Atoms Collection (#4)

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

Testosterone hormone molecule. Computer model showing the structure of a molecule of the male sex hormone testosterone. Testosterone is the main human androgen

Progesterone hormone molecule. Computer model showing the structure of a molecule of the hormone progesterone. Progesterone is produced in the ovaries of women and the testes of men

Glyphosate weed killer molecule. Computer model showing the molecular structure of a molecule of the herbicide glyphosate. Glyphosate is a widely used herbicide

Ibuprofen molecule. Computer artwork showing the structure of a molecule of the painkilling (analgesic) drug ibuprofen. Ibuprofen is a non-steroidal anti-inflammatory drug (NSAID)

Graphene sheet. Computer artwork showing the structure of a graphene sheet. Graphene is a single layer of graphite. It is composed of hexagonally arranged carbon atoms (spheres)

Caffeine molecule. Computer artwork showing the structure of a molecule of the alkaloid stimulant and legal drug caffeine. Caffeine is found in drinks such as tea, coffee, and fizzy drinks

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

Aspirin molecule. Computer artwork showing the structure of a molecule of aspirin (acetylsalicylic acid). Atoms are represented as spheres and are colour-coded: carbon (black), hydrogen (white)

Aspirin in action. Computer artwork showing how aspirin has its effect. Aspirin (acetylsalicylic acid) is converted to salicylic acid and acetic acid in the body

Formation of sodium chloride, artwork. At left are sodium (Na) and chlorine (Cl) atoms. At right is a molecule of sodium chloride (NaCl), or salt. This is an example of ionic bonding

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

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

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

Structure of matter, artwork C017 / 8029
Structure of matter. Computer artwork representing the Standard Model of particle physics. Shown here are an atom (left) composed of electrons (blue) orbiting a central nucleus

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)

Zanamivir flu drug, molecular model C016 / 5801
Zanamivir flu drug, molecular model. Zanamivir is an antiviral drug (commonly known by its trade name Relenza). It is administered in spray form for inhalation

Zanamivir flu drug, molecular model C016 / 5800
Zanamivir flu drug, molecular model. Zanamivir is an antiviral drug (commonly known by its trade name Relenza). It is administered in spray form for inhalation

Zanamivir flu drug, molecular model C016 / 5799
Zanamivir flu drug, molecular model. Zanamivir is an antiviral drug (commonly known by its trade name Relenza). It is administered in spray form for inhalation

Zanamivir flu drug, molecular model C016 / 5798
Zanamivir flu drug, molecular model. Zanamivir is an antiviral drug (commonly known by its trade name Relenza). It is administered in spray form for inhalation

Chitin, molecular model C016 / 5797
Chitin. Molecular model of chitin, a long-chain polysaccharide polymer with the repeat unit having the formula C8.H13.O5.N

Chitin, molecular model C016 / 5796
Chitin. Molecular model of chitin, a long-chain polysaccharide polymer with the repeat unit having the formula C8.H13.O5.N

Chitin, molecular model C016 / 5795
Chitin. Molecular model of chitin, a long-chain polysaccharide polymer with the repeat unit having the formula C8.H13.O5.N

Water molecule, artwork C014 / 0007
Water molecule. Computer artwork showing the structure of a molecule of water (chemical formula H2O), consisting of two atoms of hydrogen (grey) bonded to one atom of oxygen (red)

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

Benzene molecule, artwork
Benzene molecule, molecular model. Benzene is an aromatic organic compound that consists of a ring of six carbon atoms, each with an attached hydrogen atom

4-Methylimidazole molecule C013 / 9438
4-Methylimidazole molecule. Computer model showing the structure of a molecule of the heterocyclic organic chemical compound 4-Methylimidazole (4-MEI)

4-Methylimidazole molecule C013 / 9436
4-Methylimidazole molecule. Computer model showing the structure of a molecule of the heterocyclic organic chemical compound 4-Methylimidazole (4-MEI)

Cathinone drug molecule C013 / 7787
Cathinone drug molecule. Computer model showing the structure of a molecule of the monoamine alkaloid drug cathinone (C9H11NO)

Cathinone drug molecule C013 / 7786
Cathinone drug molecule. Computer model showing the structure of a molecule of the monoamine alkaloid drug cathinone (C9H11NO)

Bexarotene chemotherapy drug molecule C013 / 7785
Bexarotene chemotherapy drug molecule. Computer model showing the structure of a molecule of the antineoplastic drug bexarotene (C24H28O2)

