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Throughout most of the history of modern computing, the speed of data processing—how much time it takes your computer to do anything—was determined by the speed of a chip’s transistors. The transistors flipped on and off, and the order in which they did so produced a code, much like letters are used to make words. Together, millions of flips could record and manipulate data in endless ways. The faster the transistors could be made to flip on and off (the transistor’s “clock speed”), the more powerful the software they could run, transforming computers from glorified calculators to multimedia entertainment and enterprise machines.

But until the 1970s, computers were used predominantly by rocket scientists and big universities. Some computers took up whole rooms or even buildings. The idea of a computer on your office desk or in your home was the stuff of science fiction. All that began to change in 1980, when Intel’s Haifa team designed the 8088 chip, whose transistors could flip almost five million times per second (4.77 megahertz), and were small enough to allow for the creation of computers that would fit in homes and offices.

IBM chose Israel’s 8088 chip as the brains for its first “personal computer,” or PC, launching a new era of computing. It was also a major breakthrough for Intel. According to journalist Michael Malone, “With the IBM contract, Intel won the microprocessor wars.”⁹

From then on, computing technology continued to get smaller and faster. By 1986, Intel’s only foreign chip factory was producing the 386 chip. Built in Jerusalem, its processing speed was 33 megahertz. Though a small fraction of today’s chip speeds, Intel called it “blazing”—it was almost seven times faster than the 8088. The company was solidly on the path imagined by one of its founders, Gordon Moore, who predicted that the industry would shrink transistors to half their size every eighteen to twenty-four months, roughly doubling a chip’s processing speed. This constant halving was dubbed “Moore’s law,” and the chip industry was built around this challenge to deliver faster and faster chips. IBM, Wall Street, and the business press all caught on, too—clock speed and size was how they measured the value of new chips.

This was proceeding well until about 2000, when another factor came into the mix: power. Chips were getting smaller and faster, just as Moore had predicted. But as they did, they also used more power and generated more heat. Chips overheating would soon become a critical problem. The obvious solution was a fan, but, in the case of laptops, the fan needed to cool the chips would be much too big to fit inside. Industry experts dubbed this dead end the “power wall.”

Intel’s Israeli team was the first group within the company to see this coming. Many late nights at Intel’s Haifa facility were dedicated to hot coffee, cold takeout, and ad hoc brainstorming sessions about how to get around the power wall. The Israeli team was more focused than anyone on what the industry called “mobility”—designing chips for laptop computers and, eventually, for all sorts of mobile devices. Noticing this tendency, Intel put their Israeli branch in charge of building mobility chips for the whole company.