Arthur Holmes: The most famous British geologist you have never heard of

25-03-2018 23:48 KALKI#1
Arthur Holmes (1890-1965) was an English geologist who made two important contributions to the development of geological ideas: the use of radioactive isotopes for dating minerals and the suggestion that convection currents in the mantle play an important role in continental drift. He held the chair of geology at Edinburgh University from 1943 until 1956.
Holmes presented his ideas on mantle convection in a lecture to the Geological Society of Glasgow on January 12 1928, and the paper was subsequently published in the society's Transactions for 1931. The 2010 BBC 2 series "Men of Rock", presented by Professor Iain Stewart, featured major contributions to world geology by Scottish geologists, including Holmes' 1928 explanation of how continents move around the surface of the planet.
Holmes was one of the first geologists to support Alfred Wegener's concept of continental drift, which became widely accepted following the development of the theory of plate tectonics in the 1960s. One of the key elements in plate tectonic theory is the phenomenon of seafloor spreading, and it is notable that Holmes' 1928 paper anticipated this concept by 35 years.
The full text of Holmes' paper appeared in volume 18 of the Transactions of the Geological Society of Glasgow, which was published in 1931. The paper can be viewed on the Lyell Collection website. (You can view an extract from the paper without logging in to the website, but will have to log in to view the full text. Members of the Geological Society of Glasgow can obtain a user name and password that will allow them to log in; details of how to do this can be found here.) A short summary of the lecture appears in the account of the meeting of January 12 1928 in the society's original minute book. The following is the full text of the summary in the minute book.
The hypocentric curve was interpreted by Wegener to indicate the existence of two dominant kinds of materials in the earth's crust, sial* corresponding to the lighter continental areas, and sima* to the denser oceanic floors. This view has been confirmed by Miller's study of surface seismic waves. The properties of the sima of the Pacific floor correspond to those of gabbro. The effect of compression on gabbro would be to transform the material into eclogite. Such change of density and the simultaneous action of isostacy would lead to subsidence of the compressed belt and therefore to the formation of oceanic seeps. Applying the principle of isostacy, it is easily shown that the average thickness of the sial should be about 30 km. This conclusion is confirmed by the recent work of Jeffreys on near earthquakes, which reveals the existence of an upper layer 10 km. thick (identified with granitic rocks); an intermediate layer 20 km. thick (supposed by Jeffreys to be tachylite, but identified by Holmes with diorite and quartz-diorite on petrological and thermal grounds), and a lower layer which may be eclogite or peridotite or both. The continents are thus thin slabs of sial, ranging in composition from granite to diorite, averaging 30 km. thick by about 3000 km. across, and embedded in material which on any interpretation is much more dense than sial.
Thus for physical reasons it becomes as impossible to "sink" a continent as to sink an iceberg. Considerable areas of the Atlantic and Indian Oceans were formerly occupied by continental masses, and since these ancient lands are no longer there we are driven to believe that their material has been moved away sideways. Evidence of lateral movement is also forthcoming from tear faults; overthrust structures of the Alpine type; the geological history of geosynclines; the echelon structures of the Asiatic Island festoons; and by the opening of the Urals geosyncline at the same geological moment as the compression of the Caledonian Mountains of Britain and Scandinavia. Moving the continental regions back in the directions indicated by the evidence leads to a Permo-Carboniferous reconstruction similar to that of Wegener's diagrams, a reconstruction that is independently called for on palaeo-climatic grounds. Wegener's deduction that the equator of the time ran through the coalfield belt of N America to China is supported by the distribution of Permo-Carboniferous laterites and bauxites. It is concluded that there is now evidence pointing to the former occurrence of continental drift on a scale of the same order as that advocated by Wegener.
The dominant forces available to move the continental slabs in the required directions (outwards from Africa towards the Pacific) tend to set up a westerly drift (tidal action) and a drift from the poles towards the equator (due to the departure of a polar section through the earth from a circle). Since our actual geography is totally different from the picture thus visualised, we have an indication that some other agency must have been at work to move the continents into the positions they now occupy. There seems no escape from the deduction that slow but overwhelmingly powerful currents must have been generated in the underworld at various times in the earth's history. These, as suggested by A.J. Bull, are probably convection currents set up in the lower layer as a result of differential heating by radioactivity. In place of the mobile basaltic magma of Joly, one imagines a highly viscous sima heated unequally to very great depths. A sheet-like upward current would develop beneath the region of greatest heat output. In turning over at or near the base of the sial it would exercise a powerful drag on the under-surface in two opposed directions, leading to the formation of a geosyncline. The return downward current would be looked for just beyond the continental edges. A continental mass would move forward by stoping of the heavy ocean floor just in front. When this ceased, mountain building would set in, and ultimately the direction of the currents would be reversed. Convection currents which themselves move their boundaries and the sources of much of the heat responsible for their existence can clearly lead to periodic alternations of heating and cooling in any one region.

