Thomas Gold

Thomas Gold (also known as Tommy Gold),[3] (May 22, 1920 – June 22, 2004[4]) was an Austrian-born astrophysicist, a professor of astronomy at Cornell University, a member of the U.S. National Academy of Sciences, and a Fellow of the Royal Society (London).[4] Gold was one of three young Cambridge scientists who in 1948 proposed the now mostly abandoned "steady state" hypothesis of the universe. Gold's work crossed academic and scientific boundaries, into biophysics, astronomy, aerospace engineering, and geophysics.

Thomas Gold

Born(1920-05-22)May 22, 1920
DiedJune 22, 2004(2004-06-22) (aged 84)
NationalityAustrian
British
American
Alma materTrinity College, Cambridge
Known forSteady-state theory, Abiogenic petroleum origin
AwardsFellow of the Royal Society (1964)
John Frederick Lewis Award (1972)[1]
Humboldt Prize (1979)
Gold Medal of the Royal Astronomical Society (1985)
Scientific career
FieldsAstrophysics, astronomy, biophysics,
cosmology, geophysics, aerospace engineering
InstitutionsUniversity of Cambridge, Royal Observatory, Greenwich,
Harvard University, Cornell University
Doctoral advisorR. J. Pumphrey
Doctoral studentsStanton J. Peale[2]
Peter Goldreich[2]

Early life

Gold was born on May 22, 1920 in Vienna, Austria to Max Gold, a wealthy Jewish industrialist (pre-war) who ran one of Austria's largest mining and metal fabrication companies, and German former actress Josefine Martin. Following the economic downfall of the European mining industry in the late 1920s, Max Gold moved his family to Berlin, where he had taken a job as director of a metal trading company.[5] Following the start of Nazi leader Adolf Hitler's anti-Jewish campaigns in 1933, Gold and his family left Germany because of his father's heritage. The family travelled through Europe for the next few years. Gold attended boarding school at the Lyceum Alpinum Zuoz in Zuoz, Switzerland, where he quickly proved to be a clever, competitive and physically and mentally aggressive individual.[6] Gold finished his schooling at Zuoz in 1938, and fled with his family to England after the German invasion of Austria in early 1938. Gold entered Trinity College, Cambridge in 1939 and began studying mechanical sciences.[7] In May 1940, just as Hitler was commencing his advance in Belgium and France, Gold was sent into internment as an enemy alien by the British government. It was on the first night of internment, at an army barracks in Bury St Edmunds, that he met his future collaborator and close friend, Hermann Bondi.[8][9]

Gold spent most of his nearly 15 months of internment in a camp in Canada, after which he returned to England and reentered Cambridge University, where he abandoned his study of mechanical sciences for physics.[8] After graduating with a pass (Ordinary) degree in June 1942, Gold worked briefly as an agricultural labourer and lumberjack in northern England before joining Bondi and Fred Hoyle on naval research into radar ground clutter near Dunsfold, Surrey. The three men would spend their off-duty hours in "intense and wide-ranging scientific discussion" on topics such as cosmology, mathematics and astrophysics.[10] Within months, Gold was placed in charge of constructing new radar systems. Gold determined how landing craft could use radar to navigate to the appropriate landing spot on D-Day and also discovered that the German navy had fitted snorkels to its U-boats, making them operable underwater while still taking in air from above the surface.[5]

Work at Cambridge

Immediately after the war, Hoyle and Bondi returned to Cambridge, while Gold stayed with naval research until 1947. He then began working at Cambridge's Cavendish Laboratory to help construct the world's largest magnetron, a device invented by two British scientists in 1940 that generated intense microwaves for radar. Soon after, Gold joined R. J. Pumphrey, a zoologist at the Cambridge Zoology Laboratory who had served as the deputy head of radar naval research during the war, to study the effect of resonance on the human ear. He found that the degree of resonance observed in the cochlea was not in accordance with the level of damping that would be expected from the viscosity of the watery liquid that fills the inner ear. In 1948, Gold hypothesized that the ear operates by "regeneration", in that electromechanical action occurs when electrical energy is used to counteract the effects of damping.[11] Although Gold won a prize fellowship from Trinity College for his thesis on the regeneration and obtained a junior lectureship at the Cavendish Laboratory, his theory was widely ignored by ear specialists and physiologists, such as future Nobel Prize winner Georg von Békésy, who did not believe the cochlea operated under a feedback system.[12] In the 1970s, researchers discovered that Gold's hypothesis had been correct – the ear contained microscopic hair cells that operated on a feedback mechanism to generate resonance.[9][11]

