To cope, Brattain immersed the entire experiment in water, inadvertently creating the largest amplification thus far observed. ![]() Brattain had built a silicon contraption to study the behavior of electrons at the surface of a semiconductor, in hopes of discovering what was causing electrons to block amplification, but condensation kept forming on the silicon. The research efforts peaked during the so-called "Miracle Month:" November 17 to December 23, 1947. ![]() The resulting device would, theoretically, amplify as well as the vacuum tube with much less power consumption and in a fraction of the space. John Bardeen, Walter Brattain and William Shockley spearheaded the Bell Labs effort to develop a new means of amplification, speculating that by adding a third electrode to the semiconductor detector, they would be able to control the amount of current flowing through the silicon. The discovery of this "P-N junction", and the ability to control its properties, laid the foundation for the transistor. In the process, they discovered that silicon was comprised of two distinct regions, one favoring positive current flow ("P") and one favoring negative current flow ("N"). They reverted to a crystal-based detector, which worked effectively and set them on the path of exploring the particular properties of the most reliable semiconductor material: silicon. In the 1930s, Bell Labs scientists were trying to use ultrahigh frequency waves for telephone communications, and needed a more reliable detection method than the vacuum tube, which proved incapable of picking up rapid vibrations. ![]() Pierce, to proclaim, "Nature abhors the vacuum tube." (The University of Pennsylvania's ENIAC computer, which incorporated thousands of vacuum tubes, filled several large rooms and consumed enough power to light ten homes.) These shortcomings prompted one Bell Labs engineer, J.R. Vacuum tubes consumed too much power, gave off too much heat, took up too much space, cost too much to produce, and eventually burned out and needed to be replaced. But the technology was less than perfect. The amplifying vacuum tube was not only an essential component in the development of radio, but also in early telephone equipment, television sets, and computers. The American inventor Lee DeForest added a further innovation: a third electrode, called a grid, consisting of a network of small wires surrounding the cathode, with a negative potential that controlled the flow of electrons from the cathode to the anode, producing an amplifying current. English physicist John Ambrose Fleming provided the first step towards a solution with his invention of the rectifying vacuum tube: a lightbulb outfitted with two electrodes attached to radio receiving systems. However, crystal sets only worked with strong radio waves, which tend to weaken over distance and terrestrial obstructions. Rectifying crystal detectors were eventually incorporated into radio receivers, which were able to separate the carrier wave from the part of the signal carrying the information. ![]() But before the technology could be fully practical, better detectors needed to be developed to detect the radio signal carrying the information. Wireless communication was born in 1895, when Marconi successfully sent a radio signal over a distance of more than a mile. It was scientists in the 1800s - including Maxwell, Hertz, and Faraday- who made the dramatic scientific discoveries that made it possible to harness electricity for human uses, while inventors applied this knowledge in the development of useful electrical devices like radio. The story of the first transistor begins well before Bell Labs scientists first started working on developing such a device in the 1930s. November 17 - December 23, 1947: Invention of the First Transistor
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