* In his "Principles of Physical Geology", first published in 1944, Holmes used the term sima for a dense ultrabasic rock with silica, iron and magnesia, and sial for the less dense rock with silica and alumina. In this book he also outlined his ideas on mantle convection and illustrated them with a diagram. This diagram also appeared in subsequent editions of the book. The following is the version from the fourth edition, published in 1993. The diagram clearly shows how well he anticipated the concept of seafloor spreading from mid-ocean ridges (constructive plate margins), and even how he partly anticipated the concept of subduction zones (destructive plate margins).


https://www.geologyglasgow.org.uk/archive/arthur-holmes/
25-03-2018 23:51 KALKI#2
Although many people have never heard of Holmes, he was arguably the greatest British geologist of the twentieth century. Geologists today recognise Holmes for making two major contributions to our understanding of Earth Science; he was the first earth scientist to recognise that heat within the earth could create currents that could move the crust of the planet and consequently rearrange the continents, and he also widely applied the newly-developed method of “radiometric dating” to minerals in the first attempt to numerically estimate the age of the Earth.

It was as an undergraduate, at London’s Imperial College, that Arthur first became interested in the phenomenon of radioactivity, which was a new and exciting field in science at the time. Originally studying for a degree in physics, Arthur took a course in geology in his second year which settled his future as a geologist, much to the shock of his tutors! It was during his final year as a student, in 1910, that he pioneered the use of radiometric dating, a technique that can be used to date rocks and minerals. It was this method which allowed scientists to discover the age of specimens which are many millions of years old, and eventually to attempt to discover the age of the earth itself. Initially Holmes was reluctant to comment on the age of the earth, but by 1913 he had published results indicating that some of the oldest rocks identified were 1.6 billion years old. Years of method improvement and retesting followed and in 1946 several different groups of scientists came to agreement – the Earth is in the region of 4.5 billion years old!

Holmes was also able to use his understanding of radioactivity and apply it to other longstanding geological problems, including suggesting that currents caused by radioactive heat were the driving force behind the Theory of Plate Tectonics. The Theory of Continental Drift, which predated Plate Tectonics, was unfashionable among scientists because it lacked a driving force to create movement of the Earth’s crust. Holmes suggested, in 1930, that the circulation of heat within the Earth could push large areas of the crust together, forming mountains such as the Himalayas, or away from each other, producing oceans such as the Atlantic. It was not until 1960 that other scientists were able to find physical evidence for the movement of the continents when sea-floor mapping revealed submarine plateaus and trenches, where tectonic plates were being pulled apart or forced underneath each other.

Thankfully Arthur Holmes was well recognised as an eminent scientist in his life time and he was given the prestigious position of Regius Chair of Geology at the University of Edinburgh. In addition to securing a professorship, Holmes received many awards and medals from international geological surveys and societies including; the Murchison Medal (1940) and Wollaston Medal (1956) awarded by the Geological Society of London; the Penrose Medal (1956) awarded by the Geological Society of America; and the highly prestigious Vetlesen Prize (1964).

The Vetlesen Prize was established in 1959 by the G. Unger Vetlesen Foundation, and was designed to be the Nobel Prize of the Earth Sciences, awarded for “scientific achievement resulting in a clearer understanding of the Earth, its history, or its relations to the universe”. Characteristically both modest and forthright in his acceptance letter, Holmes expressed his surprise at being selected “for what must surely be the highest distinction in the world for geologists. The surprise was all the greater because I have to confess that I had not even known there was such an award”.

Holmes shared the award of $25,000 with his friend the Finnish geologist, Professor Pentti Eskola. Unfortunately Arthur was suffering poor health and was unable to travel to America to receive the prize. The Royal Society London held a luncheon party in his honour where another famous geologist Maurice Ewing presented him with the medal. Ewing, who was the first recipient of the Vetlesen Prize in 1960, praised Homes as a “pioneer in the field of isotope geology, in the use of radioactive elements for determination of the age of rocks and of the Earth… His papers, books and teaching have profoundly influenced the thinking of every modern student of the Earth Sciences”.


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