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April 10, 2026
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"Much later, I was to find that my view of Von Neumann as a great man was completely confirmed."
"He was becoming more concerned with defense than with science. But it seemed that he was living proof that one could do science without really belonging to a âguild.â In fact, he was under extreme pressure at Princeton. From there, he left for Washington and was not planning to return. Luckily, von Neumann had realized that, by having failed to claim admission to any guild, I was leading a very dangerous life. A foundation executive told me much later that von Neumann had specifically asked him to watch after me, and to help in case of trouble."
"Phenomenon."
"Johnny von Neumann was the genius."
"I think we were right, though, in thinking he was several leaps ahead of the rest of us."
"Johnny von Neumann was very, very good and very quick and very sharp. He just was a universalist. He was not a mathematician."
"Johnny von Neumann who was very, very quickâI mean, you have no idea how quickly he would infer things and extrapolate them. Well, he was fantastic."
"He knew so much about physics and philosophy and even things like history. He was very, very sharp. He worked all the time."
"His talents were so obvious and his cooperative spirit so stimulating that he garnered the interest of many of us."
"It is worth emphasizing that as great a mathematician as J. von Neumann never tired of repeating the fact that the errors of observation are what really matter. This is entirely in the spirit of Gauss. It is also noteworthy that von Neumann was firmly convinced that the intimate contact between mathematics and reality would produce, from time to time, decisive progress in mathematics."
"He worked with tremendous energy and fantastic speed."
"The fastest mind I ever met."
"I tried at that time to cast the unifying Dirac-Jordan transformation theory into a simpler and more easily understandable form and to convey its essence to Hilbert. When von Neumann saw this he cast it in a few days into an elegant axiomatic form much to the liking of Hilbert. (This is the origin of the paper âOber die Grundlagen der Quantenmechanikâ by Hilbert, von Neumann and myself . . .). The method used was that of integral operators. . . . This work set von Neumann on his way to his definite studies on the foundations of quantum mechanics."
"We are in what can only be described as a desperate need of your help. We have a good many theoretical people working here, but I think that if your usual shrewdness is a guide to you about the probable nature of our problems you will see why even this staff is in some respects critically inadequate...I would like you to come as a permanent, and let me assure you, honored member of our staff. A visit will give you a better idea of this somewhat Buck Rogers project than any amount of correspondence."
"I remember that there was a feeling of excitement and interest both in Hilbertâs lecture and in the lecture of von Neumann on the foundations of set theory â a feeling that one now finally was coming to grips with both the axiomatic foundation of mathematics and with the reasons for the applications of mathematics in the natural sciences."
"Morgenstern was once asked how a scholar outside the mainstream of economic thinking could make a contribution as original, innovative, and decisive as Johnny's. He replied that Johnny had an extraordinary capacity for picking the brains of a person whom he engaged in casual conversations. Once he saw from these that there was a problem of sufficient mathematical interest to warrant his spending time on it, he homed on to that subject like a guided missile."
"In my life I have met men even greater than Johnny, but none as brilliant. He shone not only in mathematics but was also fluently multilingual and particularly well-versed in history. One of his most remarkable abilities I soon came to note was his power of absolute recall."
"Von Neumann's reputation and fame have grown steadily since his death. His fantastic brain, and the breadth of his interests and undertakings, have become almost legendary."
"If doing physics meant proving theorems, youâd be a great physicist."