Steady-state theory

Gold began discussing problems in physics with Hoyle and Bondi again, centering on the issues over redshift and Hubble's law. This led the three to all start questioning the Big Bang theory originally proposed by Georges Lemaître in 1931 and later advanced by George Gamow, which suggested that the universe expanded from an extremely dense and hot state and continues to expand today. As recounted in a 1978 interview with physicist and historian Spencer R. Weart, Gold believed that there was reason to think that the creation of matter was "done all the time and then none of the problems about fleeting moments arise. It can be just in a steady state with the expansion taking things apart as fast as new matter comes into being and condenses into new galaxies".[13]

Two papers were published in 1948 discussing the "steady-state theory" as an alternative to the Big Bang: one by Gold and Bondi, the other by Hoyle. In their seminal paper, Gold and Bondi asserted that although the universe is expanding, it nevertheless does not change its look over time; it has no beginning and no end.[13][14] They proposed the perfect cosmological principle as the underpinning of their theory, which held that the universe is homogeneous and isotropic in space and time. On the large scale, they argued that there "is nothing outstanding about any place in the universe, and that those differences which do exist are only of local significance; that seen on a large scale the universe is homogeneous."[15] However, since the universe was not characterized by a lack of evolution, distinguishing features or recognizable direction of time, they postulated that there had to be large-scale motions in the universe. They highlighted two possible types of motion: large-scale expansion and its reverse, large-scale contraction.[16] They estimated that within the expanding universe, hydrogen atoms were being created out of a vacuum at a rate of one atom per cubic meter per 109 years.[17] This creation of matter would keep the density of the universe constant as it expanded. Gold and Bondi also stated that the issues with time scale that had plagued other cosmological theories – such as the discrepancy between the age of the universe as calculated by Hubble and dating of radioactive decay in terrestrial rocks – were absent for the steady-state theory.[18]

It was not until the 1960s that major problems with the steady-state theory began to emerge, when observations apparently supported the idea that the universe was in fact changing: quasars and radio galaxies were found only at large distances (therefore existing only in the distant past), not in closer galaxies. Whereas the Big Bang theory predicted as much, steady state predicted that such objects would be found everywhere, including close to our own galaxy, since evolution would be more evenly distributed, not observed only at great distances.[14] In addition, proponents of the theory predicted that in addition to hydrogen atoms, antimatter would also be produced, as with cosmic gamma ray background from the annihilation of protons and antiprotons and X-ray emitting gas from the creation of neutrons.[14]

For most cosmologists, the refutation of the steady-state theory came with the discovery of the cosmic microwave background radiation in 1965, which was predicted by the Big Bang theory.[19] Stephen Hawking said that the fact that microwave radiation had been found, and that it was thought to be left over from the Big Bang, was "the final nail in the coffin of the steady-state theory."[20] Bondi conceded that the theory had been disproved, but Hoyle and Gold remained unconvinced for a number of years. Gold even supported Hoyle's modified steady-state theory, however, by 1998, he started to express some doubts about the theory, but maintained that despite its faults, the theory helped improve understanding regarding the origin of the universe.[9]

Accidental panspermia

Gold suggested a "garbage theory" for the origin of life which was an accidental panspermia; the theory says that life on Earth might have spread from a pile of waste products accidentally dumped on Earth long ago by extraterrestrials.[21]

