Victoria University of Manchester
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The Victoria University of Manchester (VUM) was a university in Manchester in England. On October 1, 2004 it merged with the University of Manchester Institute of Science and Technology to form a new institution called the University of Manchester. The Victoria University of Manchester was almost invariably known in recent times by its working title of The University of Manchester and only reverted to its full title to distinguish it from the new merged institution.
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[edit] History
The university began in 1851 as Owens College (named after John Owens), a textile merchant who left a bequest of £96,942 for the purpose. It moved to its current location in 1873 the building was designed by Alfred Waterhouse, and was granted its Royal Charter in 1880, becoming the first institution of the federal Victoria University. In 1884, University College Liverpool joined the University, followed, in 1887 by the Yorkshire College in Leeds.
In 1903, the University's college in Liverpool left the Victoria University to become the independent University of Liverpool and Leeds followed in 1904 to become the University of Leeds. The remaining Manchester site was renamed Victoria University of Manchester.
It was commonly known as the University of Manchester, and had over 18,000 full-time students (including 2500 international students from more than 120 countries) by the time it merged with UMIST. It was one of the top universities in the country, regularly getting top ratings for research [1].
On March 5, 2003 it was announced that the University was to merge with UMIST on October 1 2004, to form the largest conventional university in the UK. The new institution is simply called The University of Manchester. In legal terms both the Victoria University of Manchester and UMIST ceased to exist when the University of Manchester came into existence on October 1 2004.
[edit] Motto and Arms
The motto of the university was "Arduus Ad Solem", literally meaning "striving towards the sun". It is a metaphor for aspiring to enlightenment. The motto is a quote from Virgil's Aeneid, but the archives do not record the reasons for its choice. In the Aeneid, the quote refers to a serpent and the sun, both of which feature in the university coat of arms.
[edit] Famous alumni
[edit] Physics
Name | Position(s) | Notability |
---|---|---|
Hans Bethe | Temporary Lecturer (1933–1934) [1] | Nobel Prize in Physics, 1967, "for his contributions to the theory of nuclear reactions, especially his discoveries concerning the energy production in stars". |
Patrick Blackett | Director and Langworthy Professor of Physics (1937–1953) | Nobel Prize in Physics, 1948, "for his development of the Wilson cloud chamber method, and his discoveries therewith in the fields of nuclear physics and cosmic radiation" |
Niels Bohr | Research Staff and Schuster Reader (1911–1916) | Nobel Prize in Physics, 1922, "for his services in the investigation of the structure of atoms and of the radiation emanating from them" |
William Lawrence Bragg | Director and Langworthy Professor of Physics (1919–1937) | Nobel Prize in Physics, 1915, with his father, William Henry Bragg "For their services in the analysis of crystal structure by means of X-rays." |
James Chadwick | BSc, MSc and Researcher (1908–1913) | Nobel Prize in Physics, 1935, "for the discovery of the neutron" |
John Cockcroft | Studied mathematics under Horace Lamb in 1914–1915, and received BSc at VUM | Nobel Prize in Physics, 1951, with Ernest Walton "for their pioneer work on the transmutation of atomic nuclei by artificially accelerated atomic particles". |
Arthur Stanley Eddington | Graduated 1902 and became a lecturer in 1905 | Founder of modern Astronomy. He made important contributions to the general theory of relativity and led an expedition team to validate it. |
Hans Geiger | Researcher (1906–1914) | Did the original "Rutherford scattering" experiment with Marsden (also the Geiger-Marsden experiment). Devised the famous Geiger ionization counter. |
Douglas Hartree | Professor (1929–1946) | Built and operated a differential analyser (a famous mechanical calculator) to evaluate the wave functions of multi-electron atoms. |
George de Hevesy | Research Staff (1910–1913) | Nobel prize in 1943 for his work on the use of isotopes as tracers in the study of chemical processes. |
John Lennard-Jones | Student (1912), Lecturer in Mathematics (1919–1922) | Founder of modern theoretical chemistry. Lennard-Jones potential and LJ fluid are named after him. |