""Johnny" von Neumann, as he was always known among scientists, achieved fame first of all as a pure mathematician. I am not qualified to describe his contributions to pure mathematics, which usually related to the most recent, and most abstruse, branches of the subject at the time, but they certainly placed him among the leaders of modern mathematics. In the 1920s, he was interested in the development of quantum mechanics, then in rapid growth, which caused difficulty to many because of the bold use of new mathematical techniques. Von Neumann contributed greatly to making this new subject "respectable"; he pointed out the precise mathematical significance of the new developments and, at the same time, helped greatly to clarify the physical content of the new ideas. He was, in fact, quicker than many physicists in grasping the changes that were then taking place in physics Later he was a frequent visitor to the Atomic Weapons Project at Los Alamos. Here his particular quality of combining powerful mathematical insight with a very practical interest in the problems became familiar to all those associated with the project. He was never satisfied with showing that a problem could be solved on paper, but he took a personal interest in its quantitative application and in its practical realization. His many contributions, particularly to the hydrodynamics of shock waves and detonation waves, which are important both in the design of atomic weapons and in an understanding of their effects, were vital to the success of the project. For a man to whom complicated mathematics presented no difficulty, he could explain his conclusions to the uninitiated with amazing lucidity. After a talk with him one always came away with a feeling that the problem was really simple and transparent. About the same time, he became interested in the application of computing techniques to mathematical problems, and this led him to design the computer now in operation at Princeton and to planning out its applications both to practical problems and to abstract problems in nonlinear equations. He was the antithesis of the conventional image of the "long-haired" mathematics don. Always well-groomed, he had as lively views on international politics and practical affairs as on mathematical problems. His book on the Theory of Games, "including the theory of bluffing at poker," which has proved fruitful for many applications going beyond the field of games of chance and skill, is another example of the happy combination of his command of mathematics with an interest in practical matters. For the last few years, he was a member of the Atomic Energy Commission, and it is worth recording that in a field beset with much controversy, he retained the universal respect and confidence of those who did not agree with his views on policy as well as those who did."
"Another frequent visitor was John von Neumann, a brilliant mathematician, whom I knew from Germany. Although he was Hungarian, he did not have the extreme superficial politeness of many Hungarians. He liked good living and a good story. His mathematics was of the purest and most abstract kind, but he also understood physics and had written a book about quantum mechanics. He was extremely fast in solving practical problems, and contributed many useful ideas to the work of Los Alamos."
"Remarkable mathematician."
"The only student of mine I was ever intimidated by. He was so quick. There was a seminar for advanced students in ZĂźrich that I was teaching and von Neumann was in the class. I came to a certain theorem, and I said it is not proved and it may be difficult. Von Neumann didn't say anything but after five minutes he raised his hand. When I called on him he went to the blackboard and proceeded to write down the proof. After that I was afraid of von Neumann."
"Von Neumann was a calculating prodigy as well. He could divide two eight-digit numbers in his head with little effort. Cuthbert Hurd of IBM told me of von Neumannâs uncanny ability to create and revise computer programs (as long as fifty lines of assembly-language code!) in his head."
"In 1956 Good Housekeeping magazine ran an article on Klara von Neumann and her husband with the improbable title, âMarried to a Man Who Believes the Mind Can Move the World.â One of the stranger examples of 1950s womenâs magazine journalism, it is a dogged attempt to humanize a not entirely promising subject. âWhatâs it like to suspect your husband of being the smartest man on earth?â the article asks. âWhen Klara von Neumann, a slender brunette of Washington, D.C., glances at her husband, a plump, cheerful man who was born in Hungary fifty-two years ago, the thought sometimes occurs to her that she may be married to the best brain in the world.â"
"It seems fair to say that if the influence of a scientist is interpreted broadly enough to include impact on fields beyond science proper, then John von Neumann was probably the most influential mathematician who ever lived."
"Under the force of Courant's plea, Trowbridge reconsidered Hilbert's request; and in the fall of 1926 von Neumann came to GĂśttingen as a Rockefeller Fellow. The young mathematicians there recognized that he was obviously a prodigy, but some were suspicious of what they saw as a certain âglibnessâ about him. They also found his mathematics âtoo abstractâ for their taste. âWe were wrong about that,â confessed Friedrichs, part of whose later work was to be strongly influenced by the work of von Neumann."
"All the mathematicians I have talked to have said that von Neumann had the quickest mind they ever knew."
"If someone gave a problem and von Neumann did not give an immediate solution, then it was an unsolvable problem."
"He was a multifaceted genius."
"There is also no objection to a mathematicianâs doing physics, provided he is qualified. The prime example was von Neumannâwhen he did physics, he talked, thought, and calculated like a physicist (but faster). He understood all branches of physics (including elementary particles as they were known then), and chemistry and astronomy, and he had a talent for introducing those and only those mathematical ideas that were relevant to the physics at hand."
