entropieverminderung thermodynamischen system eingriffen intelligenter de szilard leo (4 résultats)

Etat : Fine. First edition. Relationship of Information to the Physical World Szilard, Leo (1898-1964). Über die Entropieverminderung in einem thermodynamischen System bei Eingriffen intelligenter Wesen. In Zeitschrift für Physik 53 (1929): 840-856. Whole volume. vii, 889pp. Text illustrations. 223 x 152 mm. Library buckram. Fine. Embossed library stamp of the Carnegie Institution of Washington, Mount Wilson Laboratory on the front free endpaper, library call number on spine. Boxed. First Edition of the founding document of information theory. In "Über die Entropieverminderung in einem thermodynamischen System bei Eingriffen intelligenter Wesen" [On the reduction of entropy in a thermodynamic system by the intervention of intelligent beings], Szilard described a theoretical model that served both as a heat engine and an information engine, establishing the relationship between information (manipulation and transmission of bits) and thermodynamics (manipulation and transfer of energy and entropy). He was one of the first to show that "Nature seems to talk in terms of information" (Seife, Decoding the Universe, p. 77). In his paper Szilard addressed the problem of "Maxwell's demon," a thought experiment posed by James Clerk Maxwell in his Theory of Heat (1871) as a challenge to the second Law of Thermodynamics. This law states that the entropy of an isolated system not in equilibrium will tend to increase over time, reaching its maximum level at equilibrium. Maxwell speculated that "if we conceive of a being whose faculties are so sharpened that he can follow every molecule in its course, such a being, whose attributes are as essentially finite as our own, would be able to do what is impossible to us. For we have seen that molecules in a vessel full of air at uniform temperature are moving with velocities by no means uniform, though the mean velocity of any great number of them, arbitrarily selected, is almost exactly uniform. Now let us suppose that such a vessel is divided into two portions, A and B, by a division in which there is a small hole, and that a being, who can see the individual molecules, opens and closes this hole, so as to allow only the swifter molecules to pass from A to B, and only the slower molecules to pass from B to A. He will thus, without expenditure of work, raise the temperature of B and lower that of A, in contradiction to the second law of thermodynamics." Maxwell's demon exploits the random, statistical nature of matter in order to decrease entropy in a closed system without any expenditure of energy-a state of affairs that is physically impossible. Recognizing the flaw in Maxwell's concept, Szilard countered the earlier physicist's challenge as follows: "Szilard realized that the act of measuring the position of the atom (or in the Maxwell case, the speed of an incoming atom) must, in some way, increase the entropy of the universe, counteracting the demon's reduction of the universe's entropy. When a demon performs a measurement, he is getting an answer to a question: Is the atom on the right side of the box or the left side of the box? Is the atom hot or cold? Should I open a shutter or not? So a measurement is an extraction of information from the particle. That information does not come for free. Something about that information-either extracting it or processing it-would increase the entropy of the universe. In fact, Szilard calculated that the "cost" of that information was a certain amount of useful energy-more precisely, kT log 2 joules for every bit of information, where T is the temperature of the room that the demon is in and k is the same constant that Boltzmann used in his entropy equation" (Seife, Decoding the Universe [2007], pp. 78-79). One of the most brilliant thinkers of the twentieth century, Szilard is best known for his work in nuclear physics: he conceived the idea of a nuclear chain reaction in 1933, filed a patent for a simple nuclear reactor in 1934, and collaborated with Fermi in the first demonstration of a chain reaction in 1942. In 1939 Szilard wrote a confidential letter to President Roosevelt outlining the possibility of nuclear weapons; this letter, co-signed by Einstein, led directly to the foundation of the Manhattan Project. Szilard worked on the Manhattan Project during the Second World War, but opposed the use of the atomic bomb as a weapon of destruction, instead advocating for a demonstration of the bomb's power in the hope that the mere threat of such a weapon would force Germany and Japan to surrender. Horrified by the devastation of Hiroshima and Nagasaki, Szilard turned from nuclear physics to biology after the war, and became an outspoken opponent of nuclear proliferation. .

