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George Rochester

From Wikipedia, the free encyclopedia

For the California politician, see George W. Rochester.

George Dixon Rochester
Born(1908-02-04)4 February 1908
Wallsend
Died26 December 2001(2001-12-26) (aged 93)
Durham
NationalityBritish
Known forCo-discovery, with Sir Clifford Charles Butler, of the kaon
SpouseIdaline Bayliffe
ChildrenDorothy and Anthony
Scientific career
FieldsPhysics
InstitutionsStockholm University
University of California, Berkeley
Victoria University of Manchester
Durham University

George Dixon Rochester, FRS (4 February 1908 – 26 December 2001) was a British physicist known for having co-discovered, with Sir Clifford Charles Butler, a subatomic particle called the kaon.[1]

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Transcription

So I'm a physicist, and one of the things I am involved here, at the University of Rochester, is running a nano-center. And for most people, you think of nanotechnology as, for example, nanochips, tiny little electronic circuits, but what you wouldn't expect is that nanotechnology is at the heart of the earliest form of photography - the daguerreotype. The daguerreotype is the first successful medium of photography. And it was a miraculous discovery by a Frenchman, Louis Daguerre. In 1839, it became the predominant mode of photography from the moment that it was invented until about the Civil War. The image that's formed in the daguerreotype is actually nanotechnology at work. If you were to take the nanoparticles that form the image on the daguerreotype, you'd have to have between 100-1000 of them, stacked side by side, to be as big as a human hair. George Eastman house was privileged to have one of the great collections of daguerreotypes in the world. Altogether in our collection, it’s about 5000 daguerreotypes and they’re from all over the world. And as we studied the collection here at the George Eastman House and actually put on a major exhibition, we saw in real time some deterioration that we couldn’t explain. And that raised a lot of questions for us. And in pursuing that, we found that the science was getting more and more complex and we needed a research capacity. So we became involved with the George Eastman House in the project to look at that nanotechnology, understand how it happens, and also, how can we preserve it and save it. One thing that we never would have expected is that the daguerreotype is a biologically active surface. We discovered that on essentially every daguerreotype we looked at, there are small colonies of fungi growing, and those fungi are in fact damaging the surface. We’ve worked to develop an argon, item level housing that could be replenished and monitored so that we can measure the oxygen inside the case. Some day, we'll be able to understand better how to remediate deteriorated daguerreotype, but this will hold them in a state of suspended animation without any further deterioration. Personally, what actually brought me into this project, was seeing a fantastic daguerreotype that was made of the Cincinnati skyline. And what's remarkable about that daguerreotype is that if you blow it up, and blow it up, and blow it up, the level of resolution and detail in this nanotechnology photograph is fantastic. A well-made daguerreotype by 1840-45 is able to be enlarged about 20-30 times and that’s not possible in most photography. You’d have to have a very very high megapixel camera to do that. It is the first form of photography but it's also perhaps one of the first forms of controlled nanotechnology. The people who discovered how to make this image almost 200 years ago, discovered how to put nanotechnology to work. They didn't mean to, but they did. A production of the University of Rochester. Please visit us online and subscribe to our channel for more videos.

Biography

Rochester was born in Wallsend, the only child of Thomas Rochester, a blacksmith, who was later a toolsmith in the Swan Hunter shipyard, and his wife, Ellen, née Dixon.

After attending local primary schools, Rochester went to Wallsend Grammar School in 1920, where he did well in chemistry and physics, and gained a scholarship to Armstrong College, Newcastle. He graduated with first-class honours in physics in 1930 (delayed by an attack of measles), under the guidance of W E Curtis (later an FRS).[2] He gained a postgraduate scholarship and joined Curtis’s research group in 1931. After an unsatisfying start, working on the band spectrum of helium, he and fellow-student H G Howell decided between them to work on the spectra of heavy diatomic molecules, in particular compounds of tin, lead, bismuth, antimony, thallium and manganese. A great deal was accomplished while Curtis was on extended holiday, the results of which appeared in Rochester's first paper.[3] The analysis of these and similar results occupied the two colleagues and other collaborators for the next five years.[4] The consequence for Rochester was the winning of two awards which enabled him to spend 1934-5 working on band spectra with Professor Erik Hulthén at the Physical Institute of the University of Stockholm. During his time at Armstrong College he had gained an MSc in 1932 and a PhD in 1937.[1]

Curtis suggested that Rochester apply for a Commonwealth Fund Fellowship. After an interview in London he was awarded it for the years 1935-37 at the University of California, Berkeley. He set sail in July 1935 from Liverpool to New York on the Samaria. He worked on halide spectra using excellent equipment, but also saw work underway on the development of the cyclotron, and met many notable visitors including: Niels Bohr, J A Wheeler, R A Millikan, Arthur Compton and John Cockcroft.

