John Strutt, 3rd Baron Rayleigh

For his great-grandfather, see John Strutt (1727–1816).

John William Strutt, 3rd Baron Rayleigh (/ˈreɪli/ RAY-lee;^[2] 12 November 1842 – 30 June 1919), was a British physicist and hereditary peer who received the Nobel Prize in Physics in 1904 "for his investigations of the densities of the most important gases and for his discovery of argon in connection with these studies".

The Right Honourable The Lord Rayleigh OM PC FRS
Rayleigh in 1904
Chancellor of the University of Cambridge
In office 1908–1919
Preceded by	Spencer Cavendish, 8th Duke of Devonshire
Succeeded by	Arthur Balfour, 1st Earl of Balfour
39th President of the Royal Society
In office 1905–1908
Preceded by	William Huggins
Succeeded by	Archibald Geikie
Personal details
Born	John William Strutt (1842-11-12)12 November 1842 Maldon, England, UKGBI
Died	30 June 1919(1919-06-30) (aged 76) Witham, England, UKGBI
Education	Eton College Harrow School
Alma mater	Trinity College, Cambridge (BA, MA)
Known for	Discovering argon Rayleigh scattering Rayleigh waves Rayleigh number Rayleigh flow Rayleigh–Taylor instability Rayleigh–Jeans law
Spouse	Evelyn Balfour ​ (m. 1871)​
Children	3, including Robert
Family	Balfour (by marriage)
Awards	See list Smith's Prize (1865) FRS (1873) Royal Medal (1882) De Morgan Medal (1890) Matteucci Medal (1894) Barnard Medal for Meritorious Service to Science (1895) Faraday Lectureship Prize (1895) Copley Medal (1899) Order of Merit (1902) Nobel Prize in Physics (1904) RSA Albert Medal (1905) Elliott Cresson Medal (1913) Rumford Medal (1914)
Scientific career
Title	Cavendish Professor of Physics (1879–84)
Fields	Acoustics fluid dynamics optics
Institutions	University of Cambridge Terling Place Royal Institution
Academic advisors	James Clerk Maxwell Edward Routh[1] George Stokes[1]
Notable students	Jagadish Bose[1] J. J. Thomson[1]
Signature

Rayleigh provided the first theoretical treatment of the elastic scattering of light by particles much smaller than the light's wavelength, a phenomenon now known as Rayleigh scattering, which notably explains why the sky is blue. He studied and described transverse surface waves in solids, now known as Rayleigh waves. He contributed extensively to fluid dynamics, with concepts such as the Rayleigh number (a dimensionless number associated with natural convection), Rayleigh flow, the Rayleigh–Taylor instability, and Rayleigh's criterion for the stability of Taylor–Couette flow.

Rayleigh also formulated the circulation theory of aerodynamic lift. In optics, he proposed a well-known criterion for angular resolution. His derivation of the Rayleigh–Jeans law for classical black-body radiation later played an important role in the birth of quantum mechanics (see ultraviolet catastrophe). His textbook, The Theory of Sound (1877), is still used today by acousticians and engineers. He introduced the Rayleigh test for circular non-uniformity, which the Rayleigh plot visualises.

Rayleigh served as President of the Royal Society from 1905 to 1908, and as Chancellor of the University of Cambridge from 1908 until his death in 1919.

Biography

John William Strutt was born on 12 November 1842 at Langford Grove, Maypole Road in Maldon, England,^[3] the son of John James Strutt, 2nd Baron Rayleigh, and Clara Elizabeth La Touche. In his early years, he suffered from frailty and poor health.^[4]

Strutt attended Eton College and Harrow School (each for only a short period),^[5] before entering Trinity College, Cambridge, in 1861, where he studied mathematics. In 1865, he received his B.A. (Senior Wrangler and Smith's Prizeman), and was elected a Fellow of Trinity College the following year. He obtained an M.A. in 1868.^[6][5]

In 1871, Stutt resigned from his fellowship to marry Evelyn Balfour, the daughter of James Maitland Balfour, with whom he had three sons. In 1873, on the death of his father, he inherited the Barony of Rayleigh. On 12 June, he was elected a Fellow of the Royal Society.