Berlin, Julius Springer, 1929. 8vo. Bound in contemporary halfcloth. In "Zeitschrift für Physik", Vol. 53, 1929. Entire volume offered. Library stamp to title page, otherwise fine and clean. Pp. 840-856. [Entire volume: VII,(1),889,(1) pp.] First edition of the landmark paper in which Szilard solved the puzzle of Maxwell's demon and discovered a theoretical model that serves both as a heat engine and information engine, establishing the connection between entropy and information. "This work is now considered to be the earliest known paper in what became the field of "information theory". (Lanouette, Genius in the Shadows: A Biography of Leo Szilard, the Man Behind the Bomb). In the philosophy of thermal and statistical physics, Maxwell's demon is a thought experiment created by Maxwell to show that the Second Law of Thermodynamics has only a statistical certainty. "Maxwell's demon was first mentioned in a letter written to Tait in 1867. Maxwell was one amongst a number of researchers in the developing field of thermodynamics who was interested in seeking an understanding of thermal phenomena in terms of an underlying atomic physics. However, unlike Boltzmann and Clausius, who were attempting to prove the law of entropy increase from such atomic physics, Maxwell had realised that if thermodynamics was ultimately grounded in atomic theory, then the second law of thermodynamics could have only a statistical validity." (SEP). Szilard (In the present paper) attempted to investigate this special case of intelligently operated devices by considering a box containing only a single molecule. He argued that in order to achieve the entropy reduction, the intelligent being must acquire knowledge of which fluctuation occurs and so must perform a measurement. The second law would not be threatened provided there was a compensating cost to performing this measurement, regardless of the character of the intelligent being."Claude E. Shannon, who spelled out detailed relationship between information and entropy in the 1950s, also later acknowledged that Szilard's paper had proposed the basis for his new field study." (Lanouette, Genius in the Shadows: A Biography of Leo Szilard, the Man Behind the Bomb).

Berlin, Julius Springer, 1929. 8vo. Contemp. hcloth. Some wear to edges and spine. A stamp on title-page. In "Zeitschrift für Physik", vol. 53. The whole volume offered. VII,(1),889,(1) pp. Szilard's paper: pp. 840-856. First edition of the important paper in which Szilard solved the puzzle of Maxwell's demon and discovered a theoretical model that serves both as a heat engine and an information engine, establishing the connection between entropy and information.Szilard was the first to stress that any manipulator of molecules would have to rely on measurement and memory. If one assumed that the demon could perform such operations without causing any changes in the system, one would by that very assumption deny the second law of thermodynamics, which requires equivalent compensations for all decreases in entropy. Szilard therefore proposed that whatever negative entropy Maxwell's demon might be able to create should be considered as compensated by an equal entropy increase due to the measurements the demon had to make. In essence, Szilard made Maxwell's doorkeeper mortal - no longer granting this tiny intelligence the ability to 'see' molecules without actually seeing them, i.e., without the sensory exchanges of energy that all other existences require. Szilard took this step for the sake of a grander vision, the dream that the adoption of his principle would lead to the discovery of a more general law of entropy in which there would be a completely universal relation for all measurements. Information theory has brought that vision to reality.

Berlin, Julius Springer, 1929. 8vo. Contem. hcloth. In "Zeitschrift für Physik", Vol. 53. VII,(1),889,(1) pp. The whole volume offered. Szilard's paper: pp. 840-856. Ex-lirbrary stamp to front free end-paper, otherwise no stamps or other markings. A fine copy. First edition of the important paper in which Szilard solved the puzzle of Maxwell's demon and discover a theoretical model that serves both as a heat engine and an information engine, eatablishing the connection between entropy and information. Szilard was the first to stress that any manipulator of molecules would have to rely on measurement and memory. If one assumed that the demon could perform such operations without causing any changes in the system, one would by that very assumption deny the second law of thermodynamics, which requires equivalent compensations for all decreases in entropy. Szilard therefore proposed that whatever negative entropy Maxwell's demon might be able to create should be considered as compensated by an equal entropy increase due to the measurements the demon had to make. In essence, Szilard made Maxwell's doorkeeper mortal-no longer granting this tiny intelligence the ability to 'see' molecules without actually seeing them, i.e., without the sensory exchanges of energy that all other existences require. Szilard took this step for the sake of a grander vision, the dream that the adoption of his principle would lead to the discovery of a more general law of entropy in which there would be a completely universal relation for all measurements. Information theory has brought that vision to reality.