Skip to main content

What Is Dark Energy? The Mystery Behind The Expanding Universe

Dark energy is the placeholder name scientists have given to the unknown force causing the universe to expand faster and faster over time.



Paris: Dark energy makes up roughly 70 percent of the universe, yet we know nothing about it.

Around 25 percent of the universe is the equally mysterious dark matter, leaving just five percent for everything that we can see and touch matter made up of atoms. Dark energy is the placeholder name scientists have given to the unknown force causing the universe to expand faster and faster over time.

But some recent cosmic clues have been chipping away at the leading theory for this phenomenon, which could eventually mean humanity will have to rethink our understanding of the universe. And with several new telescopes taking aim at the problem, scientists hope to have some concrete answers soon.

Here is what you need to know about what many scientists have called the greatest mystery in the universe.

So what is dark energy exactly?

No one knows. It is invisible and it does not interact with matter or light. And it may not even exist. This story begins like everything else at the Big Bang around 13.8 billion years ago, when the universe first started expanding.

Since then, there has been "cosmic tug-of-war" between two mysterious forces, Joshua Frieman, a theoretical astrophysicist at the University of Chicago, told AFP. Dark matter is thought to pull galaxies together, while dark energy pushes them apart.

During the first nine or so billion years of the universe, "dark matter was winning," forming galaxies and everything else, Frieman said. Then dark energy gained the upper hand, starting to speed up the expansion of the universe. However, for most of history, scientists had little idea this almighty tussle was going on. They thought that the expansion of the universe would simply start to slow down because of gravity.

Everything changed in 1998 when two separate groups of astronomers noticed that distant exploding stars called supernovae were farther away than they ought to be. This led to the discovery that the universe is not just expanding it is do so faster and faster. So what could be causing this acceleration? They gave this strange force a name: dark energy.

What are the main theories?

The leading theory has long been that empty space itself produces dark energy.

Think of a cup of coffee, Frieman said.

"If I remove all the particles from the cup of coffee, there is still energy in there due to what we call the quantum vacuum," he said. This energy of empty space is known as the cosmological constant. It is the theory used in the standard model of cosmology, Lambda-CDM, which is our best guess for how the universe works. But in recent years, several scientific results have appeared to support a rival theory called evolving dark energy which has brought the standard model into question.

On Wednesday, new results from the Dark Energy Spectroscopic Instrument provided the latest signs that dark energy could actually be weakening over time. However, the scientists behind the research emphasise there is not yet definitive proof. If proven right, this would rule out that dark energy is a cosmological constant.

It could not be "the energy of empty space because empty space doesn't change," explained Frieman, a leading proponent of the theory. For dark matter to change, it would likely require the existence of some incredibly light, as-yet-unknown particle. Another possibility is that there is something wrong with our calculations or our understanding of gravity.

Einstein's theory of relativity has withstood an incredible amount of scientific scrutiny over the last century, and has been proven right again and again. There is no evidence that Einstein was wrong, but there is "a little bit of room" to change his theory when it comes to the largest scales of the universe, Frieman said.

When could we know more?

Soon. The best way to understand dark energy is to look at a vast swathe of sky, taking in as many galaxies with as much data as possible. And a bunch of new telescopes are working to do just that.

On Wednesday, Europe's Euclid space telescope released its first astronomical data since launching in 2023 but any dark energy results are a couple of years away.

NASA's Nancy Grace Roman space telescope, planned for launch in 2027, and the under-construction Vera Rubin Observatory in Chile will also take aim at the problem. It is an exciting time for dark energy, Frieman said, adding that he expected a "definitive answer" in the next couple of years.

There is no time to waste, Frieman said.

"Every minute we wait, galaxies are disappearing from view."

Website: International Research Awards on High Energy Physics and Computational Science.


#HighEnergyPhysics#ParticlePhysics#QuantumPhysics#AstroparticlePhysics#ColliderPhysics#HiggsBoson#LHC#QuantumFieldTheory#NeutrinoPhysics#PhysicsResearch#ComputationalScience#DataScience#ScientificComputing#NumericalMethods#HighPerformanceComputing#MachineLearningInScience#BigData#AlgorithmDevelopment#SimulationScience#ParallelComputing

Visit Our Website : hep-conferences.sciencefather.com
Nomination Link :hep-conferences.sciencefather.com/award-nomination/?ecategory=Awards&rcategory=Awardee
Registration Link : hep-conferences.sciencefather.com/award-registration/
Member Link : hep-conferences.sciencefather.com/conference-membership/?ecategory=Membership&rcategory=Member
Awards-Winners : hep-conferences.sciencefather.com/awards-winners/
For Enquiries: physicsqueries@sciencefather.com

Get Connected Here:
==================
Social Media Link
Twitter : x.com/Psciencefather
Pinterest : in.pinterest.com/physicsresearchorganisation
Blog : physicscience23.blogspot.com
Instagram : www.instagram.com/victoriaanisa1
YouTube :www.youtube.com/channel/UCzqmZ9z40uRjiPSr9XdEwMA
Tumblr : www.tumblr.com/blog/victoriaanisa

Comments

Popular posts from this blog

Physicists observe a new form of magnetism for the first time

MIT physicists have demonstrated a new form of magnetism that could one day be harnessed to build faster, denser, and less power-hungry " spintronic " memory chips. The new magnetic state is a mash-up of two main forms of magnetism: the ferromagnetism of everyday fridge magnets and compass needles, and antiferromagnetism, in which materials have magnetic properties at the microscale yet are not macroscopically magnetized. Now, the MIT team has demonstrated a new form of magnetism , termed "p-wave magnetism." Physicists have long observed that electrons of atoms in regular ferromagnets share the same orientation of "spin," like so many tiny compasses pointing in the same direction. This spin alignment generates a magnetic field, which gives a ferromagnet its inherent magnetism. Electrons belonging to magnetic atoms in an antiferromagnet also have spin, although these spins alternate, with electrons orbiting neighboring atoms aligning their spins antiparalle...

new research in qauntum physics

         VISIT:https: //hep-conferences.sciencefather.com/          N ew research in  qauntum physics.                                                    Alphabet Has a Second, Secretive Quantum Computing Team Recent research in quantum physics includes the development of quantum computers, which are expected to be much more powerful than conventional computers and could revolutionize many aspects of technology, such as artificial intelligence and cryptography. Other research includes the development of quantum sensors for a variety of applications, including medical diagnostics, and the study of quantum entanglement and its potential to enable quantum computing and secure communication. Additionally, research is being conducted into the applications of quantum mechanics in materials science, such as unde...

Freezing light? Italian scientists froze fastest thing in universe, here’s how

In a rare occurrence, physics made it possible to control the fastest travelling element - light. Italian scientists have managed to freeze the light, as per reports. A recent study published in a British weekly journal reportedly revealed that light can exhibit ‘ supersolid behavior ’ a unique state of matter that flows without friction while retaining a solid-like structure. The research, led by Antonio Gianfate from CNR Nanotec and Davide Nigro from the University of Pavia, marks a significant step in understanding supersolidity in light. The scientists described their findings as “just the beginning” of this exploration, as per reports. In what can be termed as ‘manipulating photons under controlled quantum conditions ’, the scientists demonstrated that light, too, can exhibit this behaviour. (A photon is a bundle of electromagnetic energy which is massless, and travel at the speed of light) How did scientists freeze light? As we know, freezing involves lowering a liquid’s tempera...