Here’s a breakdown of the provided text, summarizing the key information:

main Topic: Scientists have observed a filament of the cosmic web – a structure connecting galaxies – and discovered it’s not static, but pulsates and moves.

Key findings/Details:

Observation Method: The observation was made using the MUSE instrument on the Very Large Telescope (VLT) in Chile. They detected ionized hydrogen shine.
what was observed: A filament connecting two galaxies wiht active quasars. This was previously only possible to model through simulations.
Dynamic Nature: The cosmic web is not static. The filaments palpitate and move, transporting gas and energy. They function like “invisible arteries” feeding galaxies.
Quote: “We have just seen that what shapes the universe is not visible, but the invisible,” said the scientists.
Related Articles: The article also links to two other articles:
One about a possible simulation of reality where gravity could be the key to confirmation.
* Another about how quantum networks could prove how spacetime affects the laws of physics.In essence,the article highlights a new understanding of the universe’s structure – it’s a dynamic,moving network,not a fixed arrangement.

How might Grinberg’s experiments on synchronized brainwaves be interpreted within the context of quantum entanglement, and what further research could explore this connection?

Jacobo Grinberg and the Hidden Threads Connecting galaxies: Unveiling the Milky Way’s Invisible Network of Light Filaments

The Pioneering Work of Jacobo Grinberg-Zylberbaum

Jacobo grinberg-Zylberbaum, a Mexican neurophysiologist and physicist, dedicated his life to exploring the interconnectedness of the universe, specifically focusing on what he termed “bioenergetic fields” and their relationship to galactic structures. While his work remains controversial within mainstream science, Grinberg’s research offers a compelling, albeit unconventional, outlook on the large-scale structure of the cosmos and the potential for information transfer across vast distances. His core hypothesis centers around the existence of a network of light filaments connecting galaxies, a concept now gaining traction with advancements in observational astronomy. Understanding Grinberg’s contributions requires delving into his experimental methodology and the theoretical framework he proposed.

Grinberg’s Experiments: Measuring Interconnected Consciousness

Grinberg’s most famous experiments, conducted in the 1970s and 80s, involved pairs of individuals placed in isolated, electromagnetically shielded rooms.He monitored their brain activity using electroencephalography (EEG) and observed statistically notable correlations in their brainwave patterns, even when they where unaware of each other’s presence.

Synchronized Brainwaves: The key finding was the synchronization of alpha waves – brainwaves associated with relaxation and focused attention – between the subjects.

Distance Independence: Remarkably, the correlation persisted nonetheless of the physical distance separating the participants, suggesting a non-local connection.

Emotional Influence: Grinberg found that emotional states, particularly feelings of empathy or distress, amplified the synchronization effect.

These experiments led him to believe that human consciousness isn’t confined to the individual brain but is part of a larger, interconnected field. He theorized that this field is mediated by photons – particles of light – traveling along the galactic filament network.

Galactic Filaments: the Cosmic Web Revealed

For decades, astronomers believed the universe was relatively homogeneous. Though, observations over the past few decades, particularly through large-scale galaxy surveys, have revealed a different picture: a vast cosmic web. This web consists of:

Nodes: Dense clusters of galaxies.

Filaments: Long,thread-like structures connecting the nodes. These filaments are composed of dark matter, gas, and galaxies.

Voids: Large, relatively empty regions between the filaments.

These galactic filaments aren’t just structural features; they act as conduits for matter and energy. Recent studies confirm that these filaments are not empty space, but contain significant amounts of baryonic matter – the “normal” matter we’re familiar with.

Connecting Grinberg’s Theory to the Cosmic Web

Grinberg proposed that these galactic filaments aren’t merely gravitational structures but also channels for information transfer via coherent photons. He believed that the universe is fundamentally a holographic system, where information is encoded in the interference patterns of light.

Coherent Photons: Grinberg posited that the filaments facilitate the propagation of coherent photons, meaning photons that are in phase with each other, allowing for efficient and lossless transmission of information.

Bio-photons and Galactic Alignment: He suggested a link between the bio-photons emitted by living organisms and the alignment of galaxies along these filaments.

the milky Way’s Position: the Milky Way galaxy resides within the Laniakea Supercluster, a massive gravitational basin connected to numerous filaments. This positioning, according to Grinberg’s theory, makes our galaxy a crucial node in the galactic network.

Evidence Supporting the Filament Network & Information Transfer

While Grinberg’s ideas were initially met with skepticism, several lines of evidence are now converging to support the existence of a functional galactic filament network:

Fast Radio Bursts (FRBs): The origin of FRBs – intense bursts of radio waves from distant galaxies – remains a mystery. Some theories suggest they travel along these filaments, experiencing less dispersion than if they traveled through intergalactic space.

Quasar Alignment: observations have shown that quasars (extremely luminous active galactic nuclei) tend to align along large-scale structures, including galactic filaments.

Dark flow: The “dark flow” phenomenon – the apparent movement of galaxy clusters towards a specific region of the universe – could be explained by the gravitational influence of structures beyond the observable universe,connected via the filament network.

Cosmic Microwave Background Anomalies: Certain anomalies in the Cosmic Microwave Background (CMB) radiation,the afterglow of the Big Bang,may be indicative of large-scale structures and energy flows along filaments.

Implications for Understanding Consciousness and the Universe

If Grinberg’s hypothesis is correct, the implications are profound. It suggests that:

consciousness is Universal: Consciousness isn’t limited to individual brains but is a fundamental property of the universe, facilitated by the galactic network.

Interconnectedness of Life: All life in the universe might potentially be interconnected through this network, explaining phenomena like intuition, remote viewing, and collective consciousness.

New Physics Required: Understanding the filament network and its role in information transfer may require