Particle Physics Collection (page 2)

Homage to six astronomers
7243369 Homage to six astronomers. by Mulder, Joseph (1658-c.1728); Private Collection; (add.info.: Six astronomers. A homage to astronomers throughout the ages)

James Watt watching his grandmothers tea kettle boil (colour litho)
7185299 James Watt watching his grandmothers tea kettle boil (colour litho) by American School, (20th century); Private Collection; (add.info.: James Watt watching his grandmothers tea kettle boil)

Artem Alikhanian, Soviet Armenian physicist (b / w photo)
7200789 Artem Alikhanian, Soviet Armenian physicist (b/w photo) by Russian Photographer, (20th century); Private Collection; (add.info.: Artem Alikhanian (1908-1978), Soviet Armenian physicist

Sir Isaac Newton (colour litho)
7190987 Sir Isaac Newton (colour litho) by English School, (20th century); Private Collection; (add.info.: Sir Isaac Newton)

Cleopatras Needle, ancient Egyptian obelisk in Heliopolis (engraving)
7202558 Cleopatras Needle, ancient Egyptian obelisk in Heliopolis (engraving) by German School, (19th century); Private Collection; (add.info.: Cleopatras Needle)

Three-way electric plug socket adapter (litho)
7202036 Three-way electric plug socket adapter (litho) by English School, (20th century); Private Collection; (add.info.: Three-way electric plug socket adapter)

Abram Alikhanov, Soviet Armenian physicist (b / w photo)
7200787 Abram Alikhanov, Soviet Armenian physicist (b/w photo) by Russian Photographer, (20th century); Private Collection; (add.info.: Abram Alikhanov (1904-1970), Soviet Armenian physicist

Construction of the Pyramids, ancient Egypt (engraving)
7202557 Construction of the Pyramids, ancient Egypt (engraving) by German School, (19th century); Private Collection; (add.info.: Construction of the Pyramids, ancient Egypt)

Oxygen atomic structure, artwork
Oxygen atomic structure. Computer artwork showing the structure of an oxygen atom. Each oxygen atom contains 8 electrons (blue) orbiting the atomic nucleus (centre)

Art of hydrogen atom with electron in orbital
Hydrogen atom. Computer artwork of an atom of the element hydrogen. The atom is shown as a nucleus (a proton, pink), and an electron orbiting in a wavy path (light blue)

L3 particle detector at CERN
L3 particle detector. View along the accelerator beamline into the L3 particle detector at CERN, the European particle physics laboratory near Geneva

Particle collision, artwork C018 / 0943
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)

Nuclear fusion, artwork C017 / 7666
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)

Particles in forcefield, artwork
Conceptual computer artwork depicting particles in a force field

Scanning tunnelling microscope, artwork F005 / 0813
Scanning tunnelling microscope (STM), computer artwork. The STM uses a fine needle with an electric potential running through it to scan the surface of an object

Proton collision C014 / 1796
Particle tracks from a proton-proton collision seen by the LHCb (large hadron collider beauty) detector at CERN (the European particle physics laboratory) near Geneva, Switzerland

Proton collision C014 / 1804
Particle tracks from a proton-proton collision seen by the ATLAS (a toroidal LHC apparatus) detector at CERN (the European particle physics laboratory) near Geneva, Switzerland

Proton collision C014 / 1811
Particle tracks from a proton-proton collision seen by the LHCb (large hadron collider beauty) detector at CERN (the European particle physics laboratory) near Geneva, Switzerland

Higgs boson event C014 / 1812
Particle tracks from a proton-proton collision seen by the CMS (compact muon solenoid) detector at CERN (the European particle physics laboratory) near Geneva, Switzerland

Zero-point energy, artwork C014 / 1245
Zero-point energy. Artwork representing the concept of zero-point energy, related to that of vacuum energy and quantum fluctuations

Structure of matter, artwork C018 / 0948
Structure of matter. Computer artwork representing the Standard Model of particle physics. Shown here is a molecule of water (top centre)

Proton collision C014 / 1802
Cut-away view of the ATLAS (a toroidal LHC apparatus) detector at CERN (the European particle physics laboratory) near Geneva, Switzerland, showing particle tracks from a proton-proton collision

Proton collision C014 / 1809
Particle tracks from a proton-proton collision seen by the ATLAS (a toroidal LHC apparatus) detector at CERN (the European particle physics laboratory) near Geneva, Switzerland

Proton collision C014 / 1814
Particle tracks from a proton-proton collision seen by the ATLAS (a toroidal LHC apparatus) detector at CERN (the European particle physics laboratory) near Geneva, Switzerland

Nuclear fusion, artwork C017 / 7665
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)

British physicist Prof. Peter Higgs C015 / 4139
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

British physicist Prof. Peter Higgs C015 / 4134
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

Fusion reactor, artwork C016 / 7497
Fusion reactor. Computer artwork of a reactor in which hydrogen fusion is taking place. Nuclear fusion is the joining (fusing) of light elements to form heavier elements

Double-slit experiment, artwork C018 / 0929
Double slit experiment, computer artwork. Laser beams (green) are shone at a plate (centre) containing two slits. The light that passes through is observed on a screen (right) behind the plate

