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Electrons Collection

Electrons, the tiny particles that revolutionized our understanding of the atomic world, have captivated scientists and artists alike

Background imageElectrons Collection: Particle physics experiment, artwork

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

Background imageElectrons Collection: Niels Bohr, caricature

Niels Bohr, caricature
Niels Bohr (1885-1962). Caricature of the Danish physicist Niels Henrik David Bohr, blowing orbiting electrons out of his pipe. Bohr won the Nobel Prize for Physics in 1922

Background imageElectrons Collection: Particle physics experiment, artwork

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

Background imageElectrons Collection: Nuclear Fission Artwork

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)

Background imageElectrons Collection: Atomic structure, artwork

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

Background imageElectrons Collection: Plutonium, atomic model

Plutonium, atomic model
Plutonium. Schematic Bohr model of a plutonium atom. the 94 electrons (red) are orbiting a central nucleus (not shown) composed of protons and neutrons

Background imageElectrons Collection: Quantum physics: nucleus made up of 2 neutrons and 2 protons

Quantum physics: nucleus made up of 2 neutrons and 2 protons

Background imageElectrons Collection: Crookes tube in which cathode rays were emitted

Crookes tube in which cathode rays were emitted
5311986 Crookes tube in which cathode rays were emitted; (add.info.: Engraving depicting Crookes tube in which cathode rays (electrons) were emitted by the cathode, a

Background imageElectrons Collection: The Aurora Borealis

The Aurora Borealis
3740649 The Aurora Borealis; (add.info.: Illustration depicting the Aurora Borealis observed from the HMS Daedalus. Dated 19th Century.); Universal History Archive/UIG

Background imageElectrons Collection: The Aurora Borealis, 19th century (engraving)

The Aurora Borealis, 19th century (engraving)
3740648 The Aurora Borealis, 19th century (engraving); (add.info.: Illustration depicting the Aurora Borealis observed from Berville-sur-Mer. Dated 19th Century.); Universal History Archive/UIG

Background imageElectrons Collection: The Aurora Borealis

The Aurora Borealis
3740659 The Aurora Borealis; (add.info.: Illustration depicting the Aurora Borealis observed from Paris. Dated 19th Century.); Universal History Archive/UIG

Background imageElectrons Collection: The Aurora Borealis

The Aurora Borealis
3740657 The Aurora Borealis; (add.info.: Illustration depicting the Aurora Borealis observed from Orleans. Dated 19th Century.); Universal History Archive/UIG

Background imageElectrons Collection: The Aurora Borealis

The Aurora Borealis
3740658 The Aurora Borealis; (add.info.: Illustration depicting the Aurora Borealis observed from Orleans. Dated 19th Century.); Universal History Archive/UIG

Background imageElectrons Collection: The Aurora Borealis

The Aurora Borealis
3740654 The Aurora Borealis; (add.info.: Illustration depicting the Aurora Borealis observed during the Franklin's lost expedition. Dated 19th Century.); Universal History Archive/UIG

Background imageElectrons Collection: The Aurora Borealis

The Aurora Borealis
3740656 The Aurora Borealis; (add.info.: Illustration depicting the Aurora Borealis observed from Boulogne-sur-Mer. Dated 19th Century.); Universal History Archive/UIG

Background imageElectrons Collection: The Aurora Borealis

The Aurora Borealis
3740655 The Aurora Borealis; (add.info.: Illustration depicting the Aurora Borealis observed from Dublin. Dated 19th Century.); Universal History Archive/UIG

Background imageElectrons Collection: The Phenomenon of Electrical Luminosity, from l Univers et l Humanite

The Phenomenon of Electrical Luminosity, from l Univers et l Humanite
CHT236039 The Phenomenon of Electrical Luminosity, from l Univers et l Humanite by Hans Kraemer, c.1900 (colour litho) by French School, (20th century); Private Collection; eArchives Charmet; French

Background imageElectrons Collection: An Electroscope (photo)

An Electroscope (photo)
XCF277648 An Electroscope (photo) by English Photographer; Private Collection; (add.info.: An instrument for detecting the presence of static electricity; ); English, out of copyright