Astrophysics research

The Arecibo Observatory, established by Cornell University and the National Science Foundation during Gold's tenure as director of the Center for Radiophysics and Space Research

In 1951, at a meeting of the Royal Astronomical Society, Gold proposed that the source of recent radio signals detected from space was outside the Milky Way galaxy, much to the derision of radio astronomer Martin Ryle and several mathematical cosmologists. However, a year later, a distant source was identified and Gold announced at an International Astronomical Union meeting in Rome that his theory had been proven. Ryle would later take Gold's argument as proof of extragalactic evolution, claiming that it invalidated the steady-state theory.[22]

Gold left Cambridge in 1952 to become the chief assistant to Astronomer Royal Harold Spencer Jones at the Royal Greenwich Observatory in Herstmonceux, Sussex, England. While there, Gold attracted some controversy by suggesting that the interaction between charged particles from the Sun with the Earth's magnetic field in creating magnetic storms in the upper atmosphere was an example of a collisionless shock wave.[23] The theory was widely disputed, until American scientists in 1957 discovered that Gold's theory held up to mathematical scrutiny by conducting a simulation using a shock tube.[9]

Gold resigned from the Royal Observatory following Spencer-Jones's retirement and moved to the United States in 1956, where he served as Professor of Astronomy (1957–1958) and Robert Wheeler Wilson Professor of Applied Astronomy (1958–1959) at Harvard University.[19] In early 1959, he accepted an appointment at Cornell University, which had offered him the opportunity to set up an interdisciplinary unit for radiophysics and space research, and take charge of the Department of Astronomy.[24] At the time, there was only one other faculty member in the department. Gold would serve as director of the Center for Radiophysics and Space Research until 1981, establishing Cornell as a leading hub of scientific research. During his tenure, Gold hired famed astronomers Carl Sagan and Frank Drake, helped establish the world's largest radio telescope at the Arecibo Observatory in Puerto Rico and the Cornell-Sydney University Astronomy Center with Harry Messel. In addition, Gold served as Assistant Vice President for Research from 1969–1971 and the John L. Wetherill Professor of Astronomy from 1971 until his retirement in 1986.[25][26][27]

The discovery of a pulsar with 0.033 second period in the Crab Nebula led to the acceptance of Gold's theory on pulsars.

In 1959, Gold expanded on his previous prediction of a collisionless shock wave, arguing that solar flares would eject material into magnetic clouds to produce a shock front that would result in geomagnetic storms. He also coined the term "magnetosphere" in his paper "Motions in the Magnetosphere of the Earth" to describe "the region above the ionosphere in which the magnetic field of the Earth has a dominant control over the motions of gas and fast charged particles ... [which was] known to extend out to a distance of the order of 10 Earth radii".[28] In 1960, Gold collaborated again with Fred Hoyle to show that magnetic energy fueled solar flares and that flares were triggered when opposite magnetic loops interact and release their stored energy.[29][30]

In 1968, a Cambridge radio astronomy postgraduate student Jocelyn Bell Burnell and her doctoral adviser Antony Hewish discovered a pulsing radio source with a period of 1.33 seconds. The source – which was termed "pulsar" – emitted beams of electromagnetic radiation at a very short and consistent interval. Gold proposed that these objects were rapidly rotating neutron stars. Gold argued that due to their strong magnetic fields and high rotational speed, pulsars would emit radiation similar to a rotating beacon. Gold's conclusion was initially not well received by the scientific community; in fact, he was refused permission to present his theory at the first international conference on pulsars. However, Gold's theory became widely accepted following the discovery of a pulsar in the Crab Nebula using the Arecibo radio telescope, opening the door for future advancements in solid-state physics and astronomy.[31] Anthony Tucker of The Guardian remarked that Gold's discovery paved the way for Stephen Hawking's groundbreaking research into black holes.[10]

Relationship with NASA

Bootprint of Lunar Module Pilot Buzz Aldrin on the surface of the Moon. Aldrin photographed this bootprint on July 20, 1969, as part of investigations into the soil mechanics of the lunar surface.

