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Electron Collection

"The Electron: Unveiling the Mysteries of Particle Physics and Beyond" In the vast realm of particle physics

Background imageElectron Collection: 5f electron orbitals, cubic set

5f electron orbitals, cubic set, computer model. An electron orbital is a region around an atomic nucleus (not seen) in which one or a pair of electrons is most likely to exist

Background imageElectron Collection: Bubble chamber photo of sigma particle decay

Bubble chamber photo of sigma particle decay. The sigma lives too briefly to be seen; its presence is deduced from other particles

Background imageElectron Collection: Particle physics equations

Particle physics equations

Background imageElectron 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

Background imageElectron 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 imageElectron 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

Background imageElectron Collection: Nuclear Fission Artwork

Nuclear Fission Artwork
Nuclear fission. Conceptual computer artwork of an atom being split through nuclear, or atomic, fission (splitting)

Background imageElectron 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 imageElectron Collection: Particle physics equations

Particle physics equations

Background imageElectron Collection: Higgs boson, artwork C018 / 0936

Higgs boson, artwork C018 / 0936
Higgs boson. Computer artwork showing a Higgs boson particle, which was formed by the collision of two protons, decaying into a pair of Z bosons, one of which decays to a pair of electrons

Background imageElectron Collection: Simulium damnosum, Simulian blackfly

Simulium damnosum, Simulian blackfly
Scanning electron microscope image of the head showing the compound eye (x 130). The fly is a vector of a parasite which causes River Blindness. Coloured artifically by computer

Background imageElectron Collection: Electron structure of helium atom

Electron structure of helium atom
Electron density of a helium atom. This image represents the quantum cloud of electrons surrounding a helium atom

Background imageElectron Collection: Snail teeth

Snail teeth

Background imageElectron Collection: Plasmodium sp. malarial parasite

Plasmodium sp. malarial parasite
Scanning electron microscope image of a malarial protozoal parasite. The parasite requires the anopheles mosquito to complete its life cycle

Background imageElectron Collection: Ernest Rutherford, caricature

Ernest Rutherford, caricature
Ernest Rutherford (1871-1937). Caricature of the New Zealand physicist Ernest Rutherford, with an electron orbiting his head

Background imageElectron Collection: Picture No. 11675585

Picture No. 11675585
Scanning Electron micrograph (SEM)showing stomata on a Yew Leaf. Date:

Background imageElectron Collection: Picture No. 11675478

Picture No. 11675478
Scanning Electron Micrograph (SEM): Freshwater Diatom, Cyclotella meneghiniana. Date:

Background imageElectron Collection: Picture No. 11675612

Picture No. 11675612
Scanning Electron Micrograph (SEM): Human White and Red Blood Cells. Date:

Background imageElectron Collection: Picture No. 11675599

Picture No. 11675599
Dark Field Light Micrograph: Lancet Liver Fluke. Date:

Background imageElectron Collection: Picture No. 10876997

Picture No. 10876997
Scanning Electron Micrograph (SEM): Human Skin with Hair Follicles Date:

Background imageElectron Collection: JJ Thomson, British nuclear physicist, 1898

JJ Thomson, British nuclear physicist, 1898. Joseph John Thomson (1856-1940), the discoverer of the electron, with his students at the Cavendish Laboratory, Cambridge

Background imageElectron Collection: JJ (Joseph John) Thomson (1856-1940) British Nuclear physicist, discovered electron

JJ (Joseph John) Thomson (1856-1940) British Nuclear physicist, discovered electron, here with his research students at the Cavendish Laboratory, Cambridge, in 1898

Background imageElectron Collection: Electricity machine by Pixii

Electricity machine by Pixii
An early form of an alternating current electrical generator built by Pixii in 1832

Background imageElectron Collection: Picture No. 11675582

Picture No. 11675582
Scanning Electron micrograph (SEM): Lily Pollen grains. Date:

Background imageElectron Collection: Picture No. 10873704

Picture No. 10873704
Sleeping Sickness Parasite in red blood cells (Trypanosoma sp. ) Date:

Background imageElectron Collection: Acanthoica acanthifera, coccosphere

Acanthoica acanthifera, coccosphere
Scanning electron microscope (SEM) image of a coccosphere, collected in the North Atlantic (x 25, 000 on negative). Artificially coloured by computer

Background imageElectron Collection: Scyliorhinus canicula, dogfish

Scyliorhinus canicula, dogfish
Scanning electron microscope (SEM) image of the scales of a dogfish (x 40)

Background imageElectron Collection: Atomic structure

Atomic structure, computer artwork. Schematic representation of the structure of the atom. At the centre of the model is the nucleus, made up of a tightly packed cluster of protons and neutrons

