Lifeboat Foundation: Safeguarding Humanity
Toggle light / dark theme

Blog

Category: particle physics

Scientists discover new heavy proton-like particle at CERN

Scientists from the University of Manchester have played a leading role in the discovery of a new subatomic particle at CERN’s Large Hadron Collider (LHC). The particle, known as the Ξcc ⁺ (Xi‑cc‑plus), is a new type of heavy proton-like particle containing two charm quarks and one down quark.

The result is the first particle discovery made using the upgraded LHCb detector, a major international project involving more than 1,000 scientists across 20 countries. The UK made the largest national contribution to the upgrade, with significant leadership from Manchester.

The newly observed Ξcc ⁺ is a heavier relative of the proton, which was famously discovered in Manchester by Ernest Rutherford and colleagues in 1917–1919. The proton contains two up quarks and a down quark. Details of the Ξcc ⁺ discovery were presented at the Rencontres de Moriond Electroweak conference.

CERN Discovers New Particle After Upgrading Large Hadron Collider

The Large Hadron Collider has discovered a new particle, the 80th identified so far by the world’s most powerful particle smasher, Europe’s CERN physics laboratory announced Tuesday.

The new particle has been named “Xi-cc-plus”

Scientists hope the particle – which is similar to a proton but four times heavier – will reveal more about the strange behaviour of quantum mechanics.

💡 We talk about the past as if it’s gone forever — erased, unreachable, finished

But according to Richard Feynman and the laws of physics, that intuition is deeply misleading.

At the fundamental level, the equations that describe reality don’t care which way time flows. The same mathematics behind Quantum Electrodynamics — the most precisely tested theory in science — work just as well forward in time as they do backward.

In this video, we explore why the past may not be as “gone” as it feels.

🎥 *In this video, we explore:*
→ Why the laws of physics don’t distinguish past from future
→ How particles can be treated as moving backward in time in calculations
→ What time symmetry really means — and what it doesn’t
→ Why our experience of time is not fundamental
→ How Feynman explained time without mysticism.

This isn’t philosophy or speculation.
This is how physicists actually calculate the universe.

📚 *Based on the work of:*

Continue reading “💡 We talk about the past as if it’s gone forever — erased, unreachable, finished” | >

Nanoengineered spintronic device can store data in four different ways

Over the past decades, electronics engineers have been trying to develop increasingly smaller devices that can store information reliably, even when they are not powered on. A promising type of non-volatile memory device is spintronics, solid-state systems that store and process information leveraging the spin (i.e., an intrinsic form of angular momentum) of electrons.

Researchers at University of Maryland and other institutes recently introduced a new spintronic device based on nanoscale structures based on materials that exhibit ferromagnetism (i.e., a permanent yet switchable magnetic order) and ferroelectricity (i.e., a permanent yet switchable electric polarization). This device, presented in a paper published in Nature Nanotechnology, can switch between four stable resistance states and could thus serve as a multistate memory.

The system that was nanoengineered by the researchers combines two different types of devices, known as magnetic tunnel junctions (MTJs) and ferroelectric tunnel junctions (FTJs). An MTJ consists of two magnetic thin films separated by an insulating thin film, while an FTJ is composed of two different metal electrode layers separated by a thin ferroelectric film. Both these types of devices have proved to be promising information storage solutions.

Perovskite crystals can host qubits, challenging long-held assumptions

For the first time, researchers have demonstrated that the properties of the perovskite family of materials can be used to create so-called quantum bits. The findings, published in the journal Nature Communications, pave the way for more affordable materials in future quantum computers.

According to the researchers from Linköping University, Sweden, behind the study, few within the field believed it would be possible. The reason is that the atoms in perovskite materials should, in theory, interact so strongly that the qubit would collapse before the calculation could be completed. However, the experiments conducted by the Linköping team show that it works.

“Our findings open up an entirely new research field,” says Yuttapoom Puttisong, associate professor at Linköping University.

LHCb Collaboration discovers new proton-like particle

The LHCb experiment at CERN’s Large Hadron Collider (LHC) has discovered a new particle consisting of two charm quarks and one down quark, a similar structure to the familiar proton, but with two heavy charm quarks replacing the two up quarks of the proton, thus quadrupling its mass. The discovery, presented at the ongoing Moriond conference, will help physicists better understand how the strong force binds protons, neutrons and other composite particles together.

Quarks are fundamental building blocks of matter and come in six flavours: up, down, charm, strange, top and bottom. They usually combine in groups of twos and threes to form mesons and baryons, respectively. Unlike the stable proton, however, most of these mesons and baryons, which are collectively known as hadrons, are unstable and short-lived, making them a challenge to observe. Producing them requires smashing together high-energy particles in a machine such as the Large Hadron Collider (LHC). These unstable hadrons will quickly decay, but the more stable particles that are produced as a result of this decay can be detected and the properties of the original particle can therefore be deduced.

Researchers have used this approach many times to find new hadrons, and the new particle just announced by the LHCb Collaboration brings the total number of hadrons discovered by LHC experiments up to 80.

Laser-assisted electron scattering seen with circularly polarized light for the first time

Researchers from Tokyo Metropolitan University have succeeded in detecting laser-assisted electron scattering (LAES) using circularly polarized light for the first time. The use of circularly polarized light promises valuable insights into how atomic scale “helicity” impacts how electrons interact with matter and light.

Using synchronized femtosecond laser pulses and electron pulses directed at argon atoms, they succeeded in detecting a LAES signal showing excellent agreement with theory. The findings are published in The Journal of Chemical Physics.

LAES is a cutting-edge tool for understanding how electrons interact with matter under the influence of strong fields. When electrons are fired at atoms or molecules, they are scattered in all directions; the presence of strong light can change the way in which the scattering takes place due to an exchange of energy with the surrounding light field.

Could a recently detected ultra-high-energy neutrino be linked to new physics?

Neutrinos are extremely lightweight and electrically neutral particles that rarely interact with ordinary matter. Due to these rare interactions, neutrinos can travel across space almost entirely unaffected, carrying information about highly energetic cosmological events, such as exploding stars or supermassive black holes.

The KM3NeT neutrino telescope, an observatory located at the bottom of the Mediterranean Sea, recently detected the presence of a neutrino carrying extremely high energy, above 100 PeV (peta-electronvolts). This is one of the most energetic neutrinos observed to date.

Theoretical predictions suggested that another large-scale neutrino detector, namely the IceCube detector, would also observe similar high-energy neutrino events. However, this did not happen, which might potentially hint at some new physics, such as a new type of neutrinos or non-standard interactions, that are not included in the standard model of physics.

/* */