Atomic Collection (page 7)

Methionine molecule
Methionine, molecular model. Essential alpha-amino acid. Atoms are represented as spheres and are colour-coded: carbon (grey), hydrogen (blue-green), nitrogen (blue), oxygen (red) and sulfur (yellow)

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

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)

Benzoperylene molecular model F007 / 0116
Benzoperylene polycyclic aromatic hydrocarbon (PAH), molecular model. Benzoperylene is an environmental pollutant and suspected to be carcinogenic, mutagenic and teratogenic

Benzoperylene molecular model F007 / 0115
Benzoperylene polycyclic aromatic hydrocarbon (PAH), molecular model. Benzoperylene is an environmental pollutant and suspected to be carcinogenic, mutagenic and teratogenic

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

Mescaline drug molecule
Mescaline, molecular model. Naturally occurring psychedelic alkaloid of the phenethylamine class. Atoms are represented as spheres and are colour-coded: carbon (grey), hydrogen (blue-green)

Ketamine drug molecule
Ketamine, molecular model. Drug used in human and veterinary medicine, generally for the induction and maintenance of general anaesthesia

Histidine molecule
Histidine, molecular model. Essential amino acid in humans and other mammals. One of the 22 proteinogenic amino acids. Atoms are represented as spheres and are colour-coded: carbon (grey)

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)

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

Chain Reaction, computer artwork. C016 / 9204
Chain reaction, artist concept illustration. A chain reaction is a sequence of reactions where a reactive product or by-product causes additional reactions to take place

Atomic clock at an observatory C016 / 7637
Atomic clock. A scientist checking an atomic clock at a radio telescope observatory. There are two clocks shown here, the one on the left (marked zvyezdnoye vryemya ) gives sidereal time

Nanotube structure, artwork C016 / 8889
Nanotube structure. Computer artwork of the structure of a cylindrical nanotube. This molecule is a type of fullerene, a structural type (allotrope) of carbon

Nanotube structure, artwork C016 / 8886
Nanotube structure. Computer artwork of the structure of a cylindrical nanotube. This molecule is a type of fullerene, a structural type (allotrope) of carbon

Nanotube structure, artwork C016 / 8887
Nanotube structure. Computer artwork of the structure of a cylindrical nanotube. This molecule is a type of fullerene, a structural type (allotrope) of carbon

Sodium chloride structure C016 / 8873
Sodium chloride structure, molecular model. Sodium chloride (common salt) consists of a cubic lattice of sodium (small spheres) and chlorine (green) ions and has the chemical formula NaCl

Nanotube structure, artwork C016 / 8890
Nanotube structure. Computer artwork of the structure of a cylindrical nanotube. This molecule is a type of fullerene, a structural type (allotrope) of carbon

Nanotube structure, artwork C016 / 8885
Nanotube structure. Computer artwork of the structure of a cylindrical nanotube. This molecule is a type of fullerene, a structural type (allotrope) of carbon

Nanotube structure, artwork C016 / 8891
Nanotube structure. Computer artwork of the structure of a cylindrical nanotube. This molecule is a type of fullerene, a structural type (allotrope) of carbon

Nanotube structure, artwork C016 / 8883
Nanotube structure. Computer artwork of the structure of a cylindrical nanotube. This molecule is a type of fullerene, a structural type (allotrope) of carbon

Nanotube structure, artwork C016 / 8884
Nanotube structure. Computer artwork of the structure of a cylindrical nanotube. This molecule is a type of fullerene, a structural type (allotrope) of carbon

Orbital space weapons, artwork
Orbital space weapons. Artwork of a ground-based mid-course space missile defence system from around 2000. Projects such as the Strategic Defense Initiative were designed to defend the USA against

Ketamine drug, molecular model. Ketamine is a drug used in human and veterinary medicine, mostly for the induction and maintenance of general anaesthesia

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

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)

Implanting a nuclear pacemaker
Pacemaker. Surgeons implanting a cardiac pacemaker powered by a nuclear battery. The battery contains promethium which decays by releasing beta-particles (electrons)

Control room of Kalinin Power Station
Nuclear power station conttrol room. View across the control room of the Kalininskaya power station, Russia. Kalininskaya has four pressurised water reactors (PWRs), each of 1000 MW capacity

