Silicon Run II

Silicon Run Productions
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Silicon Run I
Silicon Run I uses live industrial footage to show the many processes necessary to manufacture microchips, including crystal growth, circuit design, and the wafer fabrication process for CMOS technology. Using close-ups of manufacturing processes and device animation, Silicon Run I provides a clear overview of front-end semiconductor manufacturing. It is…
Silicon Run Lithography
Silicon Run Lithography examines the role of photolithography in imaging and printing the many intricate layers of integrated circuits. Focusing on critical and non-critical mask levels of a CMOS transistor, this video takes a close look at the manufacturing materials, tools, and processes that have made more precise and complex…
Silicon Run Etch
This sixth video in the Silicon Run Series takes a close look at the etch process in semiconductor manufacturing, including chemical mechanical polish, or CMP. It shows how thin films of nonconductive, semiconductive, and conductive materials are sculpted into microchips. Following the fabrication process of a CMOS transistor, Silicon Run…
Silicon Run Lite
Silicon Run Lite combines key sequences and images from both Silicon Run I and Silicon Run II to show from the growth of silicon crystals through the assembly of a personal computer. Live industrial footage, microscopic filming, animation, graphics, and special effects give an up-close view of manufacturing. Silicon Run…
Silicon Run Implantation
Silicon Run Implantation takes a close look at the process of ion implantation. This video shows how ions are accelerated to high energies and directed into specific regions of the silicon substrate to change its molecular structure and alter its electrical properties. Silicon Run Implantation explores the various types of…
Silicon Run Deposition
Silicon Run Deposition uses 3D atomic animation and live manufacturing footage to provide a detailed close-up look at the process of thin film deposition in CMOS fabrication. It shows the chemical and physical reactions that create the dielectric and conductive layers of an integrated circuit. Silicon Run Deposition examines the…
Resistance Is Useful: Semiconductors
Episode 22 of The Nature of Matter
How does a tiny piece of impure silicon launch an electronics revolution? Follow the development of semiconductors from the invention of the transistor in the 1940s to ever-smaller circuits that are now measured in nanometers. Along the way, discover how today's complex microchips are made.
Silicon Run Series
This series features semiconductor and computer manufacturing. Each video includes rarely seen live industrial footage and explores technical processes using vivid animations and graphics. The videos in this collection each have a PDF attached with details on downloading an interactive quiz. Each quiz includes footage from the videos and are…
MEMS: Making Micro Machines
MEMS: Making Micro Machines is an overview of the manufacture and design of microelectromechanical systems. This video shows the fabrication, testing and packaging, and design of some of our most common MEMS devices. It features the fabrication of Hewlett-Packard's thermal inkjet printhead and covers the testing and packaging of Texas…
Erasure Cost and Reversible Computing
Maxwell's demon has startling implications for the push toward ever-faster computers. Probe the connection between the second law of thermodynamics and the erasure of information, which turns out to be a practical barrier to computer processing speed. Learn how computer scientists deal with the demon.
Turing Machines and Algorithmic Information
Contrast Shannon's code- and communication-based approach to information with a new, algorithmic way of thinking about the problem in terms of descriptions and computations. See how this idea relates to Alan Turing's theoretical universal computing machine, which underlies the operation of all digital computers.
Matter and Heat
Heat flow into a substance usually raises its temperature. But it can have other effects, including thermal expansion and changes between solid, liquid, and gaseous forms: collectively called phase changes. Investigate these phenomena, starting with an experiment in which Professor Wolfson pours liquid nitrogen onto a balloon filled with air.