Bexarotene chemotherapy drug molecule C013 / 7784
Bexarotene chemotherapy drug molecule. Computer model showing the structure of a molecule of the antineoplastic drug bexarotene (C24H28O2)

Nitrogen-fixing molybdenum iron enzyme C013 / 7176
Nitrogen-fixing molybdenum iron enzyme, molecular model showing secondary structure. This protein is a nitrogen fixation enzyme (nitrogenase)

Boyles law of gases, artwork
Boyles law of gases. Computer artwork explaining the gas laws as described by the combined gas law equation: PV=kT, which shows the relationship between the pressure (P), volume (V)

Combined gas law, artwork C013 / 4731
Combined gas law. Computer artwork explaining the gas laws as described by the combined gas law equation: PV=kT, which shows the relationship between the pressure (P), volume (V)

Pressure-temperature gas law, artwork C013 / 4730
Pressure-temperature gas law. Computer artwork explaining the gas laws as described by the combined gas law equation: PV=kT, which shows the relationship between the pressure (P), volume (V)

Pressure-temperature gas law, artwork C013 / 4729
Pressure-temperature gas law. Computer artwork explaining the gas laws as described by the combined gas law equation: PV=kT, which shows the relationship between the pressure (P), volume (V)

Atmospheric pressure explained, artwork C013 / 4712
Atmospheric pressure explained. Computer artwork of a number of small balls in a glass jar, representing the molecules present in a sample of liquid or gas

Aurora Borealis at night, Finland, february

Aurora Borealis, over coniferous forest at night, Finland, february

Democritean Universe. 17th-century artwork of the atomistic universe proposed by the Ancient Greek philosopher Democritus (c.460-370 BC). The artwork was published in 1675

Caesium atomic clock, 1956
Caesium atomic clock. Physicists Jack Parry (left) and Louis Essen (right) adjusting their caesium resonator, which they developed in 1955

Caesium atomic clock. In this clock, atoms of vapourised caesium-133 oscillate between two energy levels as they pass back and forth between magnets at each end of the resonator (long cylinder)

Panspermia: biomolecules in the universe
Panspermia, conceptual computer artwork. The theory of panspermia states that the molecules that form the building blocks of life are found throughout the universe

Hands holding black hole and stars
Hands holding a black hole and stars, conceptual image

Early history of the universe, artwork
Early history of the universe. Artwork showing the cooling and expansion of the early universe from its origin in the Big Bang (upper left)

Multiple universes, artwork
Multiple universes. Artwork showing multiple universes forming from black holes following the Big Bang formation of the initial universe at top left

Nanohoops, molecular model
Nanohoops. Molecular model of a structure based on fullerenes, a structural form (allotrope) of carbon. Theoretically, a wide range of molecular shapes can be engineered at the molecular level using

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"Unveiling the Mysteries of Atoms: From Northern Lights to Quantum Marvels" Witness the captivating dance under the shimmering Northern lights, a celestial spectacle that mirrors their intricate nature. Niels Bohr, a pioneer in atomic theory, immortalized through a whimsical caricature capturing his profound contributions to our understanding of atoms. Behold the explosive beauty of nuclear fission artwork, showcasing the immense power harnessed within tiny atomic nuclei. Delve into the microscopic world as we explore HIV reverse transcription enzyme—a remarkable atom-driven process crucial for viral replication. Ernest Rutherford's genius encapsulated in an amusing caricature, symbolizing his groundbreaking experiments that unraveled atomic structure. Embark on an artistic journey depicting the evolution of our universe—where atoms play a pivotal role in shaping cosmic wonders beyond imagination. Witness the exhilarating collision between particles—an awe-inspiring event revealing hidden secrets about matter and energy at its most fundamental level. Step into a simulated realm where Bose-Einstein condensate defies conventional physics—unleashing mind-bending phenomena like superfluidity and quantum coherence. Discover oxytocin—the enchanting neurotransmitter molecule responsible for bonding and affection, reminding us how atoms shape human emotions and connections. Explore density within a Bose-Einstein condensate—a surreal state where atoms merge into one entity with extraordinary properties yet to be fully understood by science. Bonus: Dive into "When The Atoms Failed, " an intriguing cover story from Amazing Stories Scifi magazine—transporting readers to alternate realities shaped by unexpected atomic anomalies. Witness nature's own masterpiece as Aurora Borealis illuminates a snowy coniferous forest in Northern Finland—a breathtaking reminder of how atoms interact with Earth's magnetic field to create this ethereal phenomenon during March nights.