#Hadron

DK art

@dkartwastaken.bsky.social

3 weeks ago

Developing this idea more

#mechanicus #nsfwart #hadron #darktide #40k #warhammer

DK art

@dkartwastaken.bsky.social

1 month ago

The Darktide lady that’s half robot and insults me repeatedly does things to me ok, i didn’t choose this
Maye WiP maybe I won’t come back to this, who knows lol

#40k #hadron #darktide #warhammer40k #mechanicus

Tali

@talius2.bsky.social

2 months ago

#Large #Hadron #Collider finally explains how #fragile #matter #forms

CERN researchers discovered that fragile deuterons form from decaying high-energy particles as fireballs cool, explaining how they exist despite the LHC’s extreme heat. scitechupdates.com/l...

This is Fun

@rbrtjay.bsky.social

2 months ago

#gayai #aigay #gay #gayporn #homoerotic #gaysex #gaymen #naked #nudemen #gaynaked #dick #cock #bigdick #hadron #erect #hardcock #bigballs #BeardedMen #gayChristmas #gayXmas

This is Fun

@rbrtjay.bsky.social

2 months ago

#gayai #aigay #gay #gayporn #homoerotic #gaysex #gaymen #naked #nudemen #gaynaked #pits #pubes #dick #cock #bigdick #hadron #erect #hardcock #bigballs #BeardedMen #gayChristmas #gayXmas

SpamInHand

@spaminhand.bsky.social

3 months ago

You are making Hadron... Testy. 🔞

#nsfw #warhammer40k #Hadron #Darktide #admech

Q-Gin

@q-gin.bsky.social

7 months ago

Project Motor Racing: il motore Hadron rivoluziona la fisica delle auto da corsa! per una simulazione ultra-realistica Straight4 Studios ha presentato Hadron, la piattaforma di simulazione fisica progettata esclusivamente per Project Motor Racing. Hadron implementa un engine fisico che simula la dinamica veicolare a 720Hz, garantendo una gestione ultrarealistica del comportamento delle vetture. La tecnologia Hadron si basa su una struttura modulare e prevede un solver multi-body open topology, in grado di gestire complessi effetti dinamici tra componenti come ali, winglets e sottofondi.

Entra nel futuro della simulazione di guida! Hadron ridefinisce i limiti della fisica nei racing game con dettagli mai visti prima. Scopri la tecnologia dietro Project Motor Racing 🚗⚡️ #RacingGame #Simulazione #Hadron #Motorsport #GamingNews

Thomas C. Gerlach

@tcgerlach.substack.com

9 months ago

Alchemy is real! #alchemy #hadron

NeutronStars

@neutronstars.activitypub.awakari.com.ap.brid.gy

10 months ago

**High-energy photons produced deep in gamma-ray burst jets emerging from a collapsed star could dissolve the outer stellar layers into free neutrons, causing a series of physical processes that results in the formation of heavy elements, according to apaper published in the _Astrophysical Journal_.** A high-energy photonic jet (white and blue) blasts through a collapsar with a black hole at its center; the red space around the jet represents the cocoon where free neutrons may be captured causing the r-process, the nucleosynthesis that results in the formation of heavy elements. Image credit: Los Alamos National Laboratory. The formation of the heaviest elements relies on astrophysical environments with a copious amount of neutrons. Neutrons can be found in the cosmos bound in atomic nuclei or in medium under extreme pressure. Free neutrons are rare, owing to a half-life of less than 15 minutes. “The creation of heavy elements such as uranium and plutonium necessitates extreme conditions,” said Dr. Matthew Mumpower, a physicist at Los Alamos National Laboratory. “There are only a few viable yet rare scenarios in the cosmos where these elements can form, and all such locations need a copious amount of neutrons. We propose a new phenomenon where those neutrons don’t pre-exist but are produced dynamically in the star.” The key to producing the heaviest elements on the periodic table is known as the rapid neutron-capture process, or r-process, and it is thought to be responsible for production of all naturally occurring thorium, uranium and plutonium in the Universe. The team’s framework takes on the challenging physics of the r-process and resolves them by proposing reactions and processes around star collapses that could result in heavy element formation. In addition to understanding the formation of heavy elements, the proposed framework helps address critical questions around neutron transport, multiphysics simulations, and the observation of rare events — all of which are of interest for national security applications that can glean insights from the research. In the scenario the researchers propose, a massive star begins to die as its nuclear fuel runs out. No longer able to push up against its own gravity, a black hole forms at the star’s center. If the black hole is spinning fast enough, frame-dragging effects from the extremely strong gravity near the black hole wind up the magnetic field and launch a powerful jet. Through subsequent reactions, a broad spectrum of photons is created, some of which are at high energy. “The jet blasts through the star ahead of it, creating a hot cocoon of material around the jet, like a freight train plowing through snow,” Dr. Mumpower said. At the interface of the jet with the stellar material, high-energy photons (that is, light) can interact with atomic nuclei, transmuting protons to neutrons. Existing atomic nuclei may also be dissolved into individual nucleons, creating more free neutrons to power the r-process. The team’s calculations suggest the interaction with light and matter can create neutrons incredibly fast, on the order of a nanosecond. Because of their charge, protons get trapped in the jet by the strong magnetic fields. Neutrons, which are chargeless, are plowed out of the jet into the cocoon. Having experienced a relativistic shock, the neutrons are extremely dense compared with the surrounding stellar material, and thus the r-process may ensue, with heavy elements and isotopes forged and then expelled out into space as the star is ripped apart. The process of protons converting into neutrons, along with free neutrons escaping into the surrounding cocoon to form heavy elements, involves a broad range of physics principles and encompasses all four fundamental forces of nature: a true multiphysics problem, combining areas of atomic and nuclear physics with hydrodynamics and general relativity. Despite the team’s efforts, more challenges remain as the heavy isotopes created during the r-process have never been made on Earth. Researchers know little about their properties including their atomic weight, half-life and so on. The high-energy jet framework proposed by the team may help explain the origination of kilonova — a glow of optical and infrared electromagnetic radiation — associated with long-duration gamma-ray bursts. “Star dissolution via high-energy photon jet offers an alternative origin for the production of heavy elements and the kilonova they may manufacture, a possibility not previously thought to be associated with collapsing stars,” the scientists said. _____ Matthew R. Mumpower _et al_. 2025. Let There Be Neutrons! Hadronic Photoproduction from a Large Flux of High-energy Photons. _ApJ_ 982, 81; doi: 10.3847/1538-4357/adb1e3