In 1879, following the death of James Clerk Maxwell, Rayleigh was appointed Cavendish Professor of Physics at the University of Cambridge. In 1883, he first described dynamic soaring by seabirds in Nature.^[7] The following year, he resigned as Cavendish Professor to continue his experimental work at Terling Place.^[5]

From 1887 to 1905, Rayleigh was Professor of Natural Philosophy at the Royal Institution. During this period, he carefully and precisely measured atomic mass of oxygen and hydrogen, and by 1892 he moved on to nitrogen. By isolating nitrogen in different ways he discovered a small but significant difference, which indicated a heavier inert gas present in the air besides nitrogen. William Ramsay joined this research topic, and in August 1894 they discovered argon.^[8][9] In 1904, Rayleigh and Ramsay were awarded the Nobel Prizes in Physics and Chemistry, respectively; both for research related to the discovery of argon.

Around 1900, Rayleigh developed the duplex (combination of two) theory of human sound localisation using two binaural cues, interaural phase difference (IPD) and interaural level difference (ILD) (based on analysis of a spherical head with no external pinnae). The theory posits that we use two primary cues for sound lateralisation, using the difference in the phases of sinusoidal components of the sound and the difference in amplitude (level) between the two ears.

Caricature of Lord Rayleigh in the London magazine Vanity Fair, 1899

Rayleigh received the degree of Doctor mathematicae (honoris causa) from the Royal Frederick University on 6 September 1902, when they celebrated the centennial of the birth of mathematician Niels Abel.^[10][11]

From 1905 to 1908, Rayleigh served as President of the Royal Society. From time to time, he participated in the House of Lords; however, he spoke up only if politics attempted to become involved in science.

During the First World War, Rayleigh was President of the Advisory Committee for Aeronautics, which was located at the National Physical Laboratory and chaired by Richard Glazebrook.^[12]

In 1919, Rayleigh served as President of the Society for Psychical Research.^[13] As an advocate that simplicity and theory be part of the scientific method, he argued for the principle of similitude.

Rayleigh died on 30 June 1919 in Witham at the age of 76, and was buried in the graveyard of All Saints' Church in Terling.^[14] His son Robert, a physicist, succeeded him as Baron Rayleigh.^[5]

Religious views

Rayleigh was an Anglican. Though he did not write about the relationship between science and religion, he retained a personal interest in spiritual matters.^[15] When his scientific papers were to be published in a collection by the Cambridge University Press, Strutt wanted to include a quotation from the Bible, but he was discouraged from doing so, as he later reported:

When I was bringing out my Scientific Papers I proposed a motto from the Psalms, "The Works of the Lord are great, sought out of all them that have pleasure therein." The Secretary to the Press suggested with many apologies that the reader might suppose that I was the Lord.^[16][17]

Still, he had his wish and the quotation was printed in the five-volume collection of scientific papers. In a letter to a family member, he wrote about his rejection of materialism and spoke of Jesus Christ as a moral teacher:

I have never thought the materialist view possible, and I look to a power beyond what we see, and to a life in which we may at least hope to take part. What is more, I think that Christ and indeed other spiritually gifted men see further and truer than I do, and I wish to follow them as far as I can.

— Rayleigh (1910)^[18][19][20]

He held an interest in parapsychology and was an early member of the Society for Psychical Research (SPR). He was not convinced of spiritualism but remained open to the possibility of supernatural phenomena.^[21] Rayleigh was the president of the SPR in 1919. He gave a presidential address in the year of his death but did not come to any definite conclusions.^[22][23]

Recognition

Awards

• 1865: Smith's Prize of the University of Cambridge
• 1866: elected an Honorary Member of the Manchester Literary and Philosophical Society^[24]
• 1873: elected a Fellow of the Royal Society
• 1882: Royal Medal of the Royal Society
• 1886: elected a Member of the American Philosophical Society
• 1890: De Morgan Medal of the London Mathematical Society
• 1894: Matteucci Medal of the Italian Society of Sciences
• 1895: Faraday Lectureship Prize of the Royal Society of Chemistry
• 1895: Barnard Medal for Meritorious Service to Science of Columbia University
• 1897: elected a Member of the Royal Swedish Academy of Sciences
• 1899: Copley Medal of the Royal Society
• 1904: Nobel Prize in Physics of the Royal Swedish Academy of Sciences
• 1905: Albert Medal of the Royal Society of Arts
• 1913: Elliott Cresson Medal of the Franklin Institute
• 1914: Rumford Medal of the Royal Society

Honours

A lunar crater, as well as a Martian crater, are named in his honour.^[25][26] The asteroid 22740 Rayleigh was named after him on 1 June 2007.^[27] A type of surface waves are known as Rayleigh waves, and the elastic scattering of electromagnetic waves is called Rayleigh scattering. The rayl, a unit of specific acoustic impedance, is also named for him.

