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Category: cosmology

The origin of space time matter and everything

On the Same Origin of Spacetime, Matter, and Everything https://lnkd.in/gCs9XBzx What if space, time, matter, gravity, dark matter, and dark energy all come from one thing: quantum entanglement? 1. Reality starts as a quantum state (not spacetime) In EWOG, the universe does **not** begin with space and time. It begins with a single quantum state: |Ψ⟩ ∈ No coordinates No distances No clocks Only quantum information. ➡ Spacetime appears later. 2. Geometry is quantum, not classical Spacetime is not a background — it is made of operators: ĝ_μν, R̂_μν, R̂ What we experience as classical spacetime is just the **average**: g_μν = ⟨ ĝ_μν ⟩ Intuition: Spacetime is a *shadow* cast by quantum entanglement. 3.

Finding runaway stars to help map dark matter in the Milky Way

Hypervelocity stars have, since the 1920s, been an important tool that allows astronomers to study the properties of the Milky Way galaxy, such as its gravitational potential and the distribution of matter. Now astronomers from China have made a large-volume search for hypervelocity stars by utilizing a special class of stars known for their distinct, regular, predictable pulsation behavior that makes them useful as distance indicators.

Their research is published in The Astrophysical Journal.

The escape velocity of any planet, star or galaxy is the velocity required for a mass, leaving the object’s surface, to coast completely and exactly out of the planet’s gravitational well, going to infinity. Earth’s escape velocity is 11.2 kilometers per second (km/s).

Searching for light dark matter by tracking its direction with quantum sensors

Dark matter is an elusive type of matter that does not emit, absorb or reflect light, interacting very weakly with ordinary matter. These characteristics make it impossible to detect using conventional technologies used by physicists to study matter particles.

As it has never been observed before, the exact composition of dark matter remains unknown. One proposed theory is that this elusive type of matter is comprised of light particles with very small masses, below 1 eV (electronvolt), which behave more like waves than particles.

Researchers at the University of Tokyo and Chuo University recently explored the possibility of searching for sub-GeV dark matter using quantum sensors, advanced systems that rely on quantum mechanical effects to detect extremely weak signals.

This Quantum Paradox Is So Strange, It Terrifies Scientists

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When people hear the word “paradox,” they usually think of something like a logic puzzle or a brain teaser. Something strange, but mostly harmless. But in quantum physics, paradoxes aren’t just puzzles. They point to something much deeper—a place where our understanding of reality breaks down.

1:13 Quantum Paradox.
8:53 The Quantum Eraser Paradox.
13:52 Wigner’s Friend (Observer vs. Observer)
19:50 Time Symmetry and Retrocausality.
26:26 Quantum Pseudo-Telepathy.
32:28 Quantum Cheshire Cat.
38:18 The Quantum Suicide Twist.
44:20 The Black Hole Information Paradox.
51:02 The Measurement Problem.
57:42 Closing the Loop.

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ASKAP discovers a spectacular outflow in a nearby galaxy

Using the Australian Square Kilometer Array Pathfinder (ASKAP), an international team of astronomers has discovered a spectacular bipolar outflow from the disk of a nearby galaxy known as ESO 130-G012. The finding was reported in a paper published December 17 on the pre-print server arXiv.

ESO 130-G012 is an edge-on galaxy at a distance of some 55 million light years, with an estimated stellar mass of about 11 billion solar masses. The galaxy has a star-formation rate at a level of 0.2 solar masses per year and hosts a black hole approximately 50 million times more massive than the sun.

Hunting for dark matter axions with a quantum-powered haloscope

Axions are hypothetical light particles that could solve two different physics problems, as they could explain why some nuclear interactions don’t violate time symmetry and are also promising dark matter candidates. Dark matter is a type of matter that does not emit, reflect or absorb light, and has never been directly observed before.

Axions are very light particles theorized to have been produced in the early universe but that would still be present today. These particles are expected to interact very weakly with ordinary matter and sometimes convert into photons (i.e., light particles), particularly in the presence of a strong magnetic field.

The QUAX (Quest for Axions/QUaerere AXion) collaboration is a large group of researchers based at different institutes in Italy, which was established to search for axions using two haloscopes located in Italy at Laboratori Nazionali di Legnaro (LNL) and Laboratori Nazionali di Frascati (LNF), respectively.

NASA’s Roman telescope will observe thousands of newfound cosmic voids

Our universe is filled with galaxies, in all directions as far as our instruments can see. Some researchers estimate that there are as many as 2 trillion galaxies in the observable universe. At first glance, these galaxies might appear to be randomly scattered across space, but they’re not. Careful mapping has shown that they are distributed across the surfaces of giant cosmic “bubbles” up to several hundred million light-years across. Inside these bubbles, few galaxies are found, so those regions are called cosmic voids. NASA’s Nancy Grace Roman Space Telescope will allow us to measure these voids with new precision, which can tell us about the history of the universe’s expansion.

“Roman’s ability to observe wide areas of the sky to great depths, spotting an abundance of faint and distant galaxies, will revolutionize the study of cosmic voids,” said Giovanni Verza of the Flatiron Institute and New York University, lead author on a paper published in The Astrophysical Journal.

Cosmic recipe The cosmos is made of three key components: normal matter, dark matter, and dark energy. The gravity of normal and dark matter tries to slow the expansion of the universe, while dark energy opposes gravity to speed up the universe’s expansion. The nature of both dark matter and dark energy is currently unknown. Scientists are trying to understand them by studying their effects on things we can observe, such as the distribution of galaxies across space.

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