Sir Ernest Titterton | |
|---|---|
 | |
| Born | Ernest William Titterton (1916-03-04)4 March 1916 Kettlebrook,Warwickshire, England |
| Died | 8 February 1990(1990-02-08) (aged 73) Canberra,Australian Capital Territory, Australia |
| Nationality | British |
| Alma mater | University of Birmingham |
| Scientific career | |
| Fields | Nuclear physics |
| Institutions | University of Birmingham Manhattan Project Atomic Energy Research Establishment Australian National University |
| Doctoral advisor | Mark Oliphant |
Sir Ernest William TittertonCMG FRS FAA (4 March 1916 – 8 February 1990) was a Britishnuclear physicist.
A graduate of theUniversity of Birmingham, Titterton worked in a research position underMark Oliphant, who recruited him to work on radar for theBritish Admiralty during the first part of theSecond World War. In 1943, he joined theManhattan Project'sLos Alamos Laboratory, where he helped develop the firstatomic bombs. He eventually became one of the laboratory's group leaders. He participated in theOperation Crossroads nuclear tests at theBikini Atoll in 1946, where he performed thecountdown for both tests. With the passage of theAtomic Energy Act of 1946, known as the McMahon Act, all British government employees had to leave. He was the last member of theBritish Mission to do so, in April 1947.
Returning to England, Titterton joined theAtomic Energy Research Establishment inHarwell, Oxfordshire, heading a group responsible for research withnuclear emulsions andcloud chambers. He investigatedternary fission, a comparatively rare type of nuclear fission in which the nucleus breaks into three pieces instead of two, and thephotodisintegration of light nuclei bygamma rays. He was also a consultant to theAtomic Weapons Research Establishment (AWRE) atAldermaston that designed and developed Britain's first nuclear weapons.
In August 1950, Titterton accepted an offer from Oliphant to become the foundation Chair of Nuclear Physics at theAustralian National University (ANU) inCanberra. Over the next thirty years, Titterton held high positions on various science, defence and nuclear-related committees, institutes and councils in Australia. He helped build up the physics department at ANU through the acquisition of accelerators. As a member of the Atomic Weapons Tests Safety Committee (AWTSC), Titterton witnessed many of theBritish nuclear tests at Maralinga. His reputation was tarnished by theMcClelland Royal Commission in 1984 and 1985, which accused him of loyalty to Britain instead of Australia. He was a strong public advocate ofnuclear power in Australia, arguing that "nuclear power is the cheapest, cleanest and safest method of power production yet devised by man."[1]
Ernest William Titterton, was born in Kettlebrook, Warwickshire, England, on 4 March 1916,[2] the son of William Alfred and his wife Elizabethnée Smith. He had a younger brother, Maurice.[3] He had a talent for music, singing with the choir and playing the organ at theChurch of St Editha, Tamworth.[2]
Titterton's primary education began next door to the family home in Kettlebrook at a single-room school for infants, starting at the age of four. After two years, he moved to a boys-only school in Glascote, Tamworth. This council school in a mining town had basic science facilities (uncommon at that time), and it was there that his interest in science was first kindled. At ten, Titterton won a scholarship to attendQueen Elizabeth's Grammar School in Tamworth, where he performed consistently well. He also excelled at sports, playingcricket andhockey for the school's first teams, and learned to play the piano and theorgan. He received hisSchool Certificate with seven credits when he was fourteen, and enteredsixth form, which was at that time reserved for gifted students expected to continue to study at a tertiary level. He studied mathematics, chemistry, and physics. His physics teacher, William Summerhayes, cultivated Titterton's interest in science. Summerhayes believed that his pupils should learn how to conduct research, and had Titterton and another boy measure thediurnal variation ofEarth's magnetic field. Their results were published in the school magazine.[2]
Summerhayes hoped that Titterton would be able to enter theUniversity of Cambridge, but the paper mill that his father worked for closed due to theGreat Depression, leaving his father unemployed for a time, and unable to afford it. Instead, in 1934, Titterton was accepted intoUniversity of Birmingham on a teacher's scholarship, which paid his tuition fees, board and residence at Chancellor's Hall, a hostel for male undergraduates. Due to his achievements at secondary school, Ernest was allowed to begin his tertiary studies with second-year subjects, and even then he was said to have found them easy. He obtained hisBachelor of Science in 1936 with distinctions in both pure and applied mathematics and, of course, physics. An honours year quickly followed, and Titterton topped the year in physics. He continued his interest in music, playing the piano at social events. He also played hockey with the universityFirst XI from 1934 to 1936.[2]