Rayleigh was among the original recipients of the Order of Merit (OM) in the 1902 Coronation Honours list published on 26 June 1902,^[28] and received the order from King Edward VII at Buckingham Palace on 8 August 1902.^[29][30]

Sir William Ramsay, his co-worker in the investigation to discover argon, described Rayleigh as "the greatest man alive" while speaking to Lady Ramsay during his last illness.^[31]

H. M. Hyndman said of Rayleigh that "no man ever showed less consciousness of great genius".^[31]

In honour of Lord Rayleigh, the Institute of Acoustics sponsors the Rayleigh Medal (established in 1970) and the Institute of Physics sponsors the John William Strutt, Lord Rayleigh Medal and Prize (established in 2008).

Many of the papers that he wrote on lubrication^[32] are now recognized as early classical contributions to the field of tribology. For these contributions, he was named as one of the 23 "Men of Tribology" by Duncan Dowson.^[33]

There is a memorial to him by Derwent Wood in St Andrew's Chapel at Westminster Abbey.^[34]

Publications

Theory of sound, 1894

• The Theory of Sound vol. I (London : Macmillan, 1877, 1894) (alternative link: Bibliothèque Nationale de France OR (Cambridge: University Press, reissued 2011, ISBN 978-1-108-03220-9)
• The Theory of Sound vol.II (London : Macmillan, 1878, 1896) (alternative link: Bibliothèque Nationale de France) OR (Cambridge: University Press, reissued 2011, ISBN 978-1-108-03221-6)
• Scientific papers (Vol. 1: 1869–1881)^[35] (Cambridge : University Press, 1899–1920, reissued by the publisher 2011, ISBN 978-0-511-70396-6)
• Scientific papers (Vol. 2: 1881–1887)^[35] (Cambridge : University Press, 1899–1920, reissued by the publisher 2011, ISBN 978-0-511-70397-3)
• Scientific papers (Vol. 3: 1887–1892)^[35] (Cambridge : University Press, 1899–1920, reissued by the publisher 2011, ISBN 978-0-511-70398-0)
• Scientific papers (Vol. 4: 1892–1901)^[35] (Cambridge : University Press, 1899–1920, reissued by the publisher 2011, ISBN 978-0-511-70399-7)
• Scientific papers (Vol. 5: 1902–1910) (Cambridge : University Press, 1899–1920, reissued by the publisher 2011, ISBN 978-0-511-70400-0)
• Scientific papers (Vol. 6: 1911–1919) (Cambridge : University Press, 1899–1920, reissued by the publisher 2011, ISBN 978-0-511-70401-7)

See also

Main article: List of things named after Lord Rayleigh

• Acoustic levitation
• Acoustic radiation pressure
• Aeolian harp
• Breath-figure self-assembly
• Calibrated airspeed
• Capillary breakup rheometry
• Clark cell
• Dawes' limit
• Extremal principles in non-equilibrium thermodynamics
• Eigenvalue perturbation
• Group velocity
• Hanle effect
• Helmholtz minimum dissipation theorem
• Laminar–turbulent transition
• Langmuir–Blodgett trough
• List of presidents of the Royal Society
• Machmeter
• Moffatt eddies
• Multiple scattering theory
• Parametric oscillator
• Rayl, a unit of specific acoustic impedance.
• Rayleigh frequency
• Rayleigh–Sommerfeld diffraction theory
• Rayleigh mixture distribution
• Rayleigh Medal (Institute of Acoustics)
• Rayleigh Medal (Institute of Physics)
• Rayleigh bandwidth (signal processing)
• Rayleigh law
• Rayleigh quotient iteration
• Rayleigh's quotient in vibrations analysis
• Rayleigh sky model
• Representative layer theory
• Talbot effect
• Thermoacoustics
• Thermoacoustic heat engine
• Virial theorem
• Waveguide (acoustics)
• Waveguide (radio frequency)
• WKB approximation