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Sydney Goldstein  
  
55   01:20 مساءً   date: 10-10-2017
Author : J Rom
Book or Source : Proceedings of the International Symposium on Modern Developments in Fluid Dynamics
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Date: 10-10-2017 108
Date: 21-9-2017 106
Date: 10-10-2017 59

Born: 3 December 1903 in Hull, England

Died: 22 January 1989 in Brockton, Massachusetts, USA


Sydney Goldstein's parents were Joseph and Hilda Goldstein. He was an only child but the early death of his mother saw him being brought up in the home of one of his mother's sisters. His father died in 1916 and he was left an orphan at the age of thirteen. He was educated in Sunderland, attending the Bede Collegiate Boys' School, completing his studies there in 1921. His favourite subject at Bede's School had been mathematics so, on 10 October 1921, he matriculated at the University of Leeds and began work towards a B.Sc. degree in mathematics.

When he first arrived in Leeds, Goldstein had not found any student accommodation so, for his first month, he was given accommodation by Selig Brodetsky who had, one year earlier, been promoted to Reader in Applied Mathematics. Brodetsky, who was a Russian Jew, had two great passions in life, mathematics and working for the Jewish community and the Zionist movement. He was to strongly influence Goldstein in both these areas, not only during the month that Goldstein lodged with Mania and Selig Brodetsky but also after he found his own accommodation since their friendship continued with frequent meetings. From this time on Goldstein, like Brodetsky, was to have the twin passions of mathematics and Zionism. Brodetsky quickly saw that Goldstein had exceptional mathematical talents which could not be fully realised by taking a degree at Leeds. He strongly advised the young student to move to Cambridge, where he himself had studied, and take the Mathematical Tripos.

After one year at Leeds, Goldstein moved to St John's College, Cambridge, graduating in 1925. Based on his very successful undergraduate career, Goldstein was awarded the Isaac Newton Studentship to continue undertaking research in applied mathematics under Harold Jeffreys. His years at Cambridge were highly significant not only from the mathematical point of view but also because it was at this time that he met his future wife. James Lighthill relates the circumstances in [4]:-

Sydney had been requested by a friend to go to Waterloo Station to meet an arriving South African girl, Rosa Sass (also from a Jewish family), whom the friend was not himself free to meet on that day. She was due to enter Newnham College for a Ph.D. degree course in Physical Chemistry. Syndey and Rosa were by no means to meet just on this one occasion; they found that they had a great deal in common - including some strong Zionist interests which in the fullness of time were to become even stronger - and their friendship prospered remarkably. They were married on 23 March 1926 and, by the time Rosa attended (successfully) her Ph.D. oral in 1927, she was already pregnant with their first child, David John.

Goldstein won the Smith's Prize in 1927 and was awarded his doctorate in 1928 for a thesis on the Mathieu functions (named after Émile Mathieu) entitled The Theory and Application of Mathieu Functions. He was appointed Rockefeller Research Fellow and spent a year working with Ludwig Prandtl in Göttingen. The strong influence of Prandtl on Goldstein is clearly seen by reading [3]. In 1929 he was made a fellow of St John's College, Cambridge and, in the same year, he was appointed to a Lectureship in Mathematics at the University of Manchester. He held these two appointments in parallel, dividing his time between the two. By this time he had twelve papers in print, the first two in 1927 and then five in each of the following two years. These included The influence of the Earth's magnetic field on electric transmission in the upper atmosphere (1928), The forces on a solid body moving through a viscous fluid (1929), The steady flow of a viscous fluid past a fixed spherical obstacle at small Reynolds number (1929), and On the vortex theory of screw propellers (1929) which were all published in the Proceedings of the Royal Society of London.

Manchester had a profound influence on Goldstein. The influence of Reynolds and Lamb in fluid dynamics was still felt there and had a strong effect on him. He also interacted with the Professor of Applied Mathematics, Douglas Hartree. He moved to Cambridge in 1931 and a clear indication of the high quality of his research over the next few years was his election as a fellow of the Royal Society of London in 1937. Leslie Howarth was a student at Manchester, where he was taught by Goldstein during 1929-31, then he followed Goldstein to Cambridge. Howarth wrote (see [4]):-

When, after taking the Mathematical Tripos (plus Schedule B), I graduated, he became my research supervisor. He was a most generous supervisor, generous in his always-stimulating suggestions and generous with his time. His home had a ready-open door and there, with Rosa, he had a profound influence on my life as well as on my work.

He took over, on Lamb's death, the editorship of Modern Developments in Fluid Dynamics, this important work appearing in 1938. Leslie Howarth comments on his editorial skills (see [4]):-

Goldstein's work as editor and part author of 'Modern developments in fluid dynamics' has been universally acclaimed. I was fortunate in seeing this at first hand as a part author and proof reader. Apart from reading and digesting every word, it was an education in itself for me to observe the skill that Sydney Goldstein applied to creating a unified, stimulating and accurate work.