Background imageElectron Collection: Particle tracks on galaxies

Particle tracks on galaxies
Particle tracks and cosmology. Computer illustration of subatomic particle tracks (white spirals) seen with galaxies behind them

Background imageElectron Collection: Aspergillus

Aspergillus
An SEM image of aspergillus in spore production (x 815 on a standard 9 cm wide print). The moulds are common in the northern hemisphere and some cause disease in humans and animals

Background imageElectron Collection: Picture No. 11675628

Picture No. 11675628
Scanning Electron Micrograph (SEM): Stomata of Yew Leaf. Date:

Background imageElectron Collection: Helium He chemical element. Helium Sign with atomic number

Helium He chemical element. Helium Sign with atomic number. Chemical 2 element of periodic table. Periodic Table of the Elements with atomic number, w Helium He chemical element

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

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

Background imageElectron Collection: J J Thomson and other Cavendish Laboratory research students

J J Thomson and other Cavendish Laboratory research students
3586077 J J Thomson and other Cavendish Laboratory research students; (add.info.: Photograph of J. J. Thompson (1856-1940) and other Cavendish Laboratory research students

Background imageElectron Collection: Baird Electron Scanner System of Television

Baird Electron Scanner System of Television, showing the Electron Scanner when used for the televising of talking films. This can be employed for a definition of 100-500 lines

Background imageElectron Collection: 1956 Fairthorpe Electron at Brands Hatch. Creator: Unknown

1956 Fairthorpe Electron at Brands Hatch. Creator: Unknown
1956 Fairthorpe Electron at Brands Hatch

Background imageElectron Collection: JJ Thomson, British physicist, c1896-c1915

JJ Thomson, British physicist, c1896-c1915
JJ Thomson, British physicist, 1896-1916. Joseph John Thomson (1856-1940) discovered the electron and was a pioneer of nuclear physics

Background imageElectron Collection: Picture No. 11014634

Picture No. 11014634
Common Frog - mid stage of tadpole development Scanning Electron Micrograph (SEM): Magnification x 85 (if print A4 size: 29.7 cm wide) - Gills are resorbed and jaws better developed

Background imageElectron Collection: Picture No. 11014629

Picture No. 11014629
Caddis Fly Scanning Electron Micrograph (SEM): Magnification x 20 (if print A4 size: 29.7 cm wide) - Caddis flies spend most of their lives as aquatic larvae in ponds and streams

Background imageElectron Collection: Picture No. 11014630

Picture No. 11014630
Cheese Mite Scanning Electron Micrograph (SEM): Magnification x 350 (if print A4 size: 29.7 cm wide) (Tyrolichus casei) Date:

Background imageElectron Collection: Picture No. 11014628

Picture No. 11014628
Caenorhabditis elegans Scanning Electron Micrograph (SEM): Magnification x 1750 (if print A4 size)

Background imageElectron Collection: Picture No. 11014626

Picture No. 11014626
Bumblebee Scanning Electron Micrograph (SEM): Magnification x30 (if print A4 size: 29.7 cm wide) (Bombus terrestris) Date:

Background imageElectron Collection: Picture No. 11014624

Picture No. 11014624
Escherishia Coli Bacteria / E

Background imageElectron Collection: Picture No. 11014620

Picture No. 11014620
Mosquito Larvae Scanning Electron Micrograph (SEM): Magnification x40 (if print A4 size: 29.7 cm wide) - The malarial mosquito larvae live in pools and puddles; almost any standing water will do

Background imageElectron Collection: Picture No. 11014623

Picture No. 11014623
Black Garden Ant Scanning Electron Micrograph (SEM): Magnification x120 (if print A4 size: 29.7 cm wide) (Lasius niger) Date:

Background imageElectron Collection: Picture No. 11014622

Picture No. 11014622
Mosquito Scanning Electron Micrograph (SEM): Magnification x90 (if print A4 size: 29.7 cm wide) - Portrait of the malarial mosquito showing the antenae and palps

Background imageElectron Collection: Picture No. 11014616

Picture No. 11014616
Sunflower Pollen Scanning Electron Micrograph (SEM): Magnification x15

Background imageElectron Collection: Picture No. 11014592

Picture No. 11014592
Aconite Anther - with pollen Scanning Electron Micrograph (SEM): Magnification x 11150 (if print A4 size)

Background imageElectron Collection: Picture No. 11014591

Picture No. 11014591
Aconite Anther - with pollen Scanning Electron Micrograph (SEM): Magnification x 450 (if print A4 size)

Background imageElectron Collection: Picture No. 10873637

Picture No. 10873637
Human Head Louse (Pediculus humanus capitis) Date:

