Atom Collection (page 14)

Phospholipids in a membrane, artwork
Phospholipids in a membrane. Computer artwork showing a row of phospholipid molecules in a cell membrane. Phospholipids consist of a phosphate group head (top)

Phospholipid molecule, artwork
Phospholipid molecule. Computer artwork showing the structure of a phospholipid molecule. Phospholipids consist of a phosphate group head (top) and a fatty acid hydrophobic ( water-hating ) tail

Buckminsterfullerene molecule C016 / 8354
Buckminsterfullerene molecule. Computer artwork showing the molecular structure of buckminsterfullerene, a structurally distinct form (allotrope) of carbon that has 60 carbon atoms (black)

ITER Fusion Research Reactor C016 / 9201
Artists concept view of the interior of the ITER reaction vessel. Nuclear fusion involves creating a plasma of superheated gas to temperatures of more than 200 million degrees C

Nanotube structure, artwork C016 / 8888
This image may not be used in educational posters Nanotube structure. Computer artwork of the structure of a cylindrical nanotube

Molecular structure, conceptual artwork C016 / 7534
Molecular structure, conceptual computer artwork

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

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

Water molecules, artwork C017 / 7384
Water molecules. Computer artwork showing the molecular (top) and atomic (bottom) structure of water (H2O). Atoms are colour-coded: hydrogen (blue) and oxygen (white)

Ionic bonding in sodium chloride, artwork C017 / 7243
Ionic bonding in sodium chloride. Computer artwork showing the formation (top) of sodium chloride (common salt) and a model of the cubic crystal lattice (bottom) created by this chemical reaction

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)

Particle rays, artwork C014 / 2579
Conceputal computer artwork of rays emitting particles. This could depict travel near the speed of light, cosmic rays, particle emitters, particle tracks, particle accelerators or big bang e.g

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

Peptide YY obesity hormone molecule C014 / 4911
Peptide YY obesity hormone molecule. Computer model showing the crystal structure of a molecule of the hormone peptide YY (PYY, or PYY3-36)

Peptide YY obesity hormone molecule C014 / 4910
Peptide YY obesity hormone molecule. Computer model showing the crystal structure of a molecule of the hormone peptide YY (PYY, or PYY3-36)

Cholecystokinin-8 molecule C014 / 4895
Cholecystokinin-8 molecule. Computer model showing the structure of the terminal fragment of a molecule of the hormone cholecystokinin-8 (CCK-8)

Activated ghrelin hormone molecule C014 / 4902
Activated ghrelin hormone molecule. Computer model showing the crystal structure of the human hormone ghrelin. The crystal structure consists of both the secondary structure

Activated ghrelin hormone molecule C014 / 4903
Activated ghrelin hormone molecule. Computer model showing the structure of the human hormone ghrelin. Atoms are colour-coded spheres (carbon: grey, oxygen: red, nitrogen: blue)

Obestatin molecule C014 / 4908
Obestatin molecule. Computer artwork showing the structure of a molecule of obestatin. Obestatin is thought to supress hunger and reduce food intake, thereby reducing weight gain

Obestatin molecule C014 / 4909
Obestatin molecule. Computer artwork showing the structure of a molecule of obestatin. Obestatin is thought to supress hunger and reduce food intake, thereby reducing weight gain

Cholecystokinin-8 molecule C014 / 4894
Cholecystokinin-8 molecule. Computer model showing the structure of the terminal fragment of a molecule of the hormone cholecystokinin-8 (CCK-8)

Activated ghrelin hormone molecule C014 / 4901
Activated ghrelin hormone molecule. Computer model showing the crystal structure of the human hormone ghrelin. The crystal structure consists of both the secondary structure

Paracetamol molecule
Serotonin molecule. Computer model showing the structure of a molecule of the neurotransmitter (nerve signalling chemical) serotonin (5-hydroxytryptamine)

Nanotube structure, artwork C016 / 8522
This image may not be used in educational posters Nanotube structure. Computer artwork of the interior of a cylindrical nanotube

Carbon dioxide molecules C016 / 8495
Carbon dioxide molecules. Computer artwork showing the structure of a molecule of carbon dioxide. Carbon dioxide is a colourless gas that occurs naturally in the atmosphere

Carbon dioxide molecule C016 / 8494
Carbon dioxide molecule. Computer artwork showing the structure of a molecule of carbon dioxide. Carbon dioxide is a colourless gas that occurs naturally in the atmosphere

Carbon dioxide molecule C016 / 8493
Carbon dioxide molecule. Computer artwork showing the structure of a molecule of carbon dioxide. Carbon dioxide is a colourless gas that occurs naturally in the atmosphere

