Nanotechnology Collection (page 6)

MEMS production, chemical etching
MODEL RELEASED. MEMS production. Clean room technicians using chemical etching processes to produce MEMS (microelectromechanical systems) devices

Medical nanorobots. Computer artwork of medical nanorobots and red blood cells in a human body. Microscopic robot technology could be developed in the future to treat diseases in new ways

Nano submarine. Conceptual computer artwork of a nano submarine in an artery. Nanotechnology could revolutionise many fields of science from manufacturing to surgery

MEMS production, device sorting
MODEL RELEASED. MEMS production. Tweezers being used by a clean room technician to sort MEMS (microelectromechanical systems) devices into waffle-box storage containers

Nanotechnology dust mote. Computer artwork of a nanomachine clinging to a dust mote, demonstrating the concept of Smart Dust

MEMS production, support bonding
MEMS production. Microscope apparatus being used to mount MEMS (microelectromechanical systems) devices onto support structures

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

Nanotechnology machines, computer artwork. Future uses of nanotechnology (machines the size of cells and molecules) could range from using nanomachines to repair the body and target diseases

MEMS production, thin film deposition
MODEL RELEASED. MEMS production. Clean room technician using a thin film deposition machine to produce MEMS (microelectromechanical systems) devices

MEMS production, plasma etching
MODEL RELEASED. MEMS production. Clean room technicians using plasma etching techniques to produce MEMS (microelectromechanical systems) devices

Nanorobots with human embryo, computer artwork. Nanorobots is a term used to describe future microscopic robots that could have a wide range of uses

MEMS production, gold metal circuitry
MEMS production. Wafer on which gold metal has been deposited to form electronic circuitry for MEMS (microelectromechanical systems) devices

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

Nanorobots killing bacteria
Medical nanorobots. Computer artwork of nanorobots killing bacteria (red). These microscopic robots are a future technology that could be developed to help treat diseases

Molecular engineering. Computer artwork of a constructed molecular device, an example of possible future nanotechnology. This device includes wheels (lower left and lower right)

Foglets, conceptual image. Foglets linking arms to eventually create a Utility Fog. A Foglet is currently a concept based around an artificially intelligent nanorobot with twelve arms pointing in all

Nanorobots with pollen
Nanorobots. Computer artwork of nanorobots with pollen. The nanorobots are light enough to float in liquids or air with the pollen, and could be spread in similar ways

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

Nanotechnology simulators. Computer artwork of identical nanomachines linking together to form a structure. Trillions of these nanomachines (called foglets)

MEMS production, wafer cutting
MEMS production. Machine being used to cut up a silicon wafer of MEMS (microelectromechanical systems) devices. The liquid provides lubrication during the cutting process

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

Musclebots, computer artwork. Scientists in California, USA have created microscopic machines from heart muscle grown in rat cells. The muscle is attached to a layer of gold

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

Nanorobots, computer artwork. Nanotechnology is an area of science concerned with producing mechanical entities on the scale of nanometres (billionths of a metre)

MEMS production, machined silicon wafer
MODEL RELEASED. MEMS production. Machined silicon wafer being used for MEMS (microelectromechanical systems) devices, being held by a clean room technician

Nanorobot on hair
Nanorobot repairing a strand of hair with a laser, computer artwork

MEMS production, photolithography
MODEL RELEASED. MEMS production. Clean room technicians using photolithography processes to produce MEMS (microelectromechanical systems) devices

MEMS production, hot embossing
MEMS production. Hot embossing machine being used to produce MEMS (microelectromechanical systems) devices. MEMS devices are constructed on a microscopic scale using technologies such as wet

MEMS production, quality control
MEMS production. Microscope being used to carry out quality control checks on a silicon wafer of MEMS (microelectromechanical systems) devices

MEMS production, flip chip bonding
MEMS production. Flip chip bonding apparatus (lower right) being used to mount MEMS (microelectromechanical systems) devices

Nano surgery. Conceptual computer artwork of nano robotic spiders repairing an eye. Nanotechnology could revolutionise many fields of science from manufacturing to surgery