Proton collision C014 / 1813
Particles-eye view of particle tracks from a proton-proton collision in the ATLAS (a toroidal LHC apparatus) detector at CERN (the European particle physics laboratory) near Geneva, Switzerland

Proton collision C014 / 1803
Particle tracks from a proton-proton collision seen by the ATLAS (a toroidal LHC apparatus) detector at CERN (the European particle physics laboratory) near Geneva, Switzerland

Proton collision C014 / 1816
Particle tracks from a proton-proton collision seen by the ATLAS (a toroidal LHC apparatus) detector at CERN (the European particle physics laboratory) near Geneva, Switzerland

Antiproton research, 1958 C014 / 2068
Antiproton research. US physicists Bruce Cork (left) and Glenn Lamberston (right) at the Bevatron Accelerator that has been configured for antiproton research

Electron-positron collision C014 / 1799
Two sets of particle tracks from electron-positron collisions seen by the ALEPH (Apparatus for LEP physics at CERN) detector at CERN (the European particle physics laboratory) near Geneva

Proton collision C014 / 1808
Particle tracks from a proton-proton collision seen by the ATLAS (a toroidal LHC apparatus) detector at CERN (the European particle physics laboratory) near Geneva, Switzerland

Proton collision C014 / 1807
Particle tracks from a proton-proton collision seen by the LHCb (large hadron collider beauty) detector at CERN (the European particle physics laboratory) near Geneva, Switzerland

Proton collision C014 / 1798
Cut-away view of the ATLAS (a toroidal LHC apparatus) detector at CERN (the European particle physics laboratory) near Geneva, Switzerland, showing particle tracks from a proton-proton collision

Proton collision C014 / 1806
Particle tracks from a proton-proton collision seen by the CMS (compact muon solenoid) detector at CERN (the European particle physics laboratory) near Geneva, Switzerland

Antineutron discovery team, 1956 C014 / 2067
Antineutron discovery team, working on the focus magnet of the Bevatron Accelerator, the machine they used to create and detect the anti-particle of the neutron

Proton collision C014 / 1815
Particle tracks from a proton-proton collision seen by the LHCb (large hadron collider beauty) detector at CERN (the European particle physics laboratory) near Geneva, Switzerland

Proton collision C014 / 1794
Particle tracks from a proton-proton collision seen by the CMS (compact muon solenoid) detector at CERN (the European particle physics laboratory) near Geneva, Switzerland

Niels Bohr, Danish physicist
Niels Bohr (1885-1962). Bust of the Danish physicist Niels Bohr outside Copenhagen University, Copenhagen, Denmark. Bohr won the Nobel Prize for Physics in 1922

Electron-positron collision
Particle tracks from an electron-positron collision seen by the L3 detector at CERN (the European particle physics laboratory) near Geneva, Switzerland

Guido Tonelli, CERN physicist. Guido Tonelli (born 1950) is an Italian physicist who is one of the leaders of the Compact Muon Solenoid (CMS) project

Atomic interactions, conceptual image C013 / 5595
Atomic interactions, conceptual image. Computer artwork representing the interactions between atomic and sub-atomic particles

Heavy atomic nuclei colliding, artwork
Heavy atomic nuclei colliding. Computer artwork of two heavy atomic nuclei colliding. The collision has created a subatomic particle (lower right)

Fusion reactor, conceptual image C013 / 5944
Fusion reactor, conceptual image. Computer artwork representing a reactor in which hydrogen fusion is taking place. Nuclear fusion is the joining (fusing) of light elements to form heavier elements

Alvarez bubble chamber research, 1959
Alvarez bubble chamber research, Radiation Laboratory of the University of California, Berkeley, USA, July 1959. From left, US engineers and physicists Paul Hernandez (1918-2009)

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"Unveiling the Mysteries of the Subatomic World: Journey into Particle Physics" Step into the fascinating realm of particle physics, where invisible forces shape our universe. Witness the intricate dance of particles through mesmerizing particle tracks, revealing their elusive nature. Behold a captivating bubble chamber photo capturing the decay of a sigma particle, unraveling its secrets one frame at a time. Marvel at the sheer power unleashed in proton collision C014 / 1797, as particles collide with unimaginable energy. Delve deeper into groundbreaking discoveries with an awe-inspiring Higgs boson event captured by ATLAS detector C013 / 6892. Explore the cutting-edge technology employed at CERN's ATLAS detector to unlock the mysteries hidden within subatomic realms. Immerse yourself in conceptual artwork depicting the enigmatic Higgs boson and witness humanity's quest to understand its significance. Celebrate history being made as we observe for the first time ever, omega-minus particle - unveiling new dimensions in our understanding of matter. Discover another marvel in CMS detector at CERN - an instrument pushing boundaries and expanding human knowledge. Engage your imagination with conceptual artwork showcasing Higgs boson's profound impact on our understanding of fundamental particles. Experience a vivid portrayal of scientists' relentless pursuit depicted through stunning artwork capturing thrilling particle physics experiments that challenge conventional wisdom. Pay homage to Niels Bohr, father figure of quantum mechanics, through his caricature - symbolizing his immense contributions towards shaping this field and inspiring generations to come. From lead ion collisions generating mind-boggling energies to revolutionary discoveries that redefine scientific frontiers – Particle Physics is an endless voyage filled with wonderment and limitless possibilities. Embark on this extraordinary journey today.