Nanoscale Collection

Green I
Ben Rea

High-contrast direct DNA image, TEM
High-contrast direct DNA image. Coloured transmission electron micrograph (TEM) of the first high-contrast direct image of a bundle (fibre) of strands of DNA (deoxyribonucleic acid)

DNA bundle on silicon nanopillars, SEM
DNA bundle on silicon nanopillars. Scanning electron micrograph (SEM) of a DNA (deoxyribonucleic acid) bundle and silicon nanopillars used to obtain the first high-contrast direct images of DNA

Self-assembled DNA triangle C015 / 5423
Self-assembled DNA triangle. Molecular model of DNA (deoxyribonucleic acid) strands forming what is called a tensegrity triangle

Self-assembled DNA triangle C015 / 5422
Self-assembled DNA triangle. Molecular model of DNA (deoxyribonucleic acid) strands forming what is called a tensegrity triangle

Atomic processing microscopy C016 / 3817
Atomic processing microscopy. Researcher operating an atomic processing microscope (APM). This device is being used to carry out nanoscale characterization of solid-state materials

Gallium nitride nanowires, SEM
Gallium nitride nanowires, coloured scanning electron micrograph (SEM). Nanowires, seen here grown in square plots, are artificially grown crystal filaments that measure only a few nanometres

Silicon nanowire device, held by tweezers. This device is coated with billions of tiny nanowires, each measuring a few nanometres (billionths of a metre) in diameter

Zinc oxide nanowires, SEM
Zinc oxide nanowires, coloured scanning electron micrograph (SEM). Nanowires are artificially grown crystal filaments that measure only a few nanometres (billionths of a metre) in diameter

Thermoelectric silicon nanowire, artwork
Thermoelectric silicon nanowire. Computer artwork showing a silicon nanowire (centre) bridging two heating pads (top and bottom)

Nanowire solar cell. This solar cell is coated with billions of tiny nanowires, each measuring 60 nanometres (billionths of a metre) in diameter and 20 micrometres (thousandths of a metre) in length

Nanowire tweezers, computer artwork
Nanowire tweezers. Computer artwork showing nanowires (grey cylinders) surrounded by an electric field (red and yellow). The electric field, known as an optoelectronic tweezer

Nano-bearing, artwork
Artwork of a nano-bearing, a nanotechnology device created at the atomic scale. A bearing allows motion between two or more parts, and here one circular element is seen inside another

Nano hoop, artwork
Artwork of a nano hoop, a tiny circular molecule created at the atomic scale by nanotechnology. Individual atoms are the round structures

Nano gearbox, artwork
Artwork of a nano gearbox, a nanotechnology device created at the atomic scale. A gearbox uses gears in a rolling element to accelerate movement

DNA crystal lattice. Computer model showing the crystal structure of a DNA (deoxyribonucleic acid) lattice. The lattice is built of small 3D triangular DNA subunits

Nano ball-bearing, artwork
Artwork of a nano ball-bearing, a nanotechnology device created at the atomic scale. A ball bearing is a rolling element that uses balls to maintain separation between moving parts

Nanobot replication. Self-contained nanobots replicating in a factory. Nanotechnology involves the use of current and future technology to build microscopically small probes

Scanner for characterising surfaces
Nanoscale engineering. View of a NanoScan device, used to characterise the surface of a material on a tiny scale. The scanner can measure the surface shape

DNA Crystal nanoscale crystal structure
DNA crystal nanoscale crystal structure designed by Nadrian Seeman, showing a crystal structure of a DNA lattice (PDB 3gbi)

Superconductor surface, STM
Superconductor surface. Coloured scanning tunnelling micrograph (STM) of the surface of a bismuth strontium calcium copper oxide (BSCCO) superconductor on an atomic scale

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"Nanoscale: Unveiling the Quantum Computer Core and Green I in High-Contrast Direct DNA Images" Step into the fascinating world of nanoscale, where groundbreaking discoveries await. Witness the marvels of technology as we delve into the intricate realm of quantum computing. Behold, the Quantum Computer Core, a mesmerizing creation that holds immense potential for revolutionizing our digital landscape. In this captivating journey, we encounter vibrant hues with Green I illuminating our path. Its radiant glow signifies progress and innovation in nanotechnology research. As we explore further, prepare to be astounded by high-contrast direct DNA images captured through Transmission Electron Microscopy (TEM). These breathtaking visuals offer unprecedented clarity, revealing intricate details at an unimaginably small scale. The TEM continues to amaze us as it presents multiple high-contrast direct DNA images; each snapshot showcases the remarkable complexity and beauty hidden within our genetic blueprint. The delicate strands intertwine like an elegant dance, unveiling secrets that have captivated scientists for generations. Moving on from TEM to Scanning Electron Microscopy (SEM), we stumble upon another awe-inspiring sight – DNA bundles resting atop silicon nanopillars. This unique arrangement highlights how nature's building blocks can interact seamlessly with artificial structures. A testament to human ingenuity merging harmoniously with biological wonders. But wait. Our exploration doesn't end here; behold the Self-assembled DNA triangle C015/5423 – a true masterpiece crafted by harnessing self-assembly techniques at the nanoscale level. This stunning structure showcases not only scientific prowess but also hints at endless possibilities for future applications in various fields such as medicine or materials science. Nanoscale beckons us towards uncharted territories where imagination meets reality. It invites us to witness extraordinary breakthroughs that push boundaries beyond what was once deemed possible. So come along on this incredible journey and let your mind expand alongside these infinitesimally small wonders that hold immense potential for our future.