Background imageElectrons Collection: Diagram showing the formation of a sun-spot (litho)

Diagram showing the formation of a sun-spot (litho)
6004833 Diagram showing the formation of a sun-spot (litho) by English School, (20th century); Private Collection; (add.info.: Diagram showing the formation of a sun-spot)

Background imageElectrons Collection: Oxygen atomic structure, artwork

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)

Background imageElectrons Collection: Helium, atomic model

Helium, atomic model
Heium, atomic model. Helium has two neutrons (white) and two protons (pink) in its nucleus (centre). The atom also has two electron (blue) orbiting the nucleus

Background imageElectrons Collection: Electron diffraction pattern

Electron diffraction pattern. Demonstration of wave-particle duality. An electron gun has been fired at a thin sheet of graphite

Background imageElectrons Collection: Beryllium, atomic model

Beryllium, atomic model. Beryllium has five neutrons (white) and four protons (pink) in its nucleus (centre). The atom also has four electron (blue) orbiting the nucleus

Background imageElectrons Collection: Boron, atomic model

Boron, atomic model. Boron has six neutrons (white) and five protons (pink) in its nucleus (centre). The atom also has five electron (blue) orbiting the nucleus

Background imageElectrons Collection: The final stages of the life of a massive star, which will go supernova

The final stages of the life of a massive star, which will go supernova

Background imageElectrons Collection: Buckyballs floating in interstellar space near a region of current star-formation

Buckyballs floating in interstellar space near a region of current star-formation
This artists conception shows buckyballs floating in interstellar space, near a region of current star-formation. Buckyballs are the largest molecule ever discovered floating between the stars

Background imageElectrons Collection: Artists concept showing carbon balls ejecting out from a dying white star in a planetary

Artists concept showing carbon balls ejecting out from a dying white star in a planetary
Artists concept showing carbon balls coming out from the type of object where they were discovered, a dying star and the material it sheds, known as a planetary nebula

Background imageElectrons Collection: Charles Thomas Rees Wilson (1869-1959) Scottish nuclear and atomic physicist. Wilson s

Charles Thomas Rees Wilson (1869-1959) Scottish nuclear and atomic physicist. Wilson s
Charles Thomas Rees Wilson (1869-1959) Scottish nuclear and atomic physicist. Wilsons Cloud Chamber for tracking electrons and alpha-particles

Background imageElectrons Collection: Blue glass globe filled with bright plasma lines

Blue glass globe filled with bright plasma lines

Background imageElectrons Collection: Tunnelling current amplifier, artwork C017 / 3618

Tunnelling current amplifier, artwork C017 / 3618
Tunnelling current amplifier, computer artwork. Tunnelling current amplifiers are used in scanning tunnelling spectroscopy

Background imageElectrons Collection: Particles in forcefield, artwork

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

Background imageElectrons Collection: Praseodymium, atomic structure

Praseodymium, atomic structure
Bismuth (Bi). Diagram of the nuclear composition, electron configuration, chemical data, and valence orbitals of an atom of bismuth-209 (atomic number: 83), the most common isotope of this element

Background imageElectrons Collection: Structure of matter, artwork C018 / 0948

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)

Background imageElectrons Collection: Phosphorus, atomic structure C018 / 3696

Phosphorus, atomic structure C018 / 3696
Argon (Ar). Diagram of the nuclear composition, electron configuration, chemical data, and valence orbitals of an atom of argon-40 (atomic number: 18)

Background imageElectrons Collection: Atom, artwork F006 / 8760

Atom, artwork F006 / 8760
Atom. Schematic diagram of an atom

Background imageElectrons Collection: Rechargeable battery, artwork

Rechargeable battery, artwork
Rechargeable battery, Computer artwork showing the structure of a typical lithium-ion rechargeable battery. The battery consists of a cathode (green) and anode (red)

Background imageElectrons Collection: Science book, conceptual artwork

Science book, conceptual artwork
Science book. Conceptual artwork of a science book, with the science, and physics and chemistry in particular, represented by ellipse symbols that depict electron orbits