Nanotube structure, artwork C016 / 8533
Nanotube structure. Computer artwork showing a cylindrical nanotube being formed from a sheet of graphene, a single layer of graphite

Nanotube structure, artwork C016 / 8532
Nanotube structure. Computer artwork showing a cylindrical nanotube being formed from a sheet of graphene, a single layer of graphite

Nanotube structure, artwork C016 / 8530
Nanotube structure. Computer artwork of the structure of a cylindrical nanotube. This molecule is a type of fullerene, a structural type (allotrope) of carbon

Nanotube structure, artwork C016 / 8526
Nanotube structure. Computer artwork of the structure of a cylindrical nanotube. This molecule is a type of fullerene, a structural type (allotrope) of carbon

Nanotube structure, artwork C016 / 8531
Nanotube structure. Computer artwork of the structure of a cylindrical nanotube. This molecule is a type of fullerene, a structural type (allotrope) of carbon

Nanotube structure, artwork C016 / 8528
Nanotube structure. Computer artwork of the structure of a cylindrical nanotube. This molecule is a type of fullerene, a structural type (allotrope) of carbon

Nanotube structure, artwork C016 / 8529
Nanotube structure. Computer artwork of the structure of a cylindrical nanotube. This molecule is a type of fullerene, a structural type (allotrope) of carbon

Nanotube structure, artwork C016 / 8524
Nanotube structure. Computer artwork of the structure of a cylindrical nanotube. This molecule is a type of fullerene, a structural type (allotrope) of carbon

Nanotube structure, artwork C016 / 8523
Nanotube structure. Computer artwork of the structure of a cylindrical nanotube. This molecule is a type of fullerene, a structural type (allotrope) of carbon

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

Nanotube structure, artwork C016 / 8521
Nanotube structure. Computer artwork of the interior of a cylindrical nanotube. This molecule is a type of fullerene, a structural type (allotrope) of carbon

Nanotube structure, artwork C016 / 8519
Nanotube structure. Computer artwork of the interior of a cylindrical nanotube. This molecule is a type of fullerene, a structural type (allotrope) of carbon

Nanotube structure, artwork C016 / 8520
Nanotube structure. Computer artwork of the interior of a cylindrical nanotube. This molecule is a type of fullerene, a structural type (allotrope) of carbon

Test of nuclear missile defence C016 / 8405
Nuclear defence. Fireball from the explosion of a Soviet nuclear anti-ballistic missile (ABM) high in the atmosphere. This was a test of the A-35 system

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)

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"Exploring the Atomic Realm: From Northern Lights to Particle Physics Experiments" Step into a world where science and art collide, revealing the wonders of the atomic realm. Just like the mesmerizing dance of the Northern Lights, atomic phenomena continue to captivate our imagination. In 1835, Dalton's Table Symbols laid the foundation for understanding matter at its most fundamental level. This groundbreaking work paved the way for countless discoveries in particle physics experiments, pushing boundaries and unraveling mysteries that were once unimaginable. As we delve deeper into fusion research with devices like tokamaks, we strive to harness the immense power locked within atoms. These scientific endeavors are not just confined to laboratories; they inspire awe-inspiring artworks that depict both beauty and complexity. From nuclear fission artwork depicting energy unleashed to HMS Conqueror's triumphant return after sinking an Argentine battleship during conflict - these moments remind us of how atoms can shape history. The quantized orbits of planets around their suns mirror electron orbits around nuclei – a testament to nature's harmonious patterns on both macroscopic and microscopic scales, and is through this delicate balance that life thrives in our universe. Even seemingly ordinary objects hold atomic secrets. Take an antidepressant molecule like Amitriptyline or an amino acid molecule such as Creatine – they represent breakthroughs in medicine and sports performance respectively, showcasing how atoms impact every aspect of our lives. Yet it is crucial not to overlook darker chapters in history. The haunting fallout from a 1957 nuclear test serves as a stark reminder of humanity's responsibility when dealing with atomic power. And who could forget about innovation? An "Atomic Motorbike" pushes conventional limits by infusing cutting-edge technology with sleek design – a symbol of progress fueled by human ingenuity. So let us embark on this journey through time and space, exploring all facets of what it means to be "atomic.