My beginning as a legally recognized
individual occurred on June 13, 1928 in Bluefield, West Virginia, in the
Bluefield Sanitarium, a hospital that no longer exists. Of course I can't
consciously remember anything from the first two or three years of my life
after birth. (And, also, one suspects, psychologically, that the earliest
memories have become "memories of memories" and are comparable to
traditional folk tales passed on by tellers and listeners from generation to
generation.) But facts are available when direct memory fails for many
circumstances.
My father, for whom I was named, was an
electrical engineer and had come to Bluefield to work for the electrical
utility company there which was and is the Appalachian Electric Power Company. He
was a veteran of WW1 and had served in France as a lieutenant in the supply
services and consequently had not been in actual front lines combat in the war.
He was originally from Texas and had obtained his B.S. degree in electrical
engineering from Texas Agricultural and Mechanical (Texas A. and M.).
My mother, originally Margaret Virginia
Martin, but called Virginia, was herself also born in Bluefield. She had
studied at West Virginia University and was a school teacher before her
marriage, teaching English and sometimes Latin. But my mother's later life was
considerably affected by a partial loss of hearing resulting from a scarlet
fever infection that came at the time when she was a student at WVU.
Her parents had come as a couple to
Bluefield from their original homes in western North Carolina. Her father, Dr.
James Everett Martin, had prepared as a physician at the University of Maryland
in Baltimore and came to Bluefield, which was then expanding rapidly in
population, to start up his practice. But in his later years Dr. Martin became
more of a real estate investor and left actual medical practice. I never saw my
grandfather because he had died before I was born but I have good memories of
my grandmother and of how she could play the piano at the old house which was
located rather centrally in Bluefield.
A sister, Martha, was born about two and
a half years later than me on November 16, 1930.
I went to the standard schools in
Bluefield but also to a kindergarten before starting in the elementary school
level. And my parents provided an encyclopedia, Compton's Pictured
Encyclopedia, that I learned a lot from by reading it as a child. And also
there were other books available from either our house or the house of the
grandparents that were of educational value.
Bluefield, a small city in a
comparatively remote geographical location in the Appalachians, was not a
community of scholars or of high technology. It was a center of businessmen,
lawyers, etc. that owed its existence to the railroad and the rich nearby coal
fields of West Virginia and western Virginia. So, from the intellectual
viewpoint, it offered the sort of challenge that one had to learn from the
world's knowledge rather than from the knowledge of the immediate community.
By the time I was a student in high
school I was reading the classic "Men of Mathematics" by E.T. Bell
and I remember succeeding in proving the classic Fermat theorem about an
integer multiplied by itself p times where p is a prime.
I also did electrical and chemistry
experiments at that time. At first, when asked in school to prepare an essay
about my career, I prepared one about a career as an electrical engineer like
my father. Later, when I actually entered Carnegie Tech. in Pittsburgh I
entered as a student with the major of chemical engineering.
Regarding the circumstances of my
studies at Carnegie (now Carnegie Mellon U.), I was lucky to be there on a full
scholarship, called the George Westinghouse Scholarship. But after one semester
as a chem. eng. student I reacted negatively to the regimentation of courses
such as mechanical drawing and shifted to chemistry instead. But again, after
continuing in chemistry for a while I encountered difficulties with
quantitative analysis where it was not a matter of how well one could think and
understand or learn facts but of how well one could handle a pipette and
perform a titration in the laboratory. Also the mathematics faculty were
encouraging me to shift into mathematics as my major and explaining to me that
it was not almost impossible to make a good career in America as a
mathematician. So I shifted again and became officially a student of
mathematics. And in the end I had learned and progressed so much in mathematics
that they gave me an M. S. in addition to my B. S. when I graduated.
I should mention that during my last
year in the Bluefield schools that my parents had arranged for me to take
supplementary math. courses at Bluefield College, which was then a 2-year
institution operated by Southern Baptists. I didn't get official advanced
standing at Carnegie because of my extra studies but I had advanced knowledge
and ability and didn't need to learn much from the first math. courses at
Carnegie.
When I graduated I remember that I had
been offered fellowships to enter as a graduate student at either Harvard or
Princeton. But the Princeton fellowship was somewhat more generous since I had
not actually won the Putnam competition and also Princeton seemed more
interested in getting me to come there. Prof. A.W. Tucker wrote a letter to me
encouraging me to come to Princeton and from the family point of view it seemed
attractive that geographically Princeton was much nearer to Bluefield. Thus
Princeton became the choice for my graduate study location.