Universal joint, computer model. This mechanical joint design, made entirely from carbon (turquoise) and hydrogen (grey) atoms, is an example of nanotechnology

Nanorobot. Computer artwork of a centipede-like nanorobot. Nanorobots is a term used to describe future microscopic robots that could have a wide range of uses

MEMS production, external connections
MEMS production. Bonding machine and microscope being used to add the external connections to MEMS (microelectromechanical systems) devices

MEMS production
MODEL RELEASED. MEMS production. Clean room technician lifting a container of silicon wafers being used to produce MEMS (microelectromechanical systems) devices

Quantum dot probe, artwork
Quantum dot probe. Computer artwork of a quantum dot, a nanocrystal (InAs crystal, orange) that can be used to probe the immune system

Twisted nanotube, molecular model
Twisted nanotube. Molecular model of a structure based on fullerenes, a structural form (allotrope) of carbon. Theoretically

Nanorobot on circuit board
Nanorobot. Computer illustration of a nanorobot on a circuit board. This tiny robot could monitor the circuit, repairing any defects as they develop

Nanophage
Nanotechnology virus. Conceptual computer artwork of an artificial virus created with nanotechnology. Nanotechnology is the branch of engineering concerned with constructing devices at the molecular

Medical nanorobots on red blood cell
Medical nanorobots. Computer artwork of medical nanorobots on red blood cells inside a human body. Microscopic robot technology could be developed in the future to treat diseases in new ways

Electronic wasp. Conceptual computer artwork of a wasp with a circuit board implanted in its body. This could represent bioengineering or nanotechnology

Miniature thermal conductivity detector. Coloured scanning electron micrograph of a detector that can be used to measure thermal conductivity of gases

Military nanorobots

Microcogs (image 1 of 3). Coloured scanning electron micrograph (SEM) of microcogs forming a microgear mechanism. This could be used in a micromachine, or MicroElectroMechanical System (MEMS)

Medical nanorobot on sperm cell
Medical nanorobot. Computer artwork of a medical nanorobot holding a sperm cell. Microscopic robot technology could be developed in the future to treat disorders, such as infertility, in new ways

Coloured SEM of an array of micromotor gears

Microscopic pressure sensor. Coloured scanning electron micrograph (SEM) of a tiny pressure sensor. The circular area at the centre of the sensor rests on a membrane that allows it to measure

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Nanotechnology, the groundbreaking field of science that operates at the atomic and molecular level, continues to astound us with its limitless potential. Imagine a swarm of nanorobots working tirelessly inside our bodies, repairing damaged cells and combating diseases. This futuristic concept comes alive through mesmerizing artwork depicting these tiny marvels in action. One such masterpiece showcases nanotube technology, where intricate structures resembling microscopic tubes hold immense promise for various applications. Another captivating artwork portrays nanorobots delicately maneuvering on a pinhead, highlighting their astonishing precision and agility. Graphene steals the spotlight as an extraordinary material with unparalleled strength and conductivity. An awe-inspiring depiction of a graphene sheet captivates viewers, showcasing its remarkable properties that revolutionize industries ranging from electronics to energy storage. The integration of carbon nanotubes into this realm further expands possibilities. Conceptual artwork envisions how these incredible structures could shape future technologies by enhancing materials' performance or enabling advanced electronic devices. Intriguingly, nanotechnology even offers hope for DNA repair using tiny yet powerful nanobots designed specifically for this purpose. Imaginative illustrations depict these minuscule machines precisely targeting damaged genetic material within our cells—a testament to human ingenuity pushing boundaries beyond imagination. But it doesn't stop there; battling cancer becomes more promising when we witness a brave little nanorobot attacking malignant cells in another captivating piece of art. The potential breakthroughs in targeted therapies bring renewed optimism in the fight against this devastating disease. And finally, self-replicating nanobots take center stage through thought-provoking artwork that explores their ability to reproduce autonomously—opening doors to unimaginable advancements across numerous fields. As we delve deeper into the world of nanotechnology, we are left awestruck by its transformative power and boundless opportunities it presents for humanity's progress.