Stars Dissolve into Neutrons to Form Heavy Elements, Study Suggests High-energy photons produced ...

www.sci.news/astronomy/hadronic-photo...

#Astronomy #Physics #Collapsar #Cosmic #jet #Gamma-Ray #Burst #Hadron #Jet #Neutron #Nucleosynthesis

Result Details

NeutronStars

@neutronstars.activitypub.awakari.com.ap.brid.gy

10 months ago

**High-energy photons produced deep in gamma-ray burst jets emerging from a collapsed star could dissolve the outer stellar layers into free neutrons, causing a series of physical processes that results in the formation of heavy elements, according to apaper published in the _Astrophysical Journal_.** A high-energy photonic jet (white and blue) blasts through a collapsar with a black hole at its center; the red space around the jet represents the cocoon where free neutrons may be captured causing the r-process, the nucleosynthesis that results in the formation of heavy elements. Image credit: Los Alamos National Laboratory. The formation of the heaviest elements relies on astrophysical environments with a copious amount of neutrons. Neutrons can be found in the cosmos bound in atomic nuclei or in medium under extreme pressure. Free neutrons are rare, owing to a half-life of less than 15 minutes. “The creation of heavy elements such as uranium and plutonium necessitates extreme conditions,” said Dr. Matthew Mumpower, a physicist at Los Alamos National Laboratory. “There are only a few viable yet rare scenarios in the cosmos where these elements can form, and all such locations need a copious amount of neutrons. We propose a new phenomenon where those neutrons don’t pre-exist but are produced dynamically in the star.” The key to producing the heaviest elements on the periodic table is known as the rapid neutron-capture process, or r-process, and it is thought to be responsible for production of all naturally occurring thorium, uranium and plutonium in the Universe. The team’s framework takes on the challenging physics of the r-process and resolves them by proposing reactions and processes around star collapses that could result in heavy element formation. In addition to understanding the formation of heavy elements, the proposed framework helps address critical questions around neutron transport, multiphysics simulations, and the observation of rare events — all of which are of interest for national security applications that can glean insights from the research. In the scenario the researchers propose, a massive star begins to die as its nuclear fuel runs out. No longer able to push up against its own gravity, a black hole forms at the star’s center. If the black hole is spinning fast enough, frame-dragging effects from the extremely strong gravity near the black hole wind up the magnetic field and launch a powerful jet. Through subsequent reactions, a broad spectrum of photons is created, some of which are at high energy. “The jet blasts through the star ahead of it, creating a hot cocoon of material around the jet, like a freight train plowing through snow,” Dr. Mumpower said. At the interface of the jet with the stellar material, high-energy photons (that is, light) can interact with atomic nuclei, transmuting protons to neutrons. Existing atomic nuclei may also be dissolved into individual nucleons, creating more free neutrons to power the r-process. The team’s calculations suggest the interaction with light and matter can create neutrons incredibly fast, on the order of a nanosecond. Because of their charge, protons get trapped in the jet by the strong magnetic fields. Neutrons, which are chargeless, are plowed out of the jet into the cocoon. Having experienced a relativistic shock, the neutrons are extremely dense compared with the surrounding stellar material, and thus the r-process may ensue, with heavy elements and isotopes forged and then expelled out into space as the star is ripped apart. The process of protons converting into neutrons, along with free neutrons escaping into the surrounding cocoon to form heavy elements, involves a broad range of physics principles and encompasses all four fundamental forces of nature: a true multiphysics problem, combining areas of atomic and nuclear physics with hydrodynamics and general relativity. Despite the team’s efforts, more challenges remain as the heavy isotopes created during the r-process have never been made on Earth. Researchers know little about their properties including their atomic weight, half-life and so on. The high-energy jet framework proposed by the team may help explain the origination of kilonova — a glow of optical and infrared electromagnetic radiation — associated with long-duration gamma-ray bursts. “Star dissolution via high-energy photon jet offers an alternative origin for the production of heavy elements and the kilonova they may manufacture, a possibility not previously thought to be associated with collapsing stars,” the scientists said. _____ Matthew R. Mumpower _et al_. 2025. Let There Be Neutrons! Hadronic Photoproduction from a Large Flux of High-energy Photons. _ApJ_ 982, 81; doi: 10.3847/1538-4357/adb1e3