Bernard Lovell | Professor (1951–1990) | Creator of the giant radio-telescope (the first large radio-telescope in the world with a diameter of 218 feet) at Jodrell Bank and pioneered the field of radio astronomy. |
Ernest Marsden | Was born in Lancashire in 1888. He won scholarships to attend grammar school and gain entry to Manchester University. It was here he met Rutherford in his honours year. Rutherford suggested a project to investigate the backwards scattering of alpha particles from a metal foil. He did this in conjunction with Hans Geiger (of Geiger counter fame), and it proved to be the key experiment in the demise of the Plum pudding model of the atom leading directly to Rutherford's nuclear atom. Rutherford also recommended Marsden for the position of physics professor at what is now Victoria University in Wellington. | |
Henry Moseley | Identified atomic number as the nuclear charges. He studied under Rutherford and brilliantly developed the application of X-ray spectra to study atomic structure; his discoveries resulted in a more accurate positioning of elements in the Periodic Table by closer determination of atomic numbers . Moseley was nominated for the 1915 Nobel Prize but was unfortunately killed in action in August 1915 and could not receive the prize. | |
Nevill Francis Mott | Lecturer (1929–1930) | Awarded Nobel prize in 1977, for his fundamental theoretical investigations of the electronic structure of magnetic and disordered systems. |
John Henry Poynting | Student (1867–1872), Lecturer (1876–1879) | Left to become Professor at Mason College (which became Birmingham University). He wrote on electrical phenomena and radiation and is best known for Poynting's vector. In 1891 he determined the mean density of the Earth and made a determination of the gravitational constant in 1893. The Poynting-Robertson effect was related to the theory of relativity. |
George Rochester | Discovered strange particles in 1947 with Clifford C Butler. C C Butler co-discovered strange particles in 1947. Went on to be head of department at Imperial College and then VC at Loughborough. | |
Ernest Rutherford | Langworthy Professor of Physics (1907–1919) | Awarded Nobel prize in 1908, for his investigations into the disintegration of the elements and the chemistry of radioactive substances. He was the first man to split the atom. |
Arthur Schuster | Langworthy Professor of Physics (1888–1907) | Made many contributions to optics and astronomy. Schuster's interests were wide-ranging: terrestrial magnetism, optics, solar physics, and the mathematical theory of periodicities. He introduced meteorology as a subject studied in British universities. |
J. J. Thomson | Studied and researched (1871–1876) | Discovered the electron; awarded Nobel prize in 1906. |
Charles Thomson Rees Wilson | Student (1884–1887) | Invented the expansion cloud chamber and was awarded Nobel prize in 1927. |
Arnold Wolfendale | BSc 1948 and PhD 1954 in cosmic rays. Lecturer (1953–1956) | 14th Astronomer Royal |
[edit] Physiology and Medicine
- Archibald Vivian Hill, Brackenburg Professor of Physiology, 1920–1923. won the Nobel Prize in Physiology or Medicine in 1922 for his discovery relating to the production of heat in muscles.
[edit] Chemistry
- Melvin Calvin (awarded nobel prize in 1961), for his research on the carbon dioxide assimilation in plants.
- Arthur Harden (awarded nobel prize in 1929), for investigations on the fermentation of sugar and fermentative enzymes.
- Walter Howarth (awarded nobel prize in 1937), for his investigations on carbohydrates and vitamin C.
- John Charles Polanyi (awarded nobel prize in 1986), for his contributions concerning the dynamics of chemical elementary processes.
- Robert Robinson (awrded nobel prize in 1947), for his investigations on plant products of biological importance, especially the alkaloids.
- Michael Smith (awarded nobel prize in 1993), for his fundamental contributions to the establishment of oligonucleiotide-based, site-directed mutagenesis and its development for protein studies.
- Alexander Todd (awarded nobel prize in 1957), for his work on nucleotides and nucleotide co-enzymes.
[edit] Economics
- John Hicks (1974) for his pioneering contributions to general economic equilibrium theory and welfare theory.
- Sir Arthur Lewis (1979) for his pioneering research into economic development research with particular consideration of the problems of developing countries.
[edit] Computer science and mathematics
- Frank Adams was a leading figure in algebraic topology and homotopy theory. He developed methods which led to important advances in calculating the homotopy groups of spheres (a problem which is still unsolved), including the invention of the Adams operations.
