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John Tyndall

John Tyndall FRS (/ˈtɪndəl/; 2 August 1820 – 4 December 1893) was a prominent 19th-century Irish physicist. His scientific fame arose in the 1850s from his study of diamagnetism. Later he made discoveries in the realms of infrared radiation and the physical properties of air, proving the connection between atmospheric CO2 and what is now known as the greenhouse effect in 1859.

This article is about the scientist. For the far-right activist, see John Tyndall (far-right activist). For the Canadian poet, see John Tyndall (poet).

John Tyndall

(1820-08-02)2 August 1820

(1893-12-04)4 December 1893 (aged 73)

Haslemere, Surrey, England, UK

Irish

Royal Medal (1853)
Rumford Medal (1864)

Tyndall also published more than a dozen science books which brought state-of-the-art 19th century experimental physics to a wide audience. From 1853 to 1887 he was professor of physics at the Royal Institution of Great Britain in London. He was elected as a member to the American Philosophical Society in 1868.[3]

Early scientific work[edit]

Tyndall's early original work in physics was his experiments on magnetism and diamagnetic polarity, on which he worked from 1850 to 1856. His two most influential reports were the first two, co-authored with Knoblauch. One of them was entitled "The magneto-optic properties of crystals, and the relation of magnetism and diamagnetism to molecular arrangement", dated May 1850. The two described an inspired experiment, with an inspired interpretation. These and other magnetic investigations very soon made Tyndall known among the leading scientists of the day.[8] He was elected a Fellow of the Royal Society in 1852. In his search for a suitable research appointment, he was able to ask the longtime editor of the leading German physics journal (Poggendorff) and other prominent men to write testimonials on his behalf. In 1853, he attained the prestigious appointment of Professor of Natural Philosophy (Physics) at the Royal Institution in London, due in no small part to the esteem his work had garnered from Michael Faraday, the leader of magnetic investigations at the Royal Institution.[9] About a decade later Tyndall was appointed the successor to the positions held by Michael Faraday at the Royal Institution on Faraday's retirement.

Tyndall explained the heat in the Earth's atmosphere in terms of the capacities of the various gases in the air to absorb radiant heat, in the form of infrared radiation. His measuring device, which used technology, is an early landmark in the history of absorption spectroscopy of gases.[20] He was the first to correctly measure the relative infrared absorptive powers of the gases nitrogen, oxygen, water vapour, carbon dioxide, ozone, methane, and other trace gases and vapours. He concluded that water vapour is the strongest absorber of radiant heat in the atmosphere and is the principal gas controlling air temperature. Absorption by the other gases is not negligible but relatively small. Prior to Tyndall it was widely surmised that the Earth's atmosphere warms the surface in what was later called a greenhouse effect, but he was the first to prove it. The proof was that water vapour strongly absorbed infrared radiation.[21][22] Three years earlier, in 1856, the American scientist Eunice Newton Foote had announced experiments demonstrating that water vapour and carbon dioxide absorb heat from solar radiation, but she did not differentiate the effects of infrared.[17][23] Relatedly, Tyndall in 1860 was first to demonstrate and quantify that visually transparent gases are infrared emitters.[24]

thermopile

He devised demonstrations that advanced the question of how radiant heat is absorbed and emitted at the molecular level. He appears to be the first person to have demonstrated experimentally that emission of heat in chemical reactions has its physical origination within the newly created molecules (1864). He produced instructive demonstrations involving the incandescent conversion of infrared into visible light at the molecular level, which he called calorescence (1865), in which he used materials that are transparent to infrared and opaque to visible light or vice versa.[26] He usually referred to infrared as "radiant heat", and sometimes as "ultra-red undulations", as the word "infrared" did not start coming into use until the 1880s. His main reports of the 1860s were republished as a 450-page collection in 1872 under the title Contributions to Molecular Physics in the Domain of Radiant Heat.

