Semiconductor Collection

Microchip connecting wire, SEM
Micro-wire. Coloured scanning electron micrograph (SEM) of a micro-wire (yellow, often made of gold) connecting to the surface of a microchip

Czochralski silicon crystal growth
Silicon crystal growth. Artwork showing the industrial Czochralski process used to grow silicon crystals. Polycrystalline silicon (top left)

Male human head with skull and artificial electronic circuit brain in ghost effect, side view

Semiconductor wafer, artwork F007 / 9912
Computer enhanced image of a part of a semiconductor wafer. Wafers are divided up into blocks to make the integrated circuits ( chips ) used in electronic devices

Solar cell F008 / 4434
Solar cell. Close-up of a high performance solar cell made from a monocrystalline silicon wafer. The contact grid is made from busbars (large strip) and fingers (small strips)

Solar cell F008 / 4431
Solar cell, computer enhanced image. High performance solar cell made from a monocrystalline silicon wafer. The contact grid is made from busbars (larger vertical strips)

Solar cell F008 / 4428
Solar cell. Close-up of a high performance solar cell made from a monocrystalline silicon wafer. The contact grid is made from busbars (large strip) and fingers (small strips)

Light-emitting diode, SEM
Light-emitting diode (LED), coloured scanning electron micrograph. This is a semiconductor that emits light when a current passes through it

Solar cell F008 / 4437
Solar cell, computer enhanced image. Close-up of a high performance solar cell made from a monocrystalline silicon wafer. The contact grid is made from busbars (larger vertical strips)

Solar cell F008 / 4438
Solar cell. High performance solar cell made from a monocrystalline silicon wafer. The contact grid is made from busbars (larger vertical strips) and fingers (small horizontal strips)

Microchip surface, SEM
Microchip surface. Coloured scanning electron micrograph (SEM) of a few of the many tracks that are etched on the surface of a microchip

Solar cell F008 / 4433
Solar cell. Close-up of a high performance solar cell made from a monocrystalline silicon wafer. The contact grid is made from busbars (large strip) and fingers (small strips)

Solar cell F008 / 4439
Solar cell. Computer enhanced close-up of a high performance solar cell made from a monocrystalline silicon wafer. The contact grid is made from busbars (large strip) and fingers (small strips)

Futuristic computing technology, artwork F006 / 8667
Futuristic computing technology, computer artwork

Circuit board F006 / 8593
Circuit board

Solar cell C016 / 9016
Solar cell. Close-up of the surface of a solar (photovoltaic) cell, which converts light into electrical energy. The cell is made from silicon (blue), a semi-conductor

Solar cell C016 / 9019
Solar cell. Close-up of the surface of a solar (photovoltaic) cell, which converts light into electrical energy. The cell is made from silicon (blue), a semi-conductor

Solar cell C018 / 6405
Solar (photovoltaic) cell, which converts light into electrical energy. The cell is made from silicon (blue), a semi-conductor

Solar cell C018 / 6396
Solar (photovoltaic) cell, which converts light into electrical energy. The cell is made from silicon (blue), a semi-conductor

Solar cell C018 / 6388
Computer enhanced image of a solar (photovoltaic) cell, which converts light into electrical energy. The cell is made from silicon (blue), a semi-conductor

Solar cell, monocrystalline, Micrograph C018 / 6392
Solar cell. Light micrograph taken with episcopic lighting and Normarski Interference Contrast (DIC) of of a high performance solar cell made from a monocrystalline silicon wafer

Silicon wafer production, artwork
Silicon wafer production. Cutaway artwork showing the apparatus used to polish silicon wafers. Silicon used in microchips needs to be precisely engineered for structure and purity

Float-zone silicon crystal growth
Silicon crystal growth. Artwork showing the float-zone process used to grow silicon crystals, an alternative to the Czochralski process (C014/7163)

Organic light emitting diode, artwork
Organic light emitting diode. Computer artwork showing the layered structure of an organic light emitting diodes (OLED). These ultra-thin polymer semi-conductors are light emitting diodes (LEDs)

Black silicon, SEM C015 / 5826
Black silicon. Coloured scanning electron micrograph showing the surface structure of black silicon. This is a modified form of silicon whose surface is covered with monocrystalline silicon needles

Black silicon, SEM C015 / 5825
Black silicon. Coloured scanning electron micrograph showing the surface structure of black silicon. This is a modified form of silicon whose surface is covered with monocrystalline silicon needles

Electro-optical laser characterization C016 / 3811
Electro-optical laser characterization. Femtosecond laser being used to characterize the electrical and optical properties of semiconductor and solid-state materials

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"Unveiling the Intricate World of Semiconductors: Where Microchips and Artificial Intelligence Converge" Exploring the intricate web of connectivity, microchip connecting wires form a complex network that powers our digital world. Delving into the depths of innovation, a male human head with a skull reveals an artificial electronic circuit brain - a testament to the incredible advancements in semiconductor technology. A mesmerizing sight unfolds as we gaze upon a semiconductor wafer, artwork F007 / 9912, where countless microscopic components come together to create powerful computing devices. Harnessing the power of sunlight, solar cells like F008 / 4434 convert this abundant energy source into clean electricity for sustainable living. The beauty lies in simplicity as solar cell F008 / 4431 captures photons from the sun and transforms them into usable energy through photovoltaic technology. Witnessing nature's gift harnessed by science, solar cell F008 / 4428 absorbs sunlight and generates renewable power for various applications around us. Illuminating our lives with vibrant colors, light-emitting diodes (LEDs) reveal their fascinating structure under SEM - tiny semiconductors that emit light when energized. Unleashing the potential of renewable energy sources further, solar cell F008 / 4437 harnesses sunlight to provide green electricity while reducing carbon emissions. Embracing sustainability on every level, solar cell F008 / 4438 demonstrates its ability to capture and convert sunlight into clean energy for homes and businesses alike. Peering closely at a microchip surface under SEM magnification unveils its intricate architecture - layers upon layers of semiconductors working harmoniously to process information swiftly and efficiently. Continuing our journey towards greener horizons, solar cell F008 / 4433 showcases its remarkable capability to transform sunlight into a sustainable energy source, reducing our dependence on fossil fuels.