Walter Schottky was born on July 23, 1886 in Zurich, Switzerland, but he spent his life in Germany. His father, Friedrich, was a university mathematician. As a result of his career move from Marburg to Berlin, Schottky attended schools in both places and entered the Humboldt University in Berlin in 1904, where he studied physics. In 1912, he was awarded a doctorate in Berlin for his thesis on the Special Theory of Relativity, which Albert Einstein had announced only seven years earlier. Schottky's tutor was Max Planck, the originator of the Quantum Theory and a man at the heart of modern physics. After receiving his Ph.D., Schottky moved to Jena, Germany, where he worked under Max Wien. It was here that he turned away from relativity theory and began what would become his life's work — the interaction of electrons and ions in vacuum and solid bodies.
Schottky's achievements can be divided into two phases: the first being research into vacuum electronics and the second, starting in 1929, covering semiconductor electronics. There were, however, two other accomplishments that do not fall under these two areas that would alone have guaranteed him a place in history. These two inventions were the ribbon microphone and the superhet. The ribbon microphone was invented jointly with Erwin Gerlach in 1924. It consisted of an extremely thin concertina ribbon of aluminum placed between the poles of a permanent magnet. They also invented a ribbon loudspeaker as well, simply by reversing the physical effects of the microphone. The invention of the superhet is typically credited to Edwin Armstrong, but Schottky independently discovered the same principle of the superheterodyne with IF amplification in 1918.
Schottky began his work on electron physics at Jena, where he performed theoretical and experimental studies of the space charge effects of electrons emitted from cathodes in vacuum tubes.
At Siemens, Schottky further developed his interests in electronic valves. Although he was only there from 1915 to 1919, he was able to produce a number of discoveries and inventions. He invented the screen-grid tube in 1915, and in 1919 he invented the tetrode, the first multigrid vacuum tube. A tetrode contains two grids--the basic one and a second grid called the screen. The screen prevents the tube from producing unwanted oscillations.
He soon overshadowed that great achievement with his prediction of thermal and shot noise, which are two of the fundamental classes of noises in electronic devices. Walter Schottky discovered the random noise due to the irregular arrival of electrons at the anode of thermionic tubes that is called "shot noise" in 1914 while studying under Planck in Berlin.
In the early years of electronic circuitry engineers and physicists were trying to solve problems involved in making better vacuum valves. Although many of the problems were related to design and manufacturing techniques, such as inadequate vacuum pumping, mechanical resonance, and poor welds, the fundamental problem of noise was gaining recognition. Scientists were trying to discover what the ideal performance of valve amplifiers would be once all the manufacturing problems were eliminated, which would then isolate the fundamental problems of physics. J.B. Johnson and Harry Nyquist, who worked at Bell laboratories in the United States, would provide some of the answers to these problems in the 1920's. Walter Schottky, however, had already answered most of these problems in his classic paper on noise in valve amplifiers, which was published in 1918. He had reached the conclusion that there would be two sources of noise of a fundamental nature in an amplifier. The first would occur in the input circuit and would result from the random motion of charge caused by the thermal motion of the molecules in the conductors, or what is now known as thermal noise. Since the noise is originated in the input circuit and would appear amplified in the output circuit, he deduced that it would be proportional to the Boltzmann constant (k) multiplied by the absolute temperature. In the mid-1920's, Johnson experimentally identified thermal noise and Nyquist analyzed the discovery mathematically, producing a formula of 4kT watts per unit of bandwidth, confirming Schottky's deduction. Schottky's second fundamental source of noise would be caused by the randomness of the emission from the cathode and the randomness of the velocity of the emitted electrons, which is now know as shot noise. This noise was first experimentally identified and measured in Schottky's laboratory. Later studies showed it was linked to factors such as the material and design of the cathode. Schottky was able to create a better understanding of the sources of these noises, which led to better valves and would also be of benefit to the next period of his career, the semiconductor age.
The next great period of his work was to be with semiconductors, but he would direct his attention to thermodynamics before actually working with them. Throughout the 1920's Schottky gathered material, which eventually appeared in 1929 in his book on thermodynamics, Thermodynamik. It presented the thermodynamic theory of solids with very low impurity content or with small deviations from stoichiometry. He was one of the first to point out the existence of electron “holes” in the valence-band structure of semiconductors. In 1935 he noticed that a vacancy in a crystal lattice results when an ion from that site is displaced to the crystal's surface, a type of lattice vacancy now known as the Schottky defect. These studies are what led him to the study of semiconductors, which is considered the most important part of his career. Ferdinand Braun is usually credited with the first systematic study of metal-semiconductor rectifiers, work that was published in 1874. Point-contact metal-semiconductor rectifiers were used in the early 1900's, but it was not until 1931 that the theory of current flow was produced by A.H. Wilson. Schottky published his diffusion theory of current transport in metal-semiconductor junctions approximately seven years later.
In today's electrical engineering community the word "Schottky" has been transformed from a man's name into a technical term associated with the construction of a wide range of electronic components. This is not an honor shared only by Walter Schottky, but it is perhaps a mark of respect that is greater than the traditional medals, awards, and other prestigious recognitions that reward success. Through is his life and career Schottky permanently embedded his name into an industry that he so diligently contributed to and quietly revolutionized.