From the 1950s, Gold served as a consultant to NASA and held positions on several national space committees, including the President's Science Advisory Committee, as the United States tried to develop its space program. At the time, scientists were engaged in a heated debate over the physical properties of the moon's surface. In 1955, he predicted that the Moon was covered by a layer of fine rock powder stemming from "the ceaseless bombardment of its surface by Solar System debris".[24] This led to the dust being jokingly referred to as "Gold dust"[32] or "Gold's dust".[33] Gold initially suggested that astronauts would sink into the dust, but upon later analysis of impact craters and electrostatic fields, he determined that the astronauts' boots would sink only three centimeters into the Moon's surface. In any case, NASA sent unmanned Surveyors to analyze the conditions on the surface of the Moon. Gold was ridiculed by fellow scientists, not only for his hypothesis, but for the approach he took in communicating NASA's concerns to the American public; in particular, some experts were infuriated with his usage of the term "moon dust" in reference to lunar regolith.[34] When the Apollo 11 crew landed on the Moon in 1969 and brought back the first samples of lunar rocks, researchers found that lunar soil was in fact powdery. Gold said the findings were consistent with his hypothesis, noting that "in one area as they walked along, they sank in between five and eight inches". However, Gold received little credit for his correct prediction, and was even criticized for his original prediction of a deep layer of lunar dust.[24] Gold had also contributed to the Apollo program by designing the Apollo Lunar Surface Closeup Camera (ALSCC) (a kind of stereo camera) used on the Apollo 11, 12, and 14 missions.[24][35]

In the 1970s and 1980s, Gold was a vocal critic of NASA's Space Shuttle program, deriding claims that the agency could fly 50 missions a year or that it could have low budget costs. NASA officials warned Gold that if he testified his concerns before Congress, his research proposals would lose their support from NASA. Gold ignored the warning and testified before a Congressional committee headed by Senator Walter Mondale. In a letter to NASA administrator James C. Fletcher, George Low wrote that "Gold should realize that being funded by the Government and NASA is a privilege, and that it would make little sense for us to fund him as long as his views are what they are now".[36] Gold recalled the aftermath of his testimony in a 1983 interview with astronomy historian David H. DeVorkin:

I had a very hard time with NASA, year after year. I got some more money, but eventually it fizzled out, after three years or so after this event. My applications, which previously each year had always gone through very smoothly, were turned down. I would then have to go to Washington, discuss it with them. and I then would get a certain fraction of it resurrected. For several years running this happened, and then eventually it fizzled permanently, and I've not tried to get any money out of NASA since.
...
I was certainly regarded as persona non grata with NASA after that. I had a very hard time. Shortly after that Noel Hinners became the Space Science administrator, and he used to joke about it and say, "Oh. Tommy's got to come to his annual pilgrimage to Washington," and regarded it as very funny, but then he'd always give me some money. But always clearly as a persona non grata.[37]

Origins of petroleum

Tube worms feeding at base of a black smoker hydrothermal vent

Gold first became interested in the origins of petroleum in the 1950s, postulating a theory on the abiogenic formation of fossil fuels. Gold engaged in thorough discussion on the matter with Fred Hoyle, who even included a chapter on "Gold's Pore Theory" in his 1955 book Frontiers in Astronomy.[26][38] In the late 1970s, just as the United States faced another major energy crisis, Gold resurrected his work on petroleum. In 1977, a research submarine near the Galapagos Islands discovered a number of thriving ecosystems down on the ocean floor, living alongside hydrothermal vents. Later expeditions found that these vents were host to a number of organisms, including giant tube worms and albino crabs, that survived off heat-loving chemosynthetic microbes. The discovery of life in this adverse environment led Gold to reconsider the established interpretation of biogenic petroleum formation. Gold believed that "biology is just a branch of thermodynamics" and that the history of life is just "a gradual systematic development toward more efficient ways of degrading energy".[39]

He began his investigation by studying how earthquakes facilitated the migration of methane gas from