Background imageElectrons Collection: Rutherfordium, atomic structure

Rutherfordium, atomic structure
Argon (Ar). Diagram of the nuclear composition, electron configuration, chemical data, and valence orbitals of an atom of argon-40 (atomic number: 18)

Background imageElectrons Collection: Niels Bohr, Danish physicist

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

Background imageElectrons Collection: 19th Century Crookes Tube

19th Century Crookes Tube. Invented by William Crookes (1832-1919) in the late 19th century this apparatus was used to investigate the path taken by electrons, or cathode rays as they were known

Background imageElectrons Collection: 19th Century Crookes Tubes

19th Century Crookes Tubes. Invented by William Crookes (1832-1919) in the late 19th century this apparatus was used to investigate the path taken by electrons, or cathode rays as they were known

Background imageElectrons Collection: Hydrogen atom, conceptual model C013 / 5605

Hydrogen atom, conceptual model C013 / 5605
Hydrogen atom, conceptual model. Computer artwork representing the atomic structure of hydrogen. Hydrogen has one proton and one neutron (large spheres) in its nucleus (large circle, centre)

Background imageElectrons Collection: Helium atom, conceptual model C013 / 5600

Helium atom, conceptual model C013 / 5600
Helium atom, conceptual model. Computer artwork representing the atomic structure of helium. Helium has two protons and two neutrons (large spheres) in its nucleus (faint circle, centre)

Background imageElectrons Collection: Helium atom, conceptual model C013 / 5601

Helium atom, conceptual model C013 / 5601
Helium atom, conceptual model. Computer artwork representing the atomic structure of helium. Helium has two protons and two neutrons (large spheres) in its nucleus (faint circle, centre)

Background imageElectrons Collection: Atomic interactions, conceptual image C013 / 5595

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

Background imageElectrons Collection: Photon emission, artwork

Photon emission, artwork
Photon emission. Computer artwork of an atom (large sphere) emitting a photon (yellow). The atom consists of a nucleus (blue, centre), which contains neutrons and protons (not shown)

Background imageElectrons Collection: Formation of sodium chloride, artwork

Formation of sodium chloride, artwork. At left are sodium (Na) and chlorine (Cl) atoms. At right is a molecule of sodium chloride (NaCl), or salt. This is an example of ionic bonding

Background imageElectrons Collection: Particles, conceptual artwork C013 / 5639

Particles, conceptual artwork C013 / 5639
Particles, conceptual computer artwork

Background imageElectrons Collection: Quantum states, conceptual artwork C013 / 5630

Quantum states, conceptual artwork C013 / 5630
Quantum states, conceptual artwork. In physics, a quantum state is a set of mathematical variables that fully describes a quantum system

Background imageElectrons Collection: Particles, conceptual artwork C013 / 5626

Particles, conceptual artwork C013 / 5626
Particles, conceptual computer artwork

Background imageElectrons Collection: Particles, conceptual artwork C013 / 5627

Particles, conceptual artwork C013 / 5627
Particles, conceptual computer artwork

Background imageElectrons Collection: Structure of matter, artwork C017 / 8029

Structure of matter, artwork C017 / 8029
Structure of matter. Computer artwork representing the Standard Model of particle physics. Shown here are an atom (left) composed of electrons (blue) orbiting a central nucleus

Background imageElectrons Collection: Hydrogen atoms, conceptual model C013 / 5606

Hydrogen atoms, conceptual model C013 / 5606
Hydrogen atoms, conceptual model. Computer artwork representing the structure of hydrogen atoms. Each atom has one proton and one neutron (large spheres) in its nucleus (pink)

Background imageElectrons Collection: Graphene conductivity, conceptual image C013 / 8897

Graphene conductivity, conceptual image C013 / 8897
Graphene conductivity, conceptual image. Computer artwork of a graphene sheet with electricity (yellow) passing through it. Graphene is a single layer of graphite

Background imageElectrons Collection: Higgs boson research, ATLAS detector C013 / 6893