"Apart from my thesis, though, I cannot overlook the great influence on all of us of the sparkling lectures in real analysis given by Professor John von Neumann, a young man who had also come from Germany during this period. How well I remember his hurried arrivals in the classroom, a mere second late but wasting no time. With spectacular fluency he instantly made the hour come alive. No notes were ever needed, for his complete control and mastery of his subject and his lightning-fast blackboard-equations quickly reflected to us some of the greatness of his precocious mind. His audience will remember his beautifully complexioned cheeks that often radiated a cherubic smile, and his bright piercing brown eyes that seemed to glow with great vitality."
"No other mathematician in this century has had as deep and lasting an influence on the course of civilization."
"At this half-century birthday party I have two purposes. The first is to free the dynamic input/output paradigin from gratuitous misinterpretations. The second is to say something about the genius of John von Neumann, contrasting the fertility of his contributions to economics with that of past great mathematicians and non-economist celebrities. While memories are still green, we should preserve for the historical record some of the legends about this great genius."
"Evidence enough has been given for von Neumannâs genius and eminence in pure and applied mathematics."
"We economists are grateful for von Neumannâs genius. It is not for us to calculate whether he was a Gauss, or a PoincarĂŠ, or a Hilbert. He was the incomparable Johnny von Neumann. He darted briefly into our domain and it has never been the same since."
"A man so smart that he saw through himself."
"The author, who through his previous mathematical achievements has already placed himself in the forefront of German mathematicians, is only 23 years old and completed his studies in chemistry at the EidgenĂśssisches Polytechnikum in Zurich with the diploma examination. He combines penetrating abstract acumen with an astonishing speed in the productive assimilation of large bodies of scientific knowledge. This is undoubtedly an altogether extraordinary talent, which justifies unlimited hopes."
"Comparing this work with the habilitation thesis, one recognizes in how outstanding and promising a manner the highly gifted young researcher combines the ability for far-reaching abstraction with a powerful sense for constructive work and also for the advancement of concrete problems."
"Bethe, Fermi, and von Neumann could often be found sitting together in a quiet room inside the throbbing heart of the Theoretical Division, challenging each other to solve complex integral equations related to pressure waves. Sometimes Oppenheimer would join them. Von Neumann usually left these other three brilliant physicists in the dust."
"But when you were in real thinking trouble, you would go to von Neumann and nobody else."
"I remember having listened to Fermiâs discussions on hydrodynamics with von Neumann. (These took the strange form of competitions before Fermiâs office blackboard as each tried to solve the problem under study first; von Neumann, with his unmatched lightning-fast analytical skill, usually won)."
"The smartest person I've ever met."
"I was a graduate studentâhe was one of the great mathematicians of the world."
"Neumann was undoubtedly a genius. This meant among other things that be was able to learn a new subject in an incredibly short time. Before designing the computer, he took two weeks off to learn electronics, thus became able to supervise the construction of the hardware."
"One of the centuryâs most esteemed scientists."
"If any one person in the previous century personified the word polymath, it was von Neumann."
"His contributions to physics, mathematics, computer science, and economics rank him as one of the all-time intellectual giants of each field."
"Later, Tucker told me that he had gone to von Neumann and said, âThis seems like very interesting work, but I canât evaluate it. I donât know whether it should really be called mathematics.â Von Neumann replied, âWell, if it isnât now, it will be somedayâletâs encourage it.â So I got my Ph.D.â"
"I think that it is a relatively good approximation to truth â which is much too complicated to allow anything but approximations â that mathematical ideas originate in empirics. But, once they are conceived, the subject begins to live a peculiar life of its own and is ⌠governed by almost entirely aesthetical motivations. In other words, at a great distance from its empirical source, or after much "abstract" inbreeding, a mathematical subject is in danger of degeneration. At the inception the style is usually classical; when it shows signs of becoming baroque, then the danger signal is up. It would be easy to give examples, to trace specific evolutions into the baroque and the very high baroque... Whenever this stage is reached the only remedy seems to me to be the rejuvenating return to the source: the reinjection of more or less directly empirical ideas."