The Chemistry of Computing

For many people, chemistry class memories can cause a cold sweat over nostalgia. Think of pointers coated in laboratories that do nothing but suck your teenage life. Our idea is different

Chemistry doubles our ability to give us a faster computer, a bigger hard drive, and a more brilliant display, and to play our work, creation, or at least a half-life 2 style. The project won all the glory, but chemistry is key

Ghavam Shahidi, director of silicon technology at IBM Research, says: "This is what we are doing to speed up while reducing power consumption." But as computer components continue to shrink, processor and hard drives, especially the designer's imagination (and market demand) I am testing. Silicon transistors and hard disk magnets can be pushed in before they operate in an unintended manner. These are not small problems. This is the way chemistry solves them. to continue

1 The importance of chemistry in computer engineering Chemistry as a chemistry includes the nature, composition, nature, energy conversion, and how they undergo various chemical changes. Chemistry plays an important role in the discovery and understanding of the material of many computer components and computer aids (Tour, 2003). In emerging fields of nanotechnology and nanoscience, computer engineers must be able to manage the structure and bonding of molecules, which is important for the manufacture of electronic components such as computers. Depending on the field of interest to the engineer, all computer engineers need a chemical career (Lee, 2002). For example, designing computers and computer components requires chemistry. It provides knowledge of which documents are appropriate for a particular computer component. And use so much

Chemists have done calculations for centuries, but the field of "computational chemistry" we know today is the product of the digital age. Martin Karplus, Michael Levitt, Arieh Warshel received the 2013 Nobel Prize in Chemistry in the 1970's and laid the foundation for today's computer model combining classical (Newton) physics and quantum theory. Principles of physics to reproduce the details of chemical processes more accurately. In 1995, three mathematical models using thermodynamics and chemistry law to explain the formation and decomposition of atmospheric ozone by three computational chemists Paul Crutzen, Mario Molina, and F. Sherwood Rowland winning Nobel chemistry Has been built. However, until 1998, Walter Kohn and John Pople received the Nobel Prize in Chemistry for research on density functional theory and quantum chemical calculations.