Stars Dissolve into Neutrons to Form Heavy Elements, Study Suggests High-energy photons produced ...

www.sci.news/astronomy/hadronic-photo...

#Astronomy #Physics #Collapsar #Cosmic #jet #Gamma-Ray #Burst #Hadron #Jet #Neutron #Nucleosynthesis

Result Details

OpenSource

@opensource.activitypub.awakari.com.ap.brid.gy

1 year ago

Argonne Aurora Exascale Supercomputer Open for Business The U.S. Department of Energy’s (DOE) A...

www.hpcwire.com/2025/01/30/argonne-auror...

#Short #Takes #Advanced #Photon #Source #ALCF #Aurora #CERN #Large #Hadron #Collider

Event Attributes

Spanish open dictionary

@wordmeaningdic.bsky.social

1 year ago

Meaning of #hadron HADRON: IN PHYSICS AND ASTRONOMY, PARTICLE THAT IS BROKEN OR IS BANKRUPTCY BY THE RECIPROCAL INFLUENCE OF POWERS... hadron

Diccionario Abierto

@significadode.bsky.social

1 year ago

Significado de #hadron hadrón: en la física y la astronomía, partícula que se rompe o se quiebra por la influencia recíproca de potencias... hadron

Dicionário colaborativo Espanhol

@ptsignificadode.bsky.social

1 year ago

Significado de #hadron Hádron: Em física e astronomia, partícula que quebra ou é quebrada pela influência recíproca dos poderes... hadron

For a Better World

@zarcode.bsky.social

1 year ago

The Physicist Decoding the Nonbinary Nature of the Subatomic World | Quanta Magazine Inside the proton, quarks and gluons shift and morph their properties in ways that physicists are still struggling to understand. Rithya Kunnawalkam Elayavalli brings to the problem a perspective unli...

The #Physicist Decoding the #Nonbinary #Nature of the #Subatomic World. #proton #quark #gluon shift/morph #properties not understood. #RithyaKunnawalkamElayavalli brings to the problem a #perspective unlike many of their #peers. #physics #reality #hadron #LHC www.quantamagazine.org/the-physicis...

🎹 Mobstermelodies

@mobstermelodies.bsky.social

1 year ago

MOMMY I MEAN MECHA MOMMY I MEAN. #hadron #darktide #warhammer #art

Ekkehard von Weiher

@ekkehardvonweiher.bsky.social

1 year ago

- YouTube Enjoy the videos and music you love, upload original content, and share it all with friends, family, and the world on YouTube.

#CERN #LHC #Genf #Higgs #Boson #Hadron

Wieviele
teure #Collider ⚛️
braucht dieser #Planet ?

#CERN versus #China
#Konkurrierende #Projekte
#Wissenschaft oder #Prestige ?

Startled Jesus

@startled.bsky.social

2 years ago

The scientists have now admitted that the original set-up didn't work, and they now 'need' an even bigger one.

Slightly ironic that an enormous structure is apparently required to investigate an atom.

Was the whole thing purely designed as a smirky play on words on 'hard on'? #hadron

The Altruist Party - Population Health & Wellbeing

@aphealthcare.bsky.social

9 years ago

Innovation - California - Stanford Medicine, VA collaborate to build nation’s first #hadron therapy center:#cancer

blogs.va.gov/VAntage/32004/…

Alan van Beek

@thiliel.bsky.social

13 years ago

Large Hadron Collider Ikea-style http://wp.me/p1dk0p-eO #science #headbugz #ikea #hadron #rofl