In 1937, Ernest was presented with a £92 university scholarship, and worked in a research position underMark Oliphant, the chairman of the physics department. The scholarship was insufficient to cover his living expenses, so he lived at home and commuted by bus and train. The project he shared with another student was to determine if the weakalpha particle activity ofsamarium was due to theelectron orgamma ray components ofcosmic rays. The work had to be carried out in a coal mine, 5,000 feet (1,500 m) below the surface. Upon completion of these experiments, Titterton was awarded aMaster of Science degree in 1938. As a requirement of his scholarship, Ernest was required to become a teacher for a year. This met with a lukewarm reception, but he graduated with hisDiploma in Education, and was even awarded theElizabeth Cadbury Prize for achieving top marks in the class. As part of his training, he taught atKing Edward's School, Birmingham. To support himself, he also taught three nights a week atBirmingham Central Technical College. With his diploma in hand, he became a teacher atBridgnorth Endowed School, acoeducationalsecondary school and sixth form located in the market town ofBridgnorth in the rural county ofShropshire.[2][3]
After a call from Oliphant, who wanted to develop a 10 cm wavelength radiation generator, Titterton worked as a research officer with theBritish Admiralty for the early part of theSecond World War, working onradar systems at the University of Birmingham. He was awarded aPhD in physics in 1941. Though the work was classed top secret, he was allowed to submit it. His examiners were the nuclear physicistsJohn Cockcroft andPhilip Dee, both of whom were engaged in work on radar at that time. He also carried out some research withOtto Frisch. The two notedspontaneous fission inuranium, but were unable to publish due to wartime security restrictions. Credit for the discovery therefore went toGeorgy Flyorov andKonstantin Petrzhak, who discovered it independently in 1940.[4][5] While at the University of Birmingham, Titterton met Peggy Eileen Johnson, a laboratory assistant, who helped him build a prototypespark gap generator. They were married on 19 September 1942 atSt John the Baptist inHagley, Worcestershire.[2][3]
In 1943, aBritish mission was sent to the United States to assist the AmericanManhattan Project in developingatomic bombs. First to arrive at theLos Alamos Laboratory were Frisch and Titterton, on 13 December 1943.[6] The two shared an office at first, but were soon working on different projects. Titterton worked in collaboration with the American physicistBoyce McDaniel inRobert R. Wilson's P-1 (Cyclotron) Group.[2][7][8] Together, they searched for delays betweennuclear fission and the emission ofprompt neutrons. A sizeable delay could make anuclear chain reaction impractical.[2] They calculated that most were emitted in less than 1nanosecond; subsequent experiments demonstrated that fission took less than a nanosecond too.[9]
Titterton then became involved with timing circuits used to track the progress of animplosion. Along with Frisch,Darol Froman,Rudolf Peierls,Philip Moon andAlvin C. Graves, he developed the "pin method". Pins were placed near the implosion and connected to circuits which connected to anoscilloscope. This gave accurate timing of the implosion, from which its symmetry could be evaluated. It turned out to be the most useful of several methods of timing the implosion.[10] When the director,Robert Oppenheimer, reorganised the Los Alamos Laboratory to focus on implosion in August 1944, Titterton joinedKenneth Greisen's X-1A Section inNorris Bradbury's X-1 (Implosion) Group.[11] The group studied the timing of theprimacord detonations using X-rays. Titterton designed a circuit for measuring the spread of detonations using a variation of the pin method. He developed a device called "the informer" that measured the time spread among detonations (and whether all thedetonators had indeed fired).[12] In July 1945 he was a senior member of the timing group at theTrinity nuclear test that fired the first nuclear weapon atAlamogordo, New Mexico. His electronic timers tracked the progress of the detonation.[13] In February 1946, he became the head of the P-1 (Electronics) Group.[14] He participated in theOperation Crossroads nuclear tests atBikini Atoll, and performed thecountdown for both tests.[2]
While most Americans saw Los Alamos as a remote and isolated place, it looked quite different to those accustomed to the shortages and danger of wartime Britain. Peggy, who worked at Los Alamos as a laboratory technician,[15] pleasantly surprised and impressedBrigadier GeneralLeslie Groves by congratulating him on the food and accommodation.[16] Titterton played the grand piano at dances and recitals at theFuller Lodge, often accompanied byRichard Feynman on the drums.[2] With the passage of theAtomic Energy Act of 1946, known as the McMahon Act, all British government employees had to leave. All had gone by the end of 1946, except for Titterton, who was granted a special dispensation, and remained until 12 April 1947. The British Mission to the Manhattan Project ended when he departed.[17][18]