Background imageElectron Collection: Oxygen atomic structure, artwork

Oxygen atomic structure, artwork
Oxygen atomic structure. Computer artwork showing the structure of an oxygen atom

Background imageElectron Collection: The anus of a bot fly

The anus of a bot fly
Scanning electron microscope image of the anus of a bot fly. Image on display in the Darwin Centre at the Natural History Museum, London

Background imageElectron Collection: Coccinella sp. black spotted ladybird

Coccinella sp. black spotted ladybird
Scanning electron microscope image showing the head of a black spotted ladybird (x 9 on a standard 9 cm wide print). This image has been coloured artifically by computer

Background imageElectron Collection: Dermatophagoides pteronyssius, dust mite

Dermatophagoides pteronyssius, dust mite
Scanning electron microscope image showing a dust mite (x 250 on standard 9cm wide print). This image has been artificially coloured by a computer

Background imageElectron Collection: Gigantiops destructor, South American jumping ant

Gigantiops destructor, South American jumping ant
High magnification image made with a scanning electron microscope of the head of a South American jumping ant. Image coloured artificially by a computer

Background imageElectron 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 imageElectron Collection: 3d electron orbitals

3d electron orbitals, computer model. An electron orbital is a region around an atomic nucleus (not seen) in which one or a pair of electrons is most likely to exist

Background imageElectron Collection: W particle decay in Ua1 detector at CERN

W particle decay in Ua1 detector at CERN
W particle decay

Background imageElectron 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 imageElectron Collection: Salvinia Effect of Salvinia natans

Salvinia Effect of Salvinia natans
Scanning electron micrograph of leaf detail of Salvinia natans, a floating fern type plant which has superhydrophobic trichomes or hairs on the upper surface of its leaves

Background imageElectron Collection: JJ Thomson, British physicist, at work in the Cavendish Laboratory, Cambridge

JJ Thomson, British physicist, at work in the Cavendish Laboratory, Cambridge. Joseph John Thomson (1856-1940) discovered the electron and was a pioneer of nuclear physics

Background imageElectron Collection: Transmission electron microscope EM9. Signed: Carl Zeiss

Transmission electron microscope EM9. Signed: Carl Zeiss. 1964

Background imageElectron Collection: Illustration of Rutherford model of the atom

Illustration of Rutherford model of the atom, consisting of nucleus and negatively charged electrons

Background imageElectron Collection: Digital illustration of electroscope showing electrostatic induction using ballpoint pen and jar

Digital illustration of electroscope showing electrostatic induction using ballpoint pen and jar

Background imageElectron Collection: Picture No. 11014633

Picture No. 11014633
Penicillin Colony This is a culture of the original strain of bacteria used by Flemming in the early research into the first antibiotics. Obliquely lit macro image from a time-lapse sequence. Date:

Background imageElectron Collection: Picture No. 11014631

Picture No. 11014631
Diatom Scanning Electron Micrograph (SEM): Magnification x5275 (if print A4 size: 29.7 cm wide) - The diatoms are single celled algae

Background imageElectron Collection: Picture No. 11014632

Picture No. 11014632
Diatom Scanning Electron Micrograph (SEM): Magnification x 4370 (if print A4 size: 29.7 cm wide) - The diatoms are single celled algae

Background imageElectron Collection: Picture No. 11014627

Picture No. 11014627
Spectacle Moth - eggs Scanning Electron Micrograph (SEM): Magnification x 35 (if print A4 size: 29.7 cm wide) (Abrostola tripartita) Date:

Background imageElectron Collection: Picture No. 11014625

Picture No. 11014625
Bedbug Scanning Electron Micrograph (SEM): Magnification x120 (if print A4 size: 29.7 cm wide) (Cimex lectularius) Date:

Background imageElectron Collection: Picture No. 11014621

Picture No. 11014621
Mosquito Larvae Scanning Electron Micrograph (SEM): Magnification x40 (if print A4 size: 29.7 cm wide) - The malarial mosquito larvae live in pools and puddles; almost any standing water will do

Background imageElectron Collection: Picture No. 11014619

Picture No. 11014619
Shelled Amoeba Scanning Electron Micrograph (SEM)): Magnification x5130 (if print A4 size: 29.7 cm wide) - Testate amoebae are found in damp soil, leaf litter and pools

Background imageElectron Collection: Picture No. 11014611

Picture No. 11014611
Primrose Pollen Scanning Electron Micrograph (SEM): Magnification 2 x28, 000 (if print A4 size: 29.7 cm wide) - Primroses appear in early spring and are usually yellow

