Atom Collection (page 5)

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Mankinds ability to harness atomic power and the atom

Coneptual image, connections, network

ATOMIC ENERGY. An idealized atom

BOYLE: SCEPTICAL CHYMIST. Title-page of the 1661 London edition of Robert Boyle s
BOYLE: SCEPTICAL CHYMIST. Title-page of the 1661 London edition of Robert Boyles The Sceptical Chymist dealing with Boyles concept of matter as composed of atoms and clusters of atoms in motion

Atomic Cooling Tower
16th October 1956: Water cascading down at the bottom of the giant cooling towers at the worlds first full-scale atomic power station at Calder Hall, Cumberland. (Photo by L)

Dounreay
The bottom half of the worlds first electricity-producing fast breeder reactor at Dounreay Nuclear Power Development Establishment in Scotland, 14th July 1956

WW2 - Little girl searching for her home
This charming comic social commentary card from WW2 is either a little girl pondering where her new home will be (following her evacuation from the big city) or (potentially)

Belgium, Brussels, Atomium. Futuristic building built for the International Exhibition of Brussels in 1958

Aurora Borealis at night, Finland, January

John Daltons depiction of the chemical elements from his A New System of Chemical Philosophy, Manchester, 1808
DALTON: CHEMICAL ELEMENTS. John Daltons depiction of the chemical elements from his A New System of Chemical Philosophy, Manchester, 1808

Aurora Borealis and stars over lake at night, Muonio, Lapland, Finland, September

Aurora Borealis and stars over lake with beached canoes at night, Muonio, Lapland, Finland, September

Nuclear Testing
Operation Hurricane, Britains first atomic weapons detonation, takes place off Trimouille Island, in the Monte Bello Islands, 3rd October 1952. (Photo by Fox Photos/Hulton Archive/Getty Images)

Survivors of the explosion of the Atom bomb at Hiroshima 1945 suffering the effects of radiation. ICRC photograph

Hiroshima after the dropping of the atom bomb in August 1945. USAF photograph

Aurora Borealis over fell at night, Saana Fell, Kilpisjarvi, Enontekio, Lapland, Finland, September

Aurora Borealis over lake with rowing boat at night, Lake Kilpisjarvi, Kilpisjarvi, Enontekio, Lapland, Finland, September

Aurora Borealis and star trails over lake at night, Muonio, Lapland, Finland, September

Aurora Borealis, over coastline at night, Hornoya Island, Vardo, Finnmark, Norway, March

Aurora Borealis, over taiga forest at night, Finland, January

Model of a glucose molecule, showing the atomic structure of Oxygen, Carbon and Hydrogen involved in photosynthesis

Lattice of sodium and chlorine atoms, model

Adenine molecule, artwork C017 / 7200
Adenine molecule. Computer artwork showing the structure of a molecule of the nucleobase adenine. Atoms are colour-coded spheres: carbon (green), nitrogen (blue), and oxygen (white)

Thymine molecule, artwork C017 / 7366
Thymine molecule. Computer artwork showing the structure of a molecule of the nucleobase thymine. Atoms are colour-coded spheres: carbon (green), nitrogen (blue), oxygen (red), and hydrogen (white)

Thymine molecule, artwork C017 / 7365
Thymine molecule. Computer artwork showing the structure of a molecule of the nucleobase thymine. Atoms are colour-coded spheres: carbon (green), nitrogen (blue), oxygen (red), and hydrogen (white)

Nanospheres, artwork F006 / 7075
Nanospheres arranged in a circular shape, computer artwork

Tablet computer, insulin molecule F006 / 6311
Tablet computer showing a part of the molecule of human insulin. A single insulin molecule is made up of two chains of amino acids, the A and B chains, which are held together by di-sulphide bridges

Nanospheres, artwork F006 / 7094
Nanospheres arranged in a circular shape, computer artwork

Space-centred cubic crystal structure F006 / 7162
Space-centred cubic crystal structure, computer artwork

Graphene sheet, artwork F006 / 7085
Graphene sheet, computer artwork. Graphene is a single layer of graphite. It is composed of hexagonally arranged carbon atoms (spheres). Graphene is very strong and flexible

Graphene sheet, artwork F006 / 7076
Graphene sheet, computer artwork. Graphene is a single layer of graphite. It is composed of hexagonally arranged carbon atoms (spheres). Graphene is very strong and flexible

Nanospheres, artwork F006 / 7082
Nanospheres arranged in a circular shape, computer artwork