Higgs boson research, ATLAS detector C013 / 6893
Higgs boson research. 3D computer graphic showing one of the numerous particle collision events recorded during the search for the Higgs boson

Background imageElectrons Collection: Higgs boson research, ATLAS detector C013 / 6894

Higgs boson research, ATLAS detector C013 / 6894
Higgs boson research. Graphic of a transverse section through a detector showing one of the numerous particle collision events recorded during the search for the Higgs boson

Background imageElectrons Collection: Higgs boson research, ATLAS detector C013 / 6889

Higgs boson research, ATLAS detector C013 / 6889
Higgs boson research. Graphic of a transverse section through a detector showing one of the numerous particle collision events recorded during the search for the Higgs boson

Background imageElectrons Collection: Higgs boson research, ATLAS detector C013 / 6888

Higgs boson research, ATLAS detector C013 / 6888
Higgs boson research. 3D computer graphic showing one of the numerous particle collision events recorded during the search for the Higgs boson

Background imageElectrons Collection: Higgs boson research, CMS detector C013 / 6884

Higgs boson research, CMS detector C013 / 6884
Higgs boson research. Graphic of a longitudinal section through a detector showing a collision event recorded during the search for the Higgs boson

Background imageElectrons Collection: Higgs boson research, CMS detector C013 / 6882

Higgs boson research, CMS detector C013 / 6882
Higgs boson research. 3D computer graphic showing one of the numerous particle collision events recorded during the search for the Higgs boson

Background imageElectrons Collection: Radiant matter physics, 19th century

Radiant matter physics, 19th century
" Radiant matter" physics. 19th-century artwork of physicists carrying out experiments on what they called radiant matter

Background imageElectrons Collection: Early radiography experiment

Early radiography experiment. Historical artwork of a Ruhmkorff induction coil (left) being used to create a large electrical voltage across a Crookes tube (glass tube, upper right)

Background imageElectrons Collection: Hydrogen fuel cell, artwork

Hydrogen fuel cell, artwork
Hydrogen fuel cell, computer artwork. This is a clean and efficient power source. Hydrogen is liberated from a natural source such as methanol or natural gases

Background imageElectrons Collection: Supernova remnant Cassiopeia A, X-ray

Supernova remnant Cassiopeia A, X-ray image. Cassiopeia A (Cas A) is a remnant of a supernova star that exploded around 320 years ago, the youngest in the Milky Way galaxy

Background imageElectrons Collection: Human intelligence

Human intelligence. Conceptual artwork representing human intelligence. It has a human brain as the nucleus (centre) of an atom, surrounded by electron orbitals (pink)

Background imageElectrons Collection: Planetary orbits, artwork

Planetary orbits, artwork
Planetary orbits, conceptual computer artwork

Background imageElectrons Collection: Atomic structure, conceptual artwork

Atomic structure, conceptual artwork
Atomic structure. Conceptual computer artwork of electron orbit paths as rings around the central nucleus (yellow) of an atom

Background imageElectrons Collection: Solar power, conceptual artwork

Solar power, conceptual artwork
Solar Energy collecting by solar cells

Background imageElectrons Collection: Lithium atoms, computer artwork

Lithium atoms, computer artwork
Computer artwork of seven lithium atoms with their nucleus and the three orbiting electrons

Background imageElectrons Collection: Plum pudding model of the atom, artwork

Plum pudding model of the atom, artwork. This model was proposed by the British physicist J J Thomson in 1904, seven years after he had discovered the electron

Background imageElectrons Collection: Lithium, atomic model

Lithium, atomic model. Lithium has three neutrons (white) and three protons (pink) in its nucleus (centre). The atom also has three electron (blue) orbiting the nucleus

Background imageElectrons Collection: Deuterium, atomic model

Deuterium, atomic model
Deuterium. Atomic model of deuterium, also known as heavy hydrogen, an isotope of hydrogen. Isotopes are forms of an element that contain different numbers of neutrons in the atomic nucleus (centre)

Background imageElectrons Collection: Quantum spin

Quantum spin. Image depicting spinning particles, representing the quantum property known as spin. Spin transport electronics (also known as magnetoelectronics or spintronics)

