Particle Collection

Higgs boson event, ATLAS detector C013 / 6892
Higgs boson event. Graphic of a transverse section through a detector showing one of the numerous particle collision events recorded during the search for the Higgs boson

Higgs boson, conceptual artwork
Higgs boson, conceptual computer artwork. The Higgs boson is a proposed fundamental particle that is thought to give other particles mass

Particle physics equations

Higgs boson, conceptual artwork
Higgs boson, conceptual computer artwork. The Higgs boson is a proposed fundamental particle that is thought to give other particles mass

Particle physics experiment, artwork
Particle physics experiment. Artwork of tracks of particles detected following a collision in a particle accelerator. In these experiments

Simulation of Higgs boson production
^BSimulated detection of Higgs boson. ^b Computer simulation of an event in which the decay of a Higgs boson particle produces four muons. Two of these muons are seen here (green tracks)

Particle physics experiment, artwork
Particle physics experiment. Artwork of tracks of particles detected following a collision in a particle accelerator. In these experiments

Nuclear Fission Artwork
Nuclear fission. Conceptual computer artwork of an atom being split through nuclear, or atomic, fission (splitting). Electrons (orange) can be seen orbiting the nucleus (centre)

Particle physics equations

Simulation of Higgs boson production
Simulated detection of Higgs boson. Computer simulation of an event in which the decay of a Higgs boson particle produces four muons. Two of these muons are seen here (green tracks)

Herpes virus replicating, computer artwork.Viruses are only able to replicate in a host cell.The glycoprotein spikes in the virus envelope(green)

CDF particle detector, Fermilab
MODEL RELEASED. CDF particle detector at the Fermi National Accelerator Laboratory (Fermilab) near Chicago, USA. The CDF (Collider Detector Facility)

Swarm of nanorobots, computer artwork. Nanotechnology is an area of science concerned with producing mechanical entities whose size is measured in nanometres (billionth of a metre)

Atomic structure, artwork
Atomic structure. Computer artwork of electrons orbiting a central nucleus. This is a classical schematic Bohr model of an atom

Prof. Peter Higgs
British theoretical physicist Professor Peter Higgs (b. 1929). In 1964, Higgs predicted the existence of a new type of fundamental particle, commonly called the Higgs boson

Norovirus particles, TEM
Norovirus particles. Coloured transmission electron micrograph (TEM) of norovirus particles. Norovirus is a genus of RNA (ribonucleic acid)

Emulsion photo of decay of kaon into pions
The first observation of the decay of a kaon into 3 pions, recorded in special photographic emulsion by Cecil Powells team at Bristol University in 1948

Simulation of Higgs boson production
Simulated detection of Higgs boson. Computer simulation of an event in which the decay of a Higgs boson particle produces four muons (red tracks)

Protozoa, a single-celled organism that feeds by scavenging for particles and other microorganisms, such as bacteria, or by absorbing nutrients from their environment

Microscopic view of human respiratory syncytial virus (RSV). RSV causes respiratory tract infection of the lungs and breathing passages

James Chadwick, British physicist C017 / 7111
James Chadwick (1891-1974), British physicist. Educated in Manchester, Chadwicks research under Rutherford was mainly with alpha particles (helium nuclei)

Particle collision, artwork C018 / 0942
Particle collision. Computer artwork of particles colliding and splitting to produce smaller particles. This is the process used by particle accelerators such as the Large Hadron Collider (LHC)

Infections spread by sneezing, artwork C013 / 5949
Infections spread by sneezing. Computer artwork showing virus particles (virions, blue) and bacteria (rod-shaped) in the spray produced by someone when they sneeze

Coronavirus particles, TEM
Coronavirus particles. Coloured transmission electron micrograph (TEM) of three coronavirus particles. Different strains of coronavirus are responsible for diseases such as the common cold

Nuclear fusion, artwork C017 / 7664
Nuclear fusion, computer artwork. At left are the atomic nuclei of deuterium (top left) and tritium (bottom left). Atomic nuclei consist of protons (white and purple) and neutrons (pink)