Space-centred cubic crystal structure F006 / 7176
Space-centred cubic crystal structure, computer artwork

Nanospheres, artwork F006 / 7079
Nanospheres arranged in a circular shape, computer artwork

Sarin nerve gas molecule F007 / 9936
Sarin nerve gas, molecular model. Atoms are represented as spheres and are colour-coded: carbon (grey), hydrogen (green), oxygen (red), phosphorous (orange) and fluorine (blue)

Matter transportation F007 / 9896
Matter transportation. Conceptual computer artwork of a human figure, representing a possible method of matter transportation

Carbon nanotube F007 / 9900
Buckytube. Molecular model of part of the cage structure of a bucky- or nanotube. The spheres represent carbon atoms. In this structure hundreds of atoms form hexagon shapes along a tube

Carbon nanotube F007 / 9915
Buckytube. Molecular model of part of the cage structure of a bucky- or nanotube. The spheres represent carbon atoms. In this structure hundreds of atoms form hexagon shapes along a tube

Carbon nanotube F007 / 9910
Buckytube. Molecular model of part of the cage structure of a bucky- or nanotube. The spheres represent carbon atoms. In this structure hundreds of atoms form hexagon shapes along a tube

Immunoglobulin G antibody molecule F007 / 9901
Immunoglobulin G antibody molecule. Computer model of the secondary structure of immunoglobulin G (IgG). This is the most abundant immunoglobulin and is found in all body fluids

Caffeine drug molecule F007 / 9899
Caffeine. Computer model of a molecule of the alkaloid, stimulant and legal drug caffeine. Caffeine is most often consumed in drinks like tea and coffee

Sarin nerve gas molecule F007 / 9933
Sarin nerve gas, molecular model. Atoms are represented as spheres and are colour-coded: carbon (grey), hydrogen (green), oxygen (red), phosphorous (orange) and fluorine (blue)

Immunoglobulin G antibody molecule F007 / 9920
Immunoglobulin G antibody molecule. Computer model of the secondary structure of immunoglobulin G (IgG). This is the most abundant immunoglobulin and is found in all body fluids

Sarin nerve gas molecule F007 / 9938
Leucine, molecular model. Essential alpha-amino acid contained in eggs, soy protein, seaweed, turkey, chicken, lamb, cheese, and fish

Immunoglobulin G antibody molecule F007 / 9889
Immunoglobulin G antibody molecule. Computer model of the secondary structure of immunoglobulin G (IgG). This is the most abundant immunoglobulin and is found in all body fluids

Sarin nerve gas molecule F007 / 9935
Sarin nerve gas, molecular model, The wire-frame map represents the electrostatic potential across the molecules surface. The atoms carbon, hydrogen, oxygen

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"Unveiling the Mysteries of the Atom: From Northern Lights to Quantum Leaps" In the ethereal dance of the Northern lights, nature showcases its own version of atomic beauty. Much like these mesmerizing lights, our understanding of atoms has evolved through groundbreaking scientific discoveries. One such milestone occurred in E. Rutherford's Cavendish Laboratory, where he unraveled the atom's structure and introduced us to its nucleus. This pivotal moment paved the way for Niels Bohr's caricatured quantum model, depicting electrons orbiting around a central core. The power within an atom is not limited to theory alone; it manifests itself in nuclear fission artwork that captures both its destructive force and potential energy release. Similarly, Britain's Ariel Atom embodies this dynamism with its sleek design and exhilarating speed. Delving deeper into atomic intricacies reveals Immunoglobulin G antibody molecule F007/9894 - a crucial defender against pathogens within our immune system. Its intricate structure mirrors the complexity hidden within every atom. Just as science progresses, so does technology - exemplified by Ariel Atom 500 and its cutting-edge engineering prowess. It pushes boundaries much like artists who depict atomic structures in captivating artworks or scientists who unveil quantized orbits resembling those found in celestial bodies' paths. Peering into helium atoms' electron structures unveils their unique properties while HIV reverse transcription enzyme sheds light on how viruses manipulate genetic material at an atomic level. Finally, we arrive at 2009 Ariel Atom - embodying innovation and evolution just as our understanding of atoms continues to expand exponentially. From enchanting natural phenomena like Northern lights to pioneering research conducted by brilliant minds like Rutherford and Bohr; from artistic interpretations capturing atomic wonders to technological marvels pushing limits – each hint represents a facet of humanity's ceaseless quest to unravel the enigmatic world of atoms.