Background imageElectron Collection: Picture No. 11014610

Picture No. 11014610
Primrose Pollen Scanning Electron Micrograph (SEM): Magnification x12, 000 (if print A4 size: 29.7 cm wide) - Primroses appear in early spring and are usually yellow. They are insect pollinated Date:

Background imageElectron Collection: Picture No. 11014609

Picture No. 11014609
Hazel Pollen Scanning Electron Micrograph (SEM): Magnification x12, 000 b1 (if print A4 size: 29.7 cm wide) - Hazel pollen is very small and is carried by the wind to stigma of other trees

Background imageElectron Collection: Picture No. 11014608

Picture No. 11014608
Grass Pollen Scanning Electron Micrograph (SEM): Magnification 2 x4560 (if print A4 size: 29.7 cm wide) - Gypsophyla is a small pink or white flower; insect pollinated Date:

Background imageElectron Collection: Picture No. 11014605

Picture No. 11014605
Grass Pollen Scanning Electron Micrograph (SEM): Magnification 2 x9410 (if print A4 size: 29.7 cm wide) - Grass pollen is wind pollinated

Background imageElectron Collection: Picture No. 11014602

Picture No. 11014602
Daffodil Pollen Scanning Electron Micrograph (SEM): Magnification x16900 (if print A4 size: 29.7 cm wide) - Daffodils are popular and common springtime flowers. Insect pollinated Date:

Background imageElectron Collection: Picture No. 11014603

Picture No. 11014603
Daisy Pollen Scanning Electron Micrograph (SEM): Magnification 2 x9k (if print A4 size: 29.7 cm wide) - Daisies are small insect pollinated flowers; common in lawns Date:

Background imageElectron Collection: Picture No. 11014600

Picture No. 11014600
Crocus Pollen Scanning Electron Micrograph (SEM): Magnification x4000 (if print A4 size: 29.7 cm wide) - Crocus is a common spring flower, insect pollinated Date:

Background imageElectron Collection: Picture No. 11014598

Picture No. 11014598
Celandine Pollen Scanning Electron Micrograph (SEM): Magnification x17, 600 (if print A4 size: 29.7 cm wide) - is a yellow springtime flower. Insect pollinated, it is toxic to humans Date:

Background imageElectron Collection: Picture No. 11014597

Picture No. 11014597
Celandine Pollen Scanning Electron Micrograph (SEM): Magnification x4900 (if print A4 size: 29.7 cm wide) - is a yellow springtime flower. Insect pollinated, it is toxic to humans. Date:

Background imageElectron Collection: Picture No. 11014595

Picture No. 11014595
Bumblebee Scanning Electron Micrograph (SEM): Magnification x40 (if print A4 size: 29.7 cm wide) (Bombus terrestris) Date:

Background imageElectron Collection: Picture No. 10873599

Picture No. 10873599
Human Crab Louse (Phthirus pubis) Date:



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"The Electron: Unveiling the Mysteries of Particle Physics and Beyond" In the vast realm of particle physics, the electron stands as a fundamental building block that has captivated scientists for decades. As we delve into its enigmatic nature, we are greeted with awe-inspiring visuals that shed light on its intricate properties. One such image is the mesmerizing bubble chamber photo capturing the decay of a sigma particle. This snapshot reveals the hidden dance between particles, unraveling their secrets within complex equations adorning scientific papers. Artwork depicting particle physics experiments further immerses us in this captivating world. It serves as a visual testament to human curiosity and our relentless pursuit of knowledge. Among these illustrations, Niels Bohr's caricature reminds us of his groundbreaking contributions to atomic theory. Nuclear fission artwork showcases humanity's quest for harnessing immense energy from splitting atoms—an achievement that forever altered our understanding of power generation and weaponry. The Higgs boson, often referred to as "the God particle, " takes center stage in another remarkable artwork. Its discovery revolutionized our comprehension of mass and solidified our understanding of how particles acquire their weight. Beyond subatomic realms lie unexpected connections—like Simulium damnosum, also known as Simulian blackfly. These tiny creatures possess an intriguing link to electrons through their unique ability to transmit diseases like river blindness—a reminder that science encompasses all facets of life. Delving deeper into atomic structures brings forth stunning artwork showcasing intricate arrangements resembling delicate lacework or snail teeth—a testament to nature's elegance even at microscopic scales. As we revisit those familiar equations describing electron structure within helium atoms, we marvel at how these minuscule entities shape everything around us—the foundation upon which matter is built. The electron remains an ever-present force shaping our world—from powering electronic devices to enabling chemical reactions essential for life itself. Its significance cannot be overstated; it embodies both simplicity and complexity, a paradox that continues to intrigue and inspire scientists worldwide.

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