Influenza virus, computer artwork
Influenza virus. Computer artwork of an influenza (flu) virus. The virus consists of a core of RNA (ribonucleic acid) genetic material surrounded by a protein coat

Influenza virus particles, TEM
Influenza virus particles, coloured transmission electron micrograph (TEM). This virus is the cause of the respiratory disease influenza (flu) in humans and other animals

Hepatitis C viruses, TEM
Hepatitis C viruses. Coloured transmission electron micrograph (TEM) of hepatitis C virus particles (green) infecting cultured liver cells (purple)

Evolution of the Universe, artwork
Evolution of the Universe. Computer artwork showing the evolution of the Universe from the Big Bang (far left) 12-15 billion years ago to the present day (far right)

Particle collision. This event takes place in particle accelerators, which are used to accelerate particles (spheres) such as protons to high energies near the speed of light

Polyoma BK virus, artwork C013 / 7465
Computer artwork of the capsid of a polyoma BK virus. This polyomavirus is common in the urinary tract of adults, where it lives without harming its host

Rift Valley fever virus, TEM

Paramyxovirus particles, TEM
Sendai virus. Coloured transmission electron micrograph (TEM) of Sendai virus particles (virions, orange). The protein coat (capsid) of one of the particles has split

Quantum universe

Particle accelerator. Trails (red) of energised particles inside a particle accelerator. Particle accelerators are used to accelerate particles such as protons to near the speed of light

Rotavirus particle, artwork
Rotavirus particle. Cut-away artwork showing the structure of the rotavirus icosahedral capsid (protein coat). The capsid, which encloses the RNA (ribonucleic acid) genome

Higgs Boson particle, artwork
Higgs Boson particle. Computer artwork of a yellow sphere in a circular chamber with light emanating from behind it. This could represent the Higgs Boson particle being discovered in a particle

Snowy Mountain Top
Mauro

Snowy Mountain Top
Mauro

Snowy Mountain Top
Mauro

Snowy Mountain Top
Mauro

Specimen XII
Amy Louise Baker

Specimen XI
Amy Louise Baker

Specimen X
Amy Louise Baker

Specimen IX
Amy Louise Baker

Specimen VIII
Amy Louise Baker

Specimen VII
Amy Louise Baker

Specimen VI
Amy Louise Baker

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In the vast realm of particle physics, a world filled with intricate equations and mind-boggling experiments, lies the enigmatic entity known as the "particle. " From its discovery to its profound implications, this captivating caption delves into various aspects that define these minuscule building blocks of our universe. At the heart of it all, we find ourselves immersed in the Higgs boson event. A momentous occasion where scientists at ATLAS detector C013/6892 unveiled crucial insights into this elusive particle's existence. Conceptual artwork depicting the Higgs boson serves as a visual representation of its significance within the field. Delving deeper into particle physics equations, we witness an intricate web woven by brilliant minds seeking to unravel nature's secrets. These formulas stand as testaments to human curiosity and determination to understand how particles interact and shape our reality. Simulations take us on a journey through time and space, unveiling mesmerizing visuals portraying Higgs boson production. These virtual realms allow scientists to explore scenarios that would otherwise be impossible or too dangerous in real-life experiments. As we ponder upon these scientific wonders, conceptual artwork brings forth vivid representations of both particle physics experiments and nuclear fission processes. Each stroke captures humanity's tireless pursuit of knowledge while showcasing the beauty hidden within atomic structures. Amidst this exploration lies Prof. Peter Higgs himself - a visionary who laid down theoretical foundations for understanding particles' behavior. His groundbreaking work earned him recognition alongside other luminaries in his field. Beyond traditional research methods lie innovative technologies like nanorobots swarming together with precision reminiscent of nature itself. This convergence between science fiction and reality opens up new frontiers for manipulating particles at unimaginably small scales. From grand detectors like CDF at Fermilab to artistic interpretations highlighting atomic structures, every facet reveals just how intricately intertwined they are with our existence. They hold answers yet undiscovered; they shape matter from stars to the tiniest atoms.