Returning to England, Titterton joined theAtomic Energy Research Establishment inHarwell, Oxfordshire. He headed a group that was part ofHerbert Skinner's General Physics Division, responsible for research withnuclear emulsions andcloud chambers. Using photographic techniques, he investigatedternary fission, a comparatively rare type of nuclear fission in which the nucleus breaks into three pieces instead of two. This occurs in only about one in 500 fission events, so was not easy to observe. He examined the cloud chamber tracks of over one million events, finding about a thousand ternary alpha particle tracks with energy of between 15MeV and 30 MeV, emitted at 90° to the two heavy fragments. He also researched thephotodisintegration of light nuclei by gamma rays. Unfortunately, thesynchrotron at Harwell was not powerful enough to createpions as he hoped, so he investigated "stars" (multi-particle disintegrations) in nuclear emulsions. In all, he published 28 papers between 1949 and 1952. He was also a consultant to theAtomic Weapons Research Establishment (AWRE) atAldermaston that designed and developed Britain's first nuclear weapons.[2]
In August 1950, Titterton accepted an offer from Oliphant, now the Director of theResearch School of Physical Sciences and Engineering at theAustralian National University (ANU) inCanberra, of its foundation chair of Nuclear Physics.[3] He arrived in Australia on the linerSS Orcades in May 1951.[2] Nonetheless, his international interests continued and he was elected afellow of the Royal Society and theAmerican Physical Society, both in 1952. In 1954 a similar honour was bestowed upon him as one of the earliest fellows of theAustralian Academy of Science. Over the next thirty years, Titterton held positions on various science, defence and nuclear-related committees, institutes and councils, including the Australian Atomic Weapons Tests Safety Committee from 1954 to 1956, theAustralian Atomic Energy Commission's Scientific Advisory Committee from 1955 to 1964, the Council of the Institute of Defence Science,Department of Supply from 1957 to 1972, Australian Atomic Weapons Tests Safety Committee from 1957 to 1973, the National Radiation Advisory Committee from 1957 to 1973, the Federal Government's Defence Research and Development Policy Committee from 1958 to 1973, the Council of the Australian Institute of Nuclear Science and Engineering from 1960 to 1984, the Council of the Australian Academy of Science from 1964 to 1966, and the Advisory Committee of theStrategic and Defence Studies Centre from 1967 to 1981.[19]
During this time, Titterton continued to pursue his academic interests at the ANU. He had a 1.2 MeVCockcroft-Walton accelerator installed so he could continue his work with nuclear emulsions. On study leave in 1954 he visitedWilliam Penney, a colleague from the Los Alamos Laboratory days who had become the Director of the AWRE at Aldermaston. On the voyages to and from England on theOrcades andRMS Otranto, he wrote a book,Facing the Atomic Future (1956), in which he examined social, ethical and political issues surrounding nuclear power and nuclear weapons.[2] He was a strong public advocate ofnuclear power in Australia,[20] writing letters to and articles in theCanberra Times.[21] In 1979, he wrote that "nuclear power is the cheapest, cleanest and safest method of power production yet devised by man",[1] an argument he repeated in a second book, with Frank Robotham, titledUranium, Energy Source of the Future?,[22] in which he put the case for nuclear power.[3]
Titterton was the Dean of the Research School of Physical Sciences from 1966 to 1968, and Director of the Research School of Physical Sciences from 1969 to 1973. He was also a member of the council ofMacquarie University from 1978 to 1984.[19] His goal was to build up the physics department at ANU into a world-class institution. When he heard that the 33 MeV electron synchrotron at theTelecommunications Research Establishment inMalvern, Worcestershire, was to be closed down, he wrote to Cockcroft, now the director of the AERE, and asked if he could have it for the ANU. Cockcroft agreed, on condition that the ANU pay for it to be dismantled and shipped all the way to Australia. Titterton arranged for this to be done. The electron synchrotron was installed in the basement of the Oliphant Building,[2] where it became known as "Ernie's erection".[23]
A third accelerator, a 600 keV Cockcroft-Walton accelerator, was acquired in 1954. With Tony Brinkley, a researcher that he recruited in England, he studied photonuclear reactions with the Cockcroft-Walton accelerators, andbremsstrahlung, the radiation produced by the deceleration of a charged particle, with the electron synchrotron. They were the first to observe ternary fission inCalifornium-252. A 5 MV terminalelectrostatic nuclear (EN) tandem accelerator commenced operation in 1961. The electron synchrotron ceased operation that year, and was given to theUniversity of Western Australia. He obtained $2.2 million in 1969 for new accelerators, with which he purchased a 26 MeV negative-ion cyclotron to inject into the EN tandem, which commenced operation in 1972, and a 14UD tandem accelerator that commenced operation in 1974.[2] He became involved in some bruising bureaucratic battles. When the Australian and British governments jointly agreed to build theAnglo-Australian telescope in 1969, a dispute arose over whether it should be controlled by the ANU or its own management. Titterton supported the latter approach, which ultimately prevailed. But he lost a battle to prevent the department of geophysics and geochemistry from becoming a new Research School of Earth Sciences.[3]