From the outbreak of World War II in 1939, he worked on boundary layer theory at the Aerodynamics Division of the National Physical Laboratory where he was seconded for the duration of the war. By this time there were two children in the family, the younger being Ruth. In 1940 the Goldsteins decided that, because of threats from the Nazis towards Jewish children, Rosa would move to the United States with David John and Ruth. She worked from 1940 to 1944 for the British Air Commission in Washington and only in 1944 did they consider it safe enough to again be reunited in England. During the six war years Goldstein worked at the National Physical Laboratory he made excellent use of the computing facilities, advanced electric calculating machines operated by bright girls, and the wind tunnels used for experiments. He showed his outstanding leadership qualities in the exceptionally demanding environment dictated by the day-to-day crises of the wartime situation.

In 1945, the University of Manchester made two inspiring appointments to the Department of Mathematics, Max Newman to the Fielden Chair of Pure Mathematics and Goldstein to the Beyer Chair of Applied Mathematics. The Vice Chancellor of the university, Sir John Stopford, had persuaded the university authorities that these two appointments would "create at Manchester a dynamic and internationally renowned Department of Mathematics, interacting admirably with other units in the university".

However in 1950, Goldstein who, as we have already noted, had strong Jewish beliefs, accepted a professorship in Applied Mathematics and the chairmanship of the department of Aeronautical Engineering at Technion in Haifa, Israel. It was his delight in Israel's victory in the 1948-50 War of Independence that made it almost impossible for him not to accept this honour. However, the death of the President of the university shortly after he arrived there meant that Goldstein came under strong pressure to take over this administrative role. He resisted but eventually accepted the role of Vice President in charge of academic affairs. In a review of the first ten years of Technion, the President wrote:-

Dr Goldstein was the architect who designed the academic framework of the Technion. It was not only that he penned the academic constitution and by-laws, set up the academic and administrative bodies, defined the functions and authority of such bodies and created the tools and broad outlines for the operation of the Technion; he also gave content and spirit to these outlines, drawn from his own experience and from the fine traditions of higher learning in that country where he lived and worked as distinguished professor, scientist and academician. ...

The pressure put on him in his role as Vice President of Technion was unbearable, however, so, as a consequence, his stay in Israel was not very long and in 1955 he accepted the Gordon McKay Professorship of Applied Mathematics at Harvard in the United States.

Goldstein's work in fluid dynamics is of major importance. He is described in [4] as:-

... one of those who most influenced progress in fluid dynamics during the 20th century.

He studied numerical solutions to steady-flow laminar boundary-layer equations in 1930. In 1935 he published work on the turbulent resistance to rotation of a disk in a fluid. His work was important in aerodynamics, a subject in which Goldstein was extremely knowledgeable. The Annual Review of Fluid Mechanics began publication in 1969 and they invited Goldstein to be write an historical survey to be the first article in the new journal. The editors wrote:-

It seems particularly appropriate that this first 'Annual Review of Fluid Mechanics' should begin with an historical survey by one of the greatest of the living fluid mechanicists, Professor Sydney Goldstein. For one thing, he is probably uniquely qualified to write on this subject. Moreover, his own editorial efforts in 'Modern Developments in Fluid Dynamics' (Oxford, 1938) surely establish the standards of accuracy, content, and style for books of this category. By inviting Professor Goldstein to write our opening chapter, we acknowledge our great debt to him.

The fascinating article [3] was contributed by Goldstein and we give just one quote from it regarding the ancient nature of the subject:-

Curiosity about at least two of the branches of fluid mechanics and their applications has a long and distinguished history, for in the Proverbs of Solomon the son of David, king of Israel, it was stated in the words of Agur the son of Jakeh that "There be three things which are too wonderful for me, yea four which I know not," of which two were "The way of an eagle in the air" and "The way of a ship in the midst of the sea," which I take to be questions of aerodynamics and naval architecture, questions that concern us still.

Goldstein retired from his Harvard chair in 1970. His 70th birthday was marked by the International Symposium on Modern Developments in Fluid Dynamics held in his honour at Technion, Haifa in December 1973. At this conference he gave his own thoughts on fluid dynamics and applied mathematics [1]:-

Fluid-dynamicists and applied mathematicians should interact with society at large to help in all aspects of technology, e.g. supersonic flight (and not only its fluid dynamics!), physiological flows, surgical tools and aids, such as diagnostic instruments, pumps and artificial organs. There exist enormous social applications, not only in medicine, but also in other areas. We cannot afford to be stand-offish! A complete integration with other subjects, professions and fields, with society at large, is of the utmost importance for the future of our profession; for the future of fluid dynamics and applied mathematics. Needed is not a vague kind of cooperation, but complete scientific and social integration. Scientists should extend into regions of alien specialities. One should welcome people from other Departments and encourage them to explore, and this should extend to collaboration with the social sciences. In doing pure mathematics there is an absence of responsibility; not so in applied mathematics. Let us return to old-fashioned attitudes and training. There is too much to learn now. Instead of spending eight years in the transfer of skills and knowledge, we should try to instil an attitude, a spirit. One should get back to being a whole man, back to an attitude of responsibility. We should be as responsible as engineers and physicians. It is often said that applied mathematicians act as bridges between mathematics and other disciplines. If you want to be a bridge you must be prepared to carry a load.