In 1937 Rochester crossed the USA to New York, where he boarded the Queen Mary en route to Southampton, arriving on 14 June. He attended an interview and was appointed assistant lecturer at the Victoria University of Manchester under Lawrence Bragg, just before Bragg moved to the National Physical Laboratory in Teddington. The post of Langworthy Professor of Physics was next filled by Patrick (later Lord) Blackett, whose group Rochester joined in 1938, this time to work on cosmic rays.

War came in 1939, and he was sent to the newly-operational radar station at Staxton Wold,[5] near Scarborough. But after a few months he was recalled to Manchester to help run the two-year intensive degree courses in what was one of just a few physics departments kept open during the war.[4] He was also University Fire Officer, work done mainly in the evenings and at weekends. This left time for him and cosmic ray physicist Lajos Jánossy to undertake research on the penetration of cosmic rays at sea level. This research continued after the war, initially still with Jánossy, but later with Clifford Butler, and led eventually to the discovery of V particles.[6]

Blackett moved from Manchester to Imperial College in 1953, leaving Rochester as acting director of the Physical Laboratories, until he was offered the Chair in Physics at Durham. He was there from 1955 until the end of his career. By “attracting excellent staff and funds for new buildings and research, he built the Durham department into a vibrant and friendly institution”.[7]

Rochester’s contributions to physics are commemorated by the Rochester building which he carefully designed, and the home of the physics department at Durham; the Rochester Prize[8] for the top performing first year Science undergraduate student; and the annual Rochester Lecture.[9] He was elected a Fellow of the Royal Society in 1958. In the period 1955 to 1966, Rochester was nominated 22 times for a Nobel Prize in Physics, by such eminent scientists as Blackett (seven times), Cockcroft (four times) and Chadwick.[10]

Family

George Rochester met his future wife, Idaline Bayliffe, when they were undergraduates at Durham through the Student Christian Movement (SCM), of which she was secretary. "[Ida] had studied English at Durham: in Rochester's subsequent professorial career, when he returned junior lecturers' research papers 'duly corrected', it was not generally known that it was she who had had a hand in correcting their prose".[7]

They were engaged in 1935, just before George sailed to the USA, and married on 18 April 1938 at John Street Methodist Church, Cullercoats. They had two children: Dorothy, born in 1942, and Anthony in 1946. Ida, like her husband, “was a pillar of the local Methodist Church, from which they gained much inner strength”.[1] She outlived him by six days.

George Dixon Rochester died in Durham of heart failure on 26 December 2001.

References

  1. ^ a b c Wolfendale, Arnold (August 2002). "Obituary: George Dixon Rochester". Physics Today. 55 (8): 63–64. Bibcode:2002PhT....55h..63W. doi:10.1063/1.1510290.
  2. ^ "Physics at Newcastle: Prof. W E Curtis, FRS". Nature. 176 (4497): 815. 29 October 1955. Bibcode:1955Natur.176Q.815.. doi:10.1038/176815a0. S2CID 10024675.
  3. ^ Howell, H G; Rochester, G D (1934). "Diatomic Spectra". Proc. Un. Durham Phil. Soc. 9: 126–132.
  4. ^ a b Wolfendale, Arnold (1 December 2003). "George Dixon Rochester. 4 February 1908 – 26 December 2001". Biographical Memoirs of Fellows of the Royal Society. 49: 415–429. doi:10.1098/rsbm.2003.0024. S2CID 71321870.
  5. ^ Not Saxton Wold, as stated in the Roy. Soc. memoir
  6. ^ Rochester, G D; Cutler, C C (1947). "Evidence for the Existence of New Unstable Elementary Particles". Nature. 160 (4077): 855–857. Bibcode:1947Natur.160..855R. doi:10.1038/160855a0. PMID 18917296. S2CID 33881752.
  7. ^ a b "Rochester, George Dixon". Oxford Dictionary of National Biography (online ed.). Oxford University Press. doi:10.1093/ref:odnb/76670. (Subscription or UK public library membership required.)
  8. ^ "The Rochester Prize". Durham University: Faculty of Science. Retrieved 18 November 2020.
  9. ^ "The Rochester Lecture Series". Durham University. Retrieved 18 November 2020.
  10. ^ "The Nobel Prize: Nomination Archive: George Dixon Rochester". The Nobel Prize. April 2020. Retrieved 18 November 2020.
This page was last edited on 28 January 2023, at 20:48
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