[25]

In the investigations on radiant heat in air it had been necessary to use air from which all traces of floating dust and other had been removed.[27] A very sensitive way to detect particulates is to bathe the air with intense light. The scattering of light by particulate impurities in air and other gases, and in liquids, is known today as the Tyndall Effect or Tyndall Scattering.[28] In studying this scattering during the late 1860s Tyndall was a beneficiary of recent improvements in electric-powered lights. He also had the use of good light concentrators. He developed the nephelometer and similar instruments that show properties of aerosols and colloids through concentrated light beams against a dark background and are based on exploiting the Tyndall Effect. (When combined with microscopes, the result is the ultramicroscope, which was developed later by others).

particulates

He was the first to observe and report the phenomenon of in aerosols. He spotted it surrounding hot objects while investigating the Tyndall Effect with focused lightbeams in a dark room. He devised a better way to demonstrate it, and then simply reported it (1870), without investigating the physics of it in depth.[29]

thermophoresis

In radiant-heat experiments that called for much laboratory expertise in the early 1860s, he showed for a variety of readily vaporisable liquids that, molecule for molecule, the vapour form and the liquid form have essentially the same power to absorb radiant heat. (In modern experiments using narrow-band spectra, some small differences are found that Tyndall's equipment was unable to get at; see e.g. absorption spectrum of H2O).

[30]

He consolidated and enhanced the results of , Forbes, Knoblauch and others demonstrating that the principal properties of visible light can be reproduced for radiant heat – namely reflection, refraction, diffraction, polarisation, depolarisation, double refraction, and rotation in a magnetic field.[31]

Desains

Using his expertise about radiant heat absorption by gases, he invented a system for measuring the amount of carbon dioxide in a sample of exhaled human breath (1862, 1864). The basics of Tyndall's system is in daily use in hospitals today for monitoring patients under .[32] (See capnometry.)

anaesthesia

When studying the absorption of radiant heat by , he came up with a demonstration that helped confirm or reaffirm that ozone is an oxygen cluster (1862).[33]

ozone

Private life[edit]

Tyndall did not marry until age 55. His bride, Louisa Hamilton, was the 30-year-old daughter of a member of parliament (Lord Claud Hamilton, M.P.). The following year, 1877, they built a summer chalet at Belalp in the Swiss Alps. Before getting married Tyndall had been living for many years in an upstairs apartment at the Royal Institution and continued living there after marriage until 1885 when a move was made to a house near Haslemere 45 miles southwest of London. The marriage was a happy one and without children. He retired from the Royal Institution at age 66 having complaints of ill health.


Tyndall became financially well-off from sales of his popular books and fees from his lectures (but there is no evidence that he owned commercial patents). For many years he got non-trivial payments for being a part-time scientific advisor to a couple of quasi-governmental agencies and partly donated the payments to charity. His successful lecture tour of the United States in 1872 netted him a substantial amount of dollars, all of which he promptly donated to a trustee for fostering science in America.[75] Late in life his money donations went most visibly to the Irish Unionist political cause.[76] When he died, his wealth was £22,122.[77] For comparison's sake, the income of a police constable in London was about £80 per year at the time.[78]

Tyndall, J. (1860), , (1861 edition) Ticknor and Fields, Boston

The glaciers of the Alps, Being a narrative of excursions and ascents, an account of the origin and phenomena of glaciers and an exposition of the physical principles to which they are related

Tyndall, J. (1862), , Longman, Green, Longman, and Roberts, London

Mountaineering in 1861. A vacation tour

Tyndall, J. (1865), : One Lecture (40 pages) [84]

On Radiation

Tyndall, J. (1868), , (1869 edition) D. Appleton, New York

Heat : A mode of motion

Tyndall, J. (1869), Natural Philosophy in Easy Lessons (180 pages) (a physics book intended for use in secondary schools)

Tyndall, J. (1870), , Longmans, Green, London

Faraday as a discoverer

Tyndall, J. (1870), Three Scientific Addresses by Prof. John Tyndall (75 pages)

[85]

Tyndall, J. (1870), Notes of a Course of Nine Lectures on Light (80 pages)

Tyndall, J. (1870), Notes of a Course of Seven Lectures on Electrical Phenomena and Theories (50 pages)

Tyndall, J. (1870), , (a compilation of 1850s research reports), Longmans, Green, London

Researches on diamagnetism and magne-crystallic action: including the question of diamagnetic polarity

Tyndall, J. (1871), , Longmans, Green, and Co., London

Hours of exercise in the Alps

Tyndall, J. (1871), , (1872 edition), Longmans, Green, London

Fragments of Science: A Series of Detached Essays, Lectures, and Reviews

Tyndall, J. (1872), , (a compilation of 1860s research reports), (1873 edition), D. Appleton and Company, New York