But while I was still at Carnegie I took
one elective course in "International Economics" and as a result of
that exposure to economic ideas and problems, arrived at the idea that led to
the paper "The Bargaining Problem" which was later published in
Econometrical. And it was this idea which in turn, when I was a graduate
student at Princeton, led to my interest in the game theory studies there which
had been stimulated by the work of von Neumann and Morgenstern.
As a graduate student I studied
mathematics fairly broadly and I was fortunate enough, besides developing the
idea which led to "Non-Cooperative Games", also to make a nice
discovery relating to manifolds and real algebraic varieties. So I was prepared
actually for the possibility that the game theory work would not be regarded as
acceptable as a thesis in the mathematics department and then that I could
realize the objective of a Ph.D. thesis with the other results.
But in the event the game theory ideas,
which deviated somewhat from the "line" (as if of "political
party lines") of von Neumann and Morgenstern's book, were accepted as a
thesis for a mathematics Ph.D. and it was later, while I was an instructor at
M.I.T., that I wrote up Real Algebraic Manifolds and sent it in for
publication.
I went to M.I.T. in the summer of 1951
as a "C.L.E. Moore Instructor". I had been an instructor at Princeton
for one year after obtaining my degree in 1950. It seemed desirable more for
personal and social reasons than academic ones to accept the higher-paying
instructorship at M.I.T.
I was on the mathematics faculty at
M.I.T. from 1951 through until I resigned in the spring of 1959. During
academic 1956 - 1957 I had an Alfred P. Sloan grant and chose to spend the year
as a (temporary) member of the Institute for Advanced Study in Princeton.
During this period of time I managed to
solve a classical unsolved problem relating to differential geometry which was
also of some interest in relation to the geometric questions arising in general
relativity. This was the problem to prove the isometric embeddability of
abstract Riemannian manifolds in flat (or "Euclidean") spaces. But
this problem, although classical, was not much talked about as an outstanding
problem. It was not like, for example, the 4-color conjecture.
So as it happened, as soon as I heard in
conversation at M.I.T. about the question of the embeddability being open I
began to study it. The first break led to a curious result about the
embeddability being realizable in surprisingly low-dimensional ambient spaces
provided that one would accept that the embedding would have only limited
smoothness. And later, with "heavy analysis", the problem was solved
in terms of embeddings with a more proper degree of smoothness.
While I was on my "Sloan
sabbatical" at the IAS in Princeton I studied another problem involving
partial differential equations which I had learned of as a problem that was
unsolved beyond the case of 2 dimensions. Here, although I did succeed in
solving the problem, I ran into some bad luck since, without my being
sufficiently informed on what other people were doing in the area, it happened
that I was working in parallel with Ennio de Giorgi of Pisa, Italy. And de
Giorgi was first actually to achieve the ascent of the summit (of the
figuratively described problem) at least for the particularly interesting case
of "elliptic equations".
It seems conceivable that if either de
Giorgi or Nash had failed in the attack on this problem (of a priori estimates
of Holder continuity) then that the lone climber reaching the peak would have
been recognized with mathematics' Fields medal (which has traditionally been
restricted to persons less than 40 years old).
Now I must arrive at the time of my
change from scientific rationality of thinking into the delusional thinking
characteristic of persons who are psychiatrically diagnosed as
"schizophrenic" or "paranoid schizophrenic". But I will not
really attempt to describe this long period of time but rather avoid
embarrassment by simply omitting to give the details of truly personal type.
While I was on the academic sabbatical
of 1956-1957 I also entered into marriage. Alicia had graduated as a physics
major from M.I.T. where we had met and she had a job in the New York City area
in 1956-1957. She had been born in El Salvador but came at an early age to the
U.S. and she and her parents had long been U.S. citizens, her father being an
M. D. and ultimately employed at a hospital operated by the federal government
in Maryland.
The mental disturbances originated in
the early months of 1959 at a time when Alicia happened to be pregnant. And as
a consequence I resigned my position as a faculty member at M.I.T. and,
ultimately, after spending 50 days under "observation" at the McLean
Hospital, travelled to Europe and attempted to gain status there as a refugee.
I later spent times of the order of five
to eight months in hospitals in New Jersey, always on an involuntary basis and
always attempting a legal argument for release.
