Atomic Collection (page 8)

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)

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

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)

Buckminsterfullerene molecule C016 / 8266
Buckminsterfullerene molecule. Computer artwork showing the molecular structure of buckminsterfullerene, a structurally distinct form (allotrope)

Carbon nanotubes in POM matrix, SEM C016 / 8042
Carbon nanotubes. Coloured scanning electron micrograph (SEM) of carbon nanotubes in a POM matrix. Carbon nanotubes are a type of fullerene, a structural type (allotrope) of carbon

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)

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)

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)

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

First nuclear submarine Nautilus, artwork
First nuclear submarine. Cut-away computer artwork of USS Nautilus (SS-571), the worlds first operational nuclear-powered submarine

Bushehr nuclear power station, Iran
Iranian nuclear power. Interior of the reactor containment building of the Bushehr nuclear power plant in Iran. Hanging from the ceiling is a fuel rod assembly

String theory, conceptual image C013 / 5638
String theory, conceptual image. Computer artwork representing the superstrings of string theory, a Theory of Everything (Grand Unification Theory)

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

Quark, conceptual model C013 / 5633
Quark, conceptual model. Computer artwork representing the theoretical internal structure of a quark. A quark is an elementary particle and a fundamental constituent of matter

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

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

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

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)

Cuban Missile Crisis of 1962, analysis C016 / 4236
Cuban Missile Crisis. Strategic Air Command (SAC) photo interpreters using a magnifying and mapping machine to examine aerial reconnaissance images of Cuba, obtained in 1962

Cuban Missile Crisis of 1962, aerial view C016 / 4235
Cuban Missile Crisis. Aerial photograph of one of the nuclear missile sites (San Cristobal launch site 2), constructed in Cuba by Soviet forces, that precipitated the Cuban Missile Crisis of 1962

Nuclear warhead being removed C016 / 2696
Arms reduction. The warhead from a RSD-10 Pioneer missile being removed for decommissioning due to an arms reduction agreement

Nano bearing, artwork C013 / 9992
Nano bearing, computer artwork. A bearing allows motion between two or more part. This bearing design is an example of nanotechnology

World War II. Ruined tram by an atomic bombing in Hiroshima (6th August 1945). Photography

All Professionally Made to Order for Quick Shipping

"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.