Contributions to Molecular Physics in the Domain of Radiant Heat

Tyndall, J. (1873), , H. S. King & Co., London

The forms of water in clouds & rivers, ice & glaciers

Tyndall, J. (1873), Six Lectures on Light (290 pages)

Tyndall, J. (1876), Lessons in Electricity at the Royal Institution (100 pages), (intended for secondary school students)

Tyndall, J. (1878), , (1969 edition), Greenwood Press, New York

Sound; delivered in eight lectures

Tyndall, J. (1882), , D. Appleton, New York

Essays on the floating matter of the air, in relation to putrefaction and infection

Tyndall, J. (1887), , D. Appleton and Company, New York

Light and electricity: notes of two courses of lectures before the Royal institution of Great Britain

Tyndall, J. (1892), (miscellaneous essays for a broad audience), D. Appleton, New York

New Fragments

Ice sheet dynamics

Spontaneous generation

Greenhouse gas

John Tyndall's system for measuring radiant heat absorption in gases

Tyndall's bar breaker

Eve, A.S.; Creasey, C.H. (1945). Life and Work of John Tyndall. London: Macmillan. 430 pages. This is the "official" biography.

wrote a 100-page biography of Professor Tyndall in 1887 (the year Tyndall retired from the Royal Institution). Downloadable.

William Tulloch Jeans

Louisa Charlotte Tyndall, his wife, wrote an 8-page biography of John Tyndall that was published in 1899 in Dictionary of National Biography (volume 57). It is (and a 1903 republication of the same biography is also readable online).

readable online

a longtime friend, wrote a 16-page biography of John Tyndall as an obituary in 1894 in a scientific journal. It is readable online.

Edward Frankland

D. Thompson (1957). . Journal of Vocational Education & Training. 9 (18): 38–48. doi:10.1080/03057875780000061. Gives an account of Tyndall's vocational development prior to 1853.

"John Tyndall (1820–1893): A study in vocational enterprise"

Brock, W.H. (1981). John Tyndall, Essays on a Natural Philosopher. Dublin: . 220 pages.

Royal Dublin Society

Arthur Whitmore Smith, a professor of physics, wrote a 10-page biography of John Tyndall in 1920 in a scientific monthly. .

Readable online

Anon (1894). "Obituary notices". Journal of the Chemical Society, Transactions. 65: 389–393. :10.1039/CT8946500382.

doi

a naturalist, wrote a 9-page obituary of John Tyndall in 1894 in a natural science journal. Readable online.

John Walter Gregory

An early, 8-page profile of John Tyndall appeared in 1864 in .

Portraits of Men of Eminence in Literature, Science and Art, Volume II, pages 25–32

A brief profile of Tyndall based on information supplied by Tyndall himself appeared in 1874 in . Nature. 10 (251): 299–302. 1874. Bibcode:1874Natur..10..299.. doi:10.1038/010299a0..

"Scientific worthies, IV.--John Tyndall"

John Tyndall as a Mountaineer, 56-page essay included in Schuster's book Postscript to Adventure, year 1950 (New Alpine Library: Eyre & Spottiswoode, London).

Claud Schuster

DeYoung, Ursula (2011). . Palgrave Macmillan. pp. 280. ISBN 978-0-230-11053-3..

A Vision of Modern Science: John Tyndall and the Role of the Scientist in Victorian Culture

Jackson, Roland (2018). The Ascent of John Tyndall. . p. 556. ISBN 9780198788959. The first major biography of Tyndall since 1945.

Oxford University Press

(2018). "Horn Section: John Tyndall's 1873 Foghorn Testing Sessions". In Strang, Veronica; Edensor, Tim; Puckering, Joanna (eds.). From the Lighthouse: Interdisciplinary Reflections on Light. Routledge. ISBN 9781472477354.

Allan, Jennifer Lucy

Street, Julie (4 January 2020). . ABC Radio National. Australian Broadcasting Corporation.

"Two pioneering scientists who changed how we think about the climate"

at the National Portrait Gallery, London

Portraits of John Tyndall

at Project Gutenberg

Works by John Tyndall

at Internet Archive

Works by or about John Tyndall

at LibriVox (public domain audiobooks)

Works by John Tyndall

.

A blog maintained by a historian who is involved in transcribing Tyndall's letters

The website

Tyndall Correspondence Project