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Computer chip implants Conceptual computer artwork of an anatomical model of a human face with several computer chip implants In the future microme
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Nanospheres computer artwork
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Nanospheres computer artwork
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Nanospheres computer artwork
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Twisted nanotube Molecular model of a structure based on fullerenes a structural form (allotrope) of carbon Theoretically a wide range of molecula
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Nanohoops Molecular model of a structure based on fullerenes a structural form (allotrope) of carbon Theoretically a wide range of molecular shape
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Nanohoops Molecular model of a structure based on fullerenes a structural form (allotrope) of carbon Theoretically a wide range of molecular shape
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Gold nanoparticles SEM
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Zinc oxide nanowires SEM
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A researcher gives life to Genghis a robot insect made by the Massachusetts Institute of Technology (MIT) USA The Mobile Robot laboratory at MIT
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Zinc oxide nanowires SEM
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Thermoelectric silicon nanowire Computer artwork showing a silicon nanowire (centre) bridging two heating pads (top and bottom) One heating pad serv
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Gallium nitride nanotubes TEM
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Nanowire tweezers Computer artwork showing nanowires (grey cylinders) surrounded by an electric field (red and yellow) The electric field known as
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Gallium nitride nanowires SEM
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Silicon nanowire device held by tweezers
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Nanowire solar cell
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Nanowire solar cell
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Silicon hardness test coloured AFM
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Genghis a robot insect made at the Massachusetts Institute of Technology (MIT) USA The Mobile Robot laboratory at MIT has produced several such r
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Nanopollution artwork
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Silicon hardness test 3D Raman map
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Silicon hardness test 3D Raman map
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MEMS production furnace processing
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MEMS production quality control
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MEMS production quality control
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MEMS production quality control
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MEMS production quality control
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MEMS production metal evaporation
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A researcher holding a robot gnat at the Massachusetts Institute of Technology (MIT) USA This is the smallest of the robot insects so far produced
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MEMS production metal evaporation
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MEMS production plasma etching
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MODEL RELEASED MEMS production Clean room technician using a photolithography machine to produce MEMS (microelectromechanical systems) devices MEMS
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MEMS production photolithography
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MODEL RELEASED MEMS production Tweezers being used by a clean room technician to place a MEMS (microelectromechanical systems) device on a microscop
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MODEL RELEASED MEMS production Clean room technician using a scanning electron microscope to carry out solder bump analysis on a MEMS (microelectr
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MEMS production Carrying case containing silicon wafers that are being used to produce MEMS (microelectromechanical systems) devices The wafers will
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MEMS production
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MEMS production quality control
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Medical nanorobot Computer artwork of a nanorobot using a laser to destroy a bacterium inside a blood vessel In the future such micromechanical nan
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MEMS production quality control
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MEMS production Machined silicon wafer being used to produce MEMS (microelectromechanical systems) devices The wafer has been machined and will now
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MEMS production machined silicon wafer
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MEMS production plasma etching
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MEMS production hot embossing
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MODEL RELEASED MEMS production Clean room technicians using photolithography processes to produce MEMS (microelectromechanical systems) devices MEM
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MEMS production photolithography
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MODEL RELEASED MEMS production Clean room technician using photolithography processes to produce MEMS (microelectromechanical systems) devices MEMS
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MEMS production chemical etching
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Examining microdevice Technician inspecting a microelectromechanical system (MEMS) with an interference microscope (surface profiler) MEMS are ele
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MEMS production chemical etching
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MEMS production thin film deposition
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MEMS production Bonding machine and microscope being used to add the external connections to MEMS (microelectromechanical systems) devices MEMS devi
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MEMS production external connections
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MODEL RELEASED MEMS production Machined silicon wafer being used for MEMS (microelectromechanical systems) devices being held by a clean room techn