- M. S. Bartlett, professor of mathematical statistics from 1947 to 1960 made important contributions to the analysis of data with spatial and temporal patterns. He is also known for his work in the theory of statistical inference and in multivariate analysis.
- Sydney Chapman, developed important theory on thermal diffusion in highly ionized gases, magnetic storms, instability along magnetic neutral lines, noctilucent clouds and the fundamentals of gas dynamics.
- Harold Davenport worked in Manchester as a contemporary of Erdős and Mordell.
- Paul Erdős was one of the most prolific mathematicians of the 20th century. The Euler of our time, he posed and solved many problems in number theory and other areas. He was a founder of the field of extremal combinatorics, of major importance in theoretical computer science. He wrote 1,500 papers. In his early career, he held a post-doctoral fellowship at Manchester University and subsequently became an itinerant mathematician. Awarded the Cole Prize of the American Mathematical Society.
- Sydney Goldstein was one of the most influential theoretical fluid mechanicians in this century. He is best known for his work in boundary layer theory where the Goldstein singularity is named after him.
- Brian Hartley is best known for his work in group theory. His book Rings, Modules and Linear Algebra (written with T. O. Hawkes) is a widely used undergraduate text.
- Tom Kilburn, along with Freddie Williams, invented the Williams-Kilburn Tube and the first modern electronic computer in the world, the Manchester Mark 1.
- Sir Horace Lamb was one of the six professors appointed when Manchester University received its Royal Charter (his chair was in Mathematics, and Osborne Reynolds was given the Chair in Engineering). He made many important contributions to applied mathematics, including the areas of acoustics and fluid dynamics. His book Hydrodynamics (first published in 1895) was for many years the standard text on the subject and is still essential reading for researchers. Lamb's main field of research was solid mechanics, and he made careful studies of the vibrations of spherical bodies which aided understanding in seismology. Research on waves in layered media led to the discovery of Lamb waves.
- James Lighthill was one of the most influential applied mathematicians of the 20th century. He made important contributions to the modern developments in theoretical aerodynamics and aeroacoustics (Lighthill's eighth power law) and was one of the founding fathers of the field of biofluiddynamics. He is also founder of IMA.
- John Littlewood is famous for his work on the theory of series, the Riemann zeta function, inequalities and the theory of functions. He held a lectureship at the University of Manchester from 1907 to 1910.
- Kurt Mahler spent several periods of his academic life at Manchester. Major themes of his work were p-adic numbers, p-adic diophantine approximation, geometry of numbers and Mahler measures.
- Edward Milne, a leading figure in the study of radiative equilibrium, the structure of stellar atmospheres, theory of relativity and the interior structure of stars. President of London Maths Society.
- Louis Mordell was a pure mathematician who made important contributions in number theory.
- Bernhard Neumann spent more than a decade in Manchester. He is one of the leading figures in group theory.
- Max Newman made important contributions to combinatorial topology, Boolean algebras and mathematical logic. He directed the now-famous Colossus cryptanalysis program in WWII.
- Osborne Reynolds is famous for his work in fluid mechanics. In 1886 he formulated a theory of lubrication and three years later he developed the standard mathematical framework used in the study of turbulence. The Reynolds number used in modelling fluid flow is named after him (his students include J. J. Thomson, who discovered the electron).
- Lewis Fry Richardson was a scientist who was the first to apply mathematics, in particular the method of finite differences, to predicting the weather (the father of CFD). He made contributions to calculus and to the theory of diffusion, in particular eddy-diffusion in the atmosphere. The Richardson number, a fundamental quantity involving gradients of temperature and wind velocity, is named after him.
- Alan Turing, founder of computer science and AI. ACM Turing award is named after him.
- Freddie Williams, along with Tom Kilburn, invented the Williams-Kilburn Tube and the first modern electronic computer in the world, the Manchester Mark 1.
- Ludwig Wittgenstein who is best known for his work in philosophy undertook aeronautical research in Manchester. Needing to understand more mathematics for his research he began a study which soon involved him in the foundations of mathematics.
[edit] Architecture
[edit] See also
[edit] References
- ^ Hans Bethe biography. Nobel Prize Committee. Retrieved on 2006-12-20.