In 1973, Titterton stepped down as Director of the Research School of Physical Sciences, and became an ordinary professor. Once again he spearheaded a proposal to upgrade the department's equipment, this time by using the tandem as an injector for a superconducting linear accelerator. Unable to secure funding in Australia, he managed to persuade the BritishScience Research Council to donate the required equipment to the ANU from facilities in England that were being closed down. It was installed and commissioned after his death.[3][24] He was appointed aCompanion of the Order of St Michael and St George on 1 January 1957,[25] and was created aknight bachelor on 1 January 1970.[26]
On 16 September 1950, thePrime Minister of the United Kingdom,Clement Attlee sounded out his Australian counterpart,Robert Menzies about the prospect of conductingBritish nuclear weapons tests in Australia. Menzies was agreeable. In April 1952, the British government asked if Titterton could assist with the forthcoming test in theMontebello Islands of Western Australia, now codenamedOperation Hurricane, as he was one of the few people outside the United States who had experience in the planning and conduct of nuclear tests. On Oliphant's advice, the vice chancellor, SirDouglas Copland, agreed to release Titterton. Two further nuclear tests were carried out in 1953 atEmu Field, South Australia, as part ofOperation Totem. Titterton and other scientists from the ANU conducted neutron flux measurements with photographic emulsions and neuron-threshold detectors. In July 1955, in response to growing concerns about health hazards related to British nuclear tests, the government created the Atomic Weapons Tests Safety Committee (AWTSC), with the power to veto tests it felt were a danger to people, flora or fauna. Titterton was one of its members, along withLeslie H. Martin,W. A. S. Butement, C. E. Eddy,Philip Baxter and L. J. Dwyer. In this capacity, Titterton witnessedBritish nuclear tests at Maralinga, starting withOperation Mosaic in May and June 1956.[2]
Titterton was grilled by theMcClelland Royal Commission, which held hearings between August 1984 and September 1985 to investigate the conduct of British nuclear testing in Australia.[2] He clashed repeatedly with its chairman,Jim McClelland,[3] who accused Titterton of being "a British plant".[23] His final report was scathing:
(47) The AWTSC failed to carry out many of its tasks in a proper manner. At times it was deceitful and allowed unsafe firing to occur. It deviated from its charter by assuming responsibilities which properly belonged to the Australian Government.
(48) Titterton played a political as well as a safety role in the testing program, especially in the minor trials. He was prepared to conceal information from the Australian Government and his fellow Committee members if he believed to do so would suit the interests of the United Kingdom Government and the testing program.
(49) The fact that the AWTSC did not negotiate with the UK openly and independently in relation to the minor trials was a result of the special relationship which enabled Titterton to deal with the AWRE in a personal and informal manner. He was from first to last, 'their man' and the concerns which were ultimately voiced in relation to the Vixen B proposals and which forced the introduction of more formal procedures for approving minor trials were a direct result of the perceived inadequacies in the manner in which he had carried out his tasks.[27]
Jack Waterford from theCanberra Times noted in Titterton's obituary that the "general charge of complaisance is better directed at Menzies than Titterton."[23] T. R. Ophel, the historian of the ANU's Department of Physics, opined that "Rarely has it been more evident that the past is the proper territory of thoughtful histories. Hindsight, conditioned by political and scientific changes evolving over a 30-year period, cannot and should not be used to judge the past."[28]
Titterton officially retired in 1981, but retained a position as a visiting fellow in the Department of Nuclear Physics at the ANU. He suffered astroke in 1982, but recovered. He divorced in 1986, and was injured seriously in a car accident in September 1987, which left him aquadriplegic.[2][23] He considered himself as "on the scrap heap of life", and claimed that "if euthanasia were legal I should opt for it tomorrow".[23] Nonetheless, he died from apulmonary embolism on 8 February 1990. His remains were cremated, and his ashes scattered along theWhite Cliffs of Dover. He was survived by his ex-wife and three children.[28] His papers are held by theAustralian Science and Technology Heritage Centre at theUniversity of Melbourne.[29]