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MEMS production gold metal circuitry
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MEMS production wafer cutting
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MODEL RELEASED MEMS production Tweezers being used by a clean room technician to sort MEMS (microelectromechanical systems) devices into waffle-box
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MEMS production support bonding
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Fly with video camera Conceptual computer artwork of a fly with a camera mounted on its back This could represent undercover video surveillance par
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MEMS production Microscope apparatus being used to mount MEMS (microelectromechanical systems) devices onto support structures MEMS devices are cons
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MEMS production flip chip bonding
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MEMS production flip chip bonding
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Universal joint computer model
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Molecular bearing computer model This bearing design is an example of nanotechnology Each sphere represents an individual atom and is colour-coded
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Nanoindenter for hardness testing
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Nanoindenter for hardness testing
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Nanoindenter for hardness testing
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Nanoprobe system
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Scanning tunnelling microscope Scanning electron micrograph of the needle of a scanning tunnelling microscope (STM) The micromechanical STMs needle
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Nanoprobe system
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Dragonfly and MEMS silicon plate The MEMS (microelectromechanical systems) devices are etched onto the silicon plate (blue) MEMS devices are mechani
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MEMS production Equipment being used in the manufacture of MEMS (microelectromechanical systems) devices on a silicon plate (purple) MEMS devices ar
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MEMS production quality control
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MEMS production Clean room technician using a microscope to examine a silicon MEMS plate (circular) as part of the quality control process for manufa
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MEMS production Clean room technician examining a computer display as part of the quality control process for manufacturing MEMS (microelectromechani
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MEMS production Clean room technician holding a silicon plate being used to make MEMS (microelectromechanical systems) devices MEMS devices are mech
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MEMS production Clean room technician holding a silicon plate being used to make MEMS (microelectromechanical systems) devices MEMS devices are mech
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MEMS production Clean room technician removing a silicon plate from a furnace as part of the process of producing MEMS (microelectromechanical system
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Micromechanical gears Coloured scanning electron micrograph (SEM) of tiny gears that increase the torque of a micromechanical motor These gears have
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MEMS production silicon furnace
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MEMS production silicon plate mask
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Microelectromechanical device SEM
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Microelectromechanical device coloured scanning electron micrograph (SEM) This is a sensor gauge that moves along the scale at right from which a r
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Microelectromechanical device coloured scanning electron micrograph (SEM) These circular components have been constructed on a piece of silicon MEM
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MEMS microscopy Researchers examining a scanning electron micrograph (SEM) of a silicon plate containing MEMS (microelectromechanical systems) device
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MEMS microscopy Scanning electron micrograph (SEM) electrodes being used to scan a silicon plate containing MEMS (microelectromechanical systems) dev
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Microelectromechanical device
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Weevil and MEMS device coloured scanning electron micrograph (SEM) MEMS (microelectromechanical systems) are mechanical and electrical devices const
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Micromechanical gears Coloured scanning electron micrograph (SEM) of an interlocking array of micromotor gears This device is geared to increase the
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Dragonfly microdrone research
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Dragonfly microdrone research
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Medical nanorobot Computer artwork of a nanorobot in a blood vessel It is removing a deposit on the vessel wall This could be an atheroma a fatty
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Medical nanorobot Computer artwork of a nanorobot in a blood vessel It is removing a deposit on the vessel wall This could be an atheroma a fatty
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Medical nanorobot Computer artwork of a nanorobot and red blood cells (erythrocytes) In the future microscopic robots such as these could be used t
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Medical nanorobot Computer artwork of a nanorobot in a blood vessel It is removing a deposit on the vessel wall This could be an atheroma a fatty
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Nano submarine Conceptual computer artwork of a nano submarine in an artery Nanotechnology could revolutionise many fields of science from manufactu
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Medical nanorobot Computer artwork of a nanorobot and red blood cells (erythrocytes) In the future microscopic robots such as these could be used t
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Nano surgery Conceptual computer artwork of nano robotic spiders repairing an eye Nanotechnology could revolutionise many fields of science from man
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Micromechanical tuning fork Coloured scanning electron micrograph (SEM) of a micromechanical device that acts as a tiny tuning fork It has been made
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