Buckminsterfullerene molecule C016 / 8372
Buckminsterfullerene molecule. Computer artwork showing the molecular structure of buckminsterfullerene, a structurally distinct form (allotrope) of carbon that has 60 carbon atoms (spheres)

Buckminsterfullerene molecule C016 / 8370
Buckminsterfullerene molecule. Computer artwork showing the molecular structure of buckminsterfullerene, a structurally distinct form (allotrope) of carbon that has 60 carbon atoms (spheres)

Buckminsterfullerene molecule C016 / 8368
Buckminsterfullerene molecule. Computer artwork showing the molecular structure of buckminsterfullerene, a structurally distinct form (allotrope) of carbon that has 60 carbon atoms (spheres)

Buckminsterfullerene molecule C016 / 8369
Buckminsterfullerene molecule. Computer artwork showing the molecular structure of buckminsterfullerene, a structurally distinct form (allotrope) of carbon that has 60 carbon atoms (spheres)

Buckminsterfullerene molecule C016 / 8364
Buckminsterfullerene molecule. Computer artwork showing the molecular structure of buckminsterfullerene, a structurally distinct form (allotrope) of carbon that has 60 carbon atoms (spheres)

Buckminsterfullerene molecule C016 / 8367
Buckminsterfullerene molecule. Computer artwork showing the molecular structure of buckminsterfullerene, a structurally distinct form (allotrope) of carbon that has 60 carbon atoms (spheres)

Buckminsterfullerene molecule C016 / 8363
Buckminsterfullerene molecule. Computer artwork showing the molecular structure of buckminsterfullerene, a structurally distinct form (allotrope) of carbon that has 60 carbon atoms (spheres)

Buckminsterfullerene molecule C016 / 8361
Buckminsterfullerene molecule. Computer artwork showing the molecular structure of buckminsterfullerene, a structurally distinct form (allotrope) of carbon that has 60 carbon atoms (orange)

Buckminsterfullerene molecule C016 / 8362
Buckminsterfullerene molecule. Computer artwork showing the molecular structure of buckminsterfullerene, a structurally distinct form (allotrope) of carbon that has 60 carbon atoms (orange)

Buckminsterfullerene molecules C016 / 8359
Buckminsterfullerene molecules. Computer artwork showing the molecular structure of buckminsterfullerene, a structurally distinct form (allotrope) of carbon that has 60 carbon atoms (black)

Buckminsterfullerene molecule C016 / 8358
Buckminsterfullerene molecule. Computer artwork showing the molecular structure of buckminsterfullerene, a structurally distinct form (allotrope) of carbon that has 60 carbon atoms (black)

Buckminsterfullerene molecule C016 / 8357
Buckminsterfullerene molecule. Computer artwork showing the molecular structure of buckminsterfullerene, a structurally distinct form (allotrope) of carbon that has 60 carbon atoms (black)

Buckminsterfullerene molecule C016 / 8351
Buckminsterfullerene molecule. Computer artwork showing the molecular structure of buckminsterfullerene, a structurally distinct form (allotrope) of carbon that has 60 carbon atoms (dark blue)

Carbon nanotube, artwork C016 / 8270
Carbon nanotube. Computer artwork of the inside of a carbon nanotube, also known as a buckytube, showing the hexagonal carbon structure

Carbon nanotube, artwork C016 / 8269
Carbon nanotube. Computer artwork of the inside of a carbon nanotube, also known as a buckytube, showing the hexagonal carbon structure

Vitamin B1 molecule C016 / 8278
Vitamin B1 molecule. Computer model showing the structure of a molecule of vitamin B1 (thiamine). Atoms are represented as colour-coded spheres: carbon (light blue), hydrogen (white)

Vitamin B1 molecule C016 / 8277
Vitamin B1 molecule. Computer model showing the structure of a molecule of vitamin B1 (thiamine). Vitamin B1 is an essential nutrient that humans are unable to produce

Vitamin B1 molecule C016 / 8276
Vitamin B1 molecule. Computer model showing the structure of a molecule of vitamin B1 (thiamine). Vitamin B1 is an essential nutrient that humans are unable to produce

Vitamin B1 molecule C016 / 8275
Vitamin B1 molecule. Computer model showing the structure of a molecule of vitamin B1 (thiamine). Vitamin B1 is an essential nutrient that humans are unable to produce

Carbon nanotube, artwork C016 / 8271
Carbon nanotube. Computer artwork of a carbon nanotube, also known as a buckytube, showing the hexagonal carbon structure. Atoms are represented as spheres and the bonds between them by rods

Buckminsterfullerene molecule C016 / 8268
Buckminsterfullerene molecule. Computer artwork showing the molecular structure of buckminsterfullerene, a structurally distinct form (allotrope)

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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.