During his career, Goldstein gave many lectures series, some of which were written up and published. These include "Linearized theory of supersonic flow" and "Statistical theory of turbulence" both given at the Institute for Fluid Dynamics and Applied Mathematics, University of Maryland in 1950. In this same year he was an invited speaker at the International Congress of Mathematicians, Cambridge, Massachusetts, giving the address Selected problems in gas dynamics. At the Summer Seminar at Boulder, Colorado in 1957 he gave a series of lectures which were written up as 300-page book. Richard Meyer writes in a review:-

To make "mature mathematicians familiar with fluid dynamics'' in 12 lectures is a task on the border, at least, of the possible. With a large minority of the audience composed of distinguished specialists in fluid dynamics, the task is well beyond that border. And the requirement of publication of the lectures cuts off any retreat. These, we may speculate, were some of the reasons for asking the particular author to make the attempt. As would be expected, he shuns resolutely the superficially elegant and the sensational, and the resulting book is an unusual and valuable contribution to the literature.

Finally let us note that Goldstein also wrote on his other passion, namely Zionism, along with applied mathematics. On 15 February 1972, Goldstein gave a lecture at the University of Leeds which was published in the following year as Views on the meaning of Zionism and of applied mathematics fifty years ago and now (1973).

Goldstein received many honours in addition to his election to the Royal Society of London mentioned above. He was elected to the Royal Netherlands Academy of Sciences and Letters in 1950 and to the Finnish Scientific Society in 1975. He was awarded an honorary fellowship of St John's College, Cambridge in 1965, by the Weizmann Institute of Science at Rehovot, Israel in 1971, by the Royal Aeronautical Society in 1971, and by the Institute of Mathematics and its Applications in 1972. He was awarded honorary doctorates by Purdue University (1967), Case Institute of Technology, Cleveland (1967), Technion, Haifa, Israel (1969) and Leeds University (1973). He received the Timoshenko Medal from the American Society of Mechanical Engineers in 1965.

James Lighthill describes Goldstein final years [4]:-

Sydney Goldstein spent the years of his retirement almost entirely at Belmont, increasingly incapacitated physically by illness. In the activity of his mind, mathematics and fluid dynamics ceased to play a significant part but his Jewish faith continued to burn brightly to the end.


 

Books:

  1. J Rom (ed.), Proceedings of the International Symposium on Modern Developments in Fluid Dynamics (Society for Industrial and Applied Mathematics, Philadelphia, Pa., 1977).

Articles:

  1. J Cook, Prof Sydney Goldstein, 85, Dies, New York Times (24 January, 1989).
  2. S Goldstein, Fluid Mechanics in the First Half of this Century, Annual Review of Fluid Mechanics 1 (1969), 1-29.
  3. J Lighthill, Sydney Goldstein, Biographical Memoirs of Fellows of the Royal Society of London 36 (1990), 175-197.
  4. J Lighthill, Obituary: Professor Sydney Goldstein, FRS, Honorary Fellow, Bull. Inst. Math. Appl. 25 (9) (1989), 244-246.
  5. J Lighthill, Goldstein and fluid dynamics, in Proceedings of the International Symposium on Modern Developments in Fluid Dynamics, Haifa, 1973 (Soc. Indust. Appl. Math., Philadelphia, Pa., 1977), x-xviii.

 




الجبر أحد الفروع الرئيسية في الرياضيات، حيث إن التمكن من الرياضيات يعتمد على الفهم السليم للجبر. ويستخدم المهندسون والعلماء الجبر يومياً، وتعول المشاريع التجارية والصناعية على الجبر لحل الكثير من المعضلات التي تتعرض لها. ونظراً لأهمية الجبر في الحياة العصرية فإنه يدرّس في المدارس والجامعات في جميع أنحاء العالم. ويُعجب الكثير من الدارسين للجبر بقدرته وفائدته الكبيرتين، إذ باستخدام الجبر يمكن للمرء أن يحل كثيرًا من المسائل التي يتعذر حلها باستخدام الحساب فقط.وجاء اسمه من كتاب عالم الرياضيات والفلك والرحالة محمد بن موسى الخورازمي.


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