Background imageElectrons Collection: Subatomic physics

Subatomic physics. Electrons (yellow) surrounding the nucleus (centre) of an atom. The blue lines represent the forces involved when removing an electron from an atom, a process known as ionisation

Background imageElectrons Collection: Electromagnetic force

Electromagnetic force. Charged particles interacting through the electromagnetic force (field lines shown). Electricity and magnetism are part of the same force, called electromagnetism

Background imageElectrons Collection: Spintronics technology

Spintronics technology. Also known as spin transport electronics, or magnetoelectronics, this technology takes advantage of the electrons spin and magnetic moment to enable the design

Background imageElectrons Collection: Nickel atom

Nickel atom. This is the most common and stable form for atoms of the metal nickel (atomic number 28). The nucleus (centre) contains 28 protons and 31 neutrons

Background imageElectrons Collection: Atomic particle decay, artwork

Atomic particle decay, artwork
Atomic particle decay, conceptual computer artwork. Particle decay is the spontaneous transformation of one elementary particle into other elementary particles

Background imageElectrons Collection: Manganese and copper voltaic cell

Manganese and copper voltaic cell. Copper (right) and manganese (left) half cells joined by a salt bridge. When a stick of copper (Cu)

Background imageElectrons Collection: Electron flow

Electron flow. Computer model representing the flow of electrons through a two-dimensional electron gas (2DEG). The " gas" is composed of many free electrons

Background imageElectrons Collection: Neon atom, artwork

Neon atom, artwork
Neon atom. Computer artwork of electron orbitals in a neon atom. The nucleus is represented by a flash of light. The orbitals shown are 1s (small white sphere)

Background imageElectrons Collection: Atom, artwork

Atom, artwork
Atomic structure. Conceptual computer artwork of nine electrons orbiting a central nucleus. Other particles are seen around the atom. This is a classical schematic Bohr model of an atom

Background imageElectrons Collection: Subatomic particles abstract

Subatomic particles abstract

Background imageElectrons Collection: Atomic structure, conceptual artwork

Atomic structure, conceptual artwork
Atomic structure. Conceptual computer artwork of electron orbit paths as rings around the central nuclei (dark clusters) of atoms. This is a classical schematic Bohr model of atoms



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Electrons, the tiny particles that revolutionized our understanding of the atomic world, have captivated scientists and artists alike. In the realm of particle physics experiments, electrons take center stage as they are studied to unravel the mysteries of matter. Their elusive nature is beautifully portrayed in artwork inspired by these experiments. Niels Bohr, a pioneer in quantum theory, is often depicted in caricatures alongside electrons buzzing around him like mischievous companions. These whimsical illustrations capture his groundbreaking contributions to atomic structure and electron behavior. The power is further explored through nuclear fission artwork. This captivating form of energy release showcases their role in splitting atoms and generating immense amounts of power. Artwork depicting atomic structures brings forth a visual representation of how electrons orbit around a nucleus, forming intricate patterns unique to each element. Plutonium's atomic model stands out with its complexity and significance in nuclear reactions. "The Phenomenon of Electrical Luminosity" from "l'Univers et l'Humanité" highlights how electrons play a pivotal role in creating light and illuminating our world. The mesmerizing glow emitted by electrical devices owes its existence to these energetic particles. An electroscope captured in a photo symbolizes humanity's ability to detect and measure the presence or movement of charged particles like electrons. It represents our quest for knowledge about these fundamental building blocks. A lithograph showcasing the formation of sunspots reveals yet another facet where electron activity influences celestial phenomena on an astronomical scale. This diagram demonstrates how magnetic fields interact with charged particles within our sun's atmosphere. Even elements like oxygen come alive through artistic renditions portraying their atomic structures intricately woven with orbiting electrons. Such artworks remind us that even seemingly mundane substances hold hidden wonders at an atomic level. Electron diffraction patterns provide valuable insights into their wave-like properties when passing through crystalline materials or obstacles—a phenomenon that defies classical intuition but aligns perfectly with quantum mechanics principles.

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