And it did happen that when I had been
long enough hospitalized that I would finally renounce my delusional hypotheses
and revert to thinking of myself as a human of more conventional circumstances
and return to mathematical research. In these interludes of, as it were,
enforced rationality, I did succeed in doing some respectable mathematical
research. Thus there came about the research for "Le Probleme de Cauchy
pour les E'quations Differentielles d'un Fluide Generale"; the idea that
Prof. Hironaka called "the Nash blowing-up transformation"; and those
of "Arc Structure of Singularities" and "Analyticity of
Solutions of Implicit Function Problems with Analytic Data".
But after my return to the dream-like
delusional hypotheses in the later 60's I became a person of delusionally
influenced thinking but of relatively moderate behavior and thus tended to
avoid hospitalization and the direct attention of psychiatrists.
Thus further time passed. Then gradually
I began to intellectually reject some of the delusionally influenced lines of
thinking which had been characteristic of my orientation. This began, most
recognizably, with the rejection of politically-oriented thinking as
essentially a hopeless waste of intellectual effort.
So at the present time I seem to be
thinking rationally again in the style that is characteristic of scientists.
However this is not entirely a matter of joy as if someone returned from
physical disability to good physical health. One aspect of this is that
rationality of thought imposes a limit on a person's concept of his relation to
the cosmos. For example, a non-Zoroastrian could think of Zarathustra as simply
a madman who led millions of naive followers to adopt a cult of ritual fire
worship. But without his "madness" Zarathustra would necessarily have
been only another of the millions or billions of human individuals who have
lived and then been forgotten.
Statistically, it would seem improbable
that any mathematician or scientist, at the age of 66, would be able through
continued research efforts, to add much to his or her previous achievements.
However I am still making the effort and it is conceivable that with the gap
period of about 25 years of partially deluded thinking providing a sort of
vacation my situation may be atypical. Thus I have hopes of being able to
achieve something of value through my current studies or with any new ideas
that come in the future.
John F. Nash
(Bluefield, 1928) Economista y matemático estadounidense.
Extraordinariamente dotado para el análisis matemático, Nash desarrolló
investigaciones en torno a la teoría de juegos, que le valieron el Premio Nobel
de Economía en 1994, junto a John Harsanyi y Reinhard Selten.
Ingresó en el Carnegie Institute of Technology, en la actualidad
Universidad Carnegie-Mellon de Pittsburgh, con la intención de estudiar
Ingeniería química; pero tras cursar algunas asignaturas de Matemáticas, aceptó
la sugerencia de sus profesores de orientar su carrera hacia esta materia. En
1948 obtuvo el grado de licenciado en Matemáticas y, tras recibir varias
ofertas para realizar el doctorado, se decidió por la Universidad de Princeton.
A lo largo de sus estudios doctorales, mostró interés por diversos campos
de estudio, como la topología, el álgebra geométrica o la teoría de juegos. En
1949 y como parte de sus investigaciones publicó en la revista Annals of
Mathematics un artículo titulado "Non-cooperative Games", en el que
se recogían las ideas principales de su tesis, que presentó el siguiente año en
Princeton. En dicho artículo se exponían los puntos básicos sobre las
estrategias y las posibilidades de predicción del comportamiento que se da en
juegos no cooperativos con información incompleta.
Una vez finalizada su tesis, trabajó durante unos meses para la Corporación
RAND, que estaba muy interesada en sus conocimientos de la teoría de juegos
para aplicarlos a la estrategia militar y diplomática. Volvió a la Universidad
de Princeton poco después, lo que no resultó impedimento para que colaborara de
forma esporádica con la Corporación RAND. En 1952 se incorporó al cuerpo
docente del prestigioso Massachusetts Institute of Technology (MIT), donde
realizó una importante labor de investigación sobre variables algebraicas
reales múltiples.
Durante la década de los años cincuenta resolvió cuestiones de importancia
como la demostración de la interpenetrabilidad isométrica de las variedades
riemannianas en espacios euclídeos, y las ecuaciones diferenciales parciales
bidimensionales, trabajo que realizó de forma independiente y simultánea a
Ennio di Giorgi. Toda esta labor se vio bruscamente interrumpida en 1959,
cuando renunció voluntariamente a su plaza aquejado de esquizofrenia.
Tras una larga serie de internamientos en instituciones psiquiátricas, se
recuperó de su enfermedad en la década de los años noventa, lo que le permitió
volver a la actividad científica. Desde entonces ha elaborado algunos artículos
relativos a las ecuaciones diferenciales y a su resolución analítica mediante
métodos numéricos, que han tenido cierto impacto en la comunidad científica
internacional. En reconocimiento a su labor investigadora en torno a la teoría
de juegos, se le concedió el Premio Nobel de Economía en 1994 junto a John
Harsanyi y a Reinhard Selten.
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