its Large Hadron Collider (LHC), replicating conditions reminiscent of the Big Bang. This 17-mile-long particle accelerator, nestled underground between France and Switzerland and operating at near-light speeds, aims to uncover elusive particles dictating the universe’s behavior.

Arnaud Marsollier, CERN’s media head, looks forward to delving into resulting data to enhance comprehension of phenomena such as the Higgs boson and dark matter.

The LHC’s thorough restart process culminated in Friday’s groundbreaking collision, breaking previous energy thresholds. Despite the minuscule size of particles involved, the energy released is monumental.

Originally slated during a solar eclipse, the experiment advanced to generate stable beams, marking a crucial milestone.

Engineers meticulously fine-tune the beam’s trajectory to optimize collision probability, vital for experimental success. This pursuit transcends particle physics; it aims to unravel the universe’s fundamental mysteries.

The validation of Professor Higgs’ 1964 Higgs field theory through these experiments is noteworthy. Although particles swiftly decay post-collision, their ephemeral existence leaves invaluable data traces. This ongoing endeavour holds promise for profound insights into the universe’s inception and constitution, solidifying CERN’s stature as a vanguard of scientific exploration.

About Large Hardon Collider (LHC)

The Large Hadron Collider (LHC), operational since 2010, accelerates protons close to light speed, causing collisions at four points.

Detectors analyze resultant particles, aiding global physicists in understanding natural laws. While the LHC manages 1 billion proton-proton collisions per second, the upcoming HL-LHC will boost this “luminosity” by five to seven times, amplifying data collection tenfold from 2026 to 2036.

This enhancement enables scrutiny of rare phenomena and precise measurements. Notably, the LHC’s 2012 discovery of the Higgs boson significantly advanced comprehension of mass acquisition by particles.

In another experiment, scientists role-played Earth as a distant alien world to search for alien life.

A team of physicists led by Sascha Quanz from the University of Zurich conducted a pioneering experiment within the LIFE project, treating Earth as though it were a distant exoplanet.

This initiative seeks to explore the possibility of extraterrestrial life beyond our solar system.

Utilizing authentic Earth data, the team simulated observations similar to those that the Large Interferometer For Exoplanets (LIFE) mission would conduct, aiming to identify potential signs of life on remote worlds. Their analysis unveiled interesting signs pointing to Earth’s suitability for life.

By scrutinizing Earth’s atmosphere through the lens of an exoplanet, they identified critical biosignatures like oxygen and methane, essential for supporting life as we recognise it. These findings validate the potential of the LIFE project to investigate Earth-like exoplanets for signs of life.

Scheduled for deployment shortly, the LIFE mission will employ a network of satellites to observe exoplanets from a position close to the James Webb Space Telescope.

This collaboration will bolster the capacity to study distant worlds and evaluate their habitability potential. Quanz and his team’s research underscores the profound significance of exploring life beyond our solar system.