George Johnstone Stoney

George Johnstone Stoney (15 February 1826 – 5 July 1911) was a physicist, a native of Ireland, and of the Anglo-Irish Ascendancy. He is most famous for introducing the term electron as the "fundamental unit quantity of electricity".[1] He had introduced the concept, though not the word, as early as 1874 and 1881, and the word came in 1891.[2]  [3] [4] He published around 75 scientific papers during his lifetime.

Contents

Education and employment positions

Stoney was born at Oakley Park, near Birr, County Offaly, in the Irish Midlands, in an old-established Anglo-Irish family.[5] He attended Trinity College, Dublin, graduating with a B.A. in 1848. From 1848 to 1852 he worked as an astronomy assistant to William Parsons, 3rd Earl of Rosse at Birr Castle, County Offaly, where Parsons had built the world's largest telescope, the 72-inch Leviathan of Parsonstown. Simultaneously Stoney continued to study physics and mathematics and was awarded an M.A. by Trinity College Dublin in 1852.

From 1852 to 1857 he was professor of physics at Queen's College Galway. From 1857 to 1882 he was employed as Secretary of the Queen's University of Ireland, an administrative job based in Dublin. In the early 1880s he moved to the post of superintendent of Civil Service Examinations in Ireland, a post he held until his retirement in 1893. In that year, he took up residence in London. Stoney died in 1911 at his home in Notting Hill, London.[1] During his decades of non-scientific employment responsibilities in Dublin, Stoney continued to do scientific research on his own. He also served for decades as honorary secretary and then vice-president of the Royal Dublin Society, a scientific society modelled after the Royal Society of London, and after his move to London Stoney served on the council of that society too. Additionally he intermittently served on scientific review committees of the British Association for the Advancement of Science from the early 1860s on.

Stoney's scientific output

Stoney published seventy-five scientific papers in a variety of journals, but chiefly in the journals of the Royal Dublin Society. He made significant contributions to cosmic physics and to the theory of gases. He estimated the number of molecules in a cubic millimetre of gas, at room temperature and pressure, from data obtained from the kinetic theory of gases. Stoney's most important scientific work was the conception and calculation of the magnitude of the "atom of electricity". In 1891, he proposed the term 'electron' to describe the fundamental unit of electrical charge, and his contributions to research in this area laid the foundations for the eventual discovery of the particle by J.J. Thomson in 1897.

He was elected a Fellow of the Royal Society in June 1861 on the basis of being the author of papers on "The Propagation of Waves," – "On the Rings seen in Fibrous Specimens of Calc Spar," and Molecular Physics, published in the Transactions of the Royal Irish Academy, et cetera, Distinguished for his acquaintance with the science of Astronomy & General Physics.[6]

The Stoney scale

Contemporary physics has settled on the Planck scale as the most suitable scale for a unified theory. The Planck scale was, however, anticipated by George Stoney.[7] Like Planck after him, Stoney realized that large-scale effects such as gravity and small-scale effects such as electromagnetism naturally imply an intermediate scale where physical differences might be rationalized. This intermediate scale comprises units (Stoney scale units) of mass, length, time etc., yet mass is the cornerstone.

The Stoney mass mS (expressed in contemporary terms):

m_S=\sqrt{\frac{e^2}{4 \pi \varepsilon_0 G}} = \sqrt{\alpha}\, m_P

where ε0 is the permittivity of free space, e is the elementary charge and G is the gravitational constant, and where α is the fine-structure constant and mP is the Planck mass.

Like the Planck scale, the Stoney scale functions as a symmetrical link between microcosmic and macrocosmic processes in general and yet it appears uniquely oriented towards the unification of electromagnetism and gravity . Thus for example whereas the Planck length is the mean square root of the reduced Compton wavelength and half the gravitational radius of any mass, the Stoney length is the mean square root of the 'electromagnetic radius' (see Classical electron radius) and half the gravitational radius of any mass, m:

\ell_P=\sqrt{\frac{\hbar}{m c}\cdot\frac{G m}{c^2}}
\ell_S=\sqrt{\frac{e^2}{4 \pi \varepsilon_0 m c^2}\cdot\frac{G m}{c^2}}

where \hbar \ is the reduced Planck's constant and c is the speed of light. It should be noted however that these are only mathematical constructs since there must be some practical limit to how small a length can get. If the Stoney length is the minimum length then either a body's electromagnetic radius or its half gravitational radius is a physical impossibility, since one of these must be smaller than the Stoney length. If Planck length is the minimum then either a body's reduced Compton wavelength or its half gravitational radius is a physical impossibility since one of these must be smaller than the Planck length. Moreover, the Stoney length and Planck length cannot both be the minimum length.

According to contemporary convention, Planck scale is the scale of vacuum energy, below which space and time do not retain any physical significance. This prescription mandates a general neglect of the Stoney scale within the scientific community today. Previous to this mandate, Hermann Weyl made a notable attempt to construct a unified theory by associating a gravitational unit of charge with the Stoney length. Weyl's theory led to significant mathematical innovations but his theory is generally thought to lack physical significance.[8][9]

Other

The woman Stoney married was one of his cousins. They had two sons and three daughters. For most of his decades in Dublin, Stoney resided in the Dundrum, Dublin neighbourhood. The street that he lived on was later re-named Stoney Road in his memory. After Stoney died in London, his cremated ashes were buried in Dundrum, Dublin.

One of Stoney's sons, George Gerald Stoney, was a scientist. But a more scientifically notable relative was Stoney's nephew, the Dublin-based physicist George FitzGerald (1851–1901). Stoney and FitzGerald were in regular communication on scientific matters. In addition, on political matters, both Stoney and FitzGearld were active opponents of the Irish Home Rule Movement. In their political opinion, the spirit of Irish Home Rule and later Irish nationalism was contrary to the spirit of science. Stoney resigned from his job as Secretary of Queen's University of Ireland in 1882 in objection to a government decision to introduce "sectarianism" into the system; i.e., Stoney wanted to keep the system non-denominational, but the government acceded to Irish Catholic demands for Catholic institutions.

Craters on Mars and the Moon are named in his honour.

See also

References and external links

  1. ^ a b Obituary in The Daily Express newspaper (6 July 1911). "George Johnstone Stoney 1826–1911". http://www.offalyhistory.com/articles/264/1/George-Johnstone-Stoney-1826-1911/Page1.html. 
  2. ^ Stoney Uses the Term Electron
  3. ^ Jammer, Max (1956). Concepts of Force – A Study of the Foundations of Dynamics. New York: Dover Publications, Inc.. ISBN 0-486-40689-X. 
  4. ^ Stoney, G.J. (1881). "On the Physical Units of Nature." Phil. Mag. [5] 11, 384.
  5. ^ McCartney, Mark; Andrew Whitaker (2003). Physicists of Ireland: Passion and Precision. CRC Press. pp. 126. ISBN 9780750308663. 
  6. ^ "Library and Archive catalogue". Royal Society. http://www2.royalsociety.org/DServe/dserve.exe?dsqIni=Dserve.ini&dsqApp=Archive&dsqCmd=Show.tcl&dsqDb=Persons&dsqPos=2&dsqSearch=%28Surname%3D%27stoney%27%29. Retrieved 22 October 2010. 
  7. ^ Stoney G. On The Physical Units of Nature, Phil.Mag. 11, 381–391, 1881
  8. ^ O'Raifeartaigh L., The Dawning of Gauge Theory, Princeton Uni Press, 1997
  9. ^ Gorelik G., Herman Weyl and Large Numbers in Relativistic Cosmology, Einstein Studies in Russia, Ed Balashov Y. and Vizgin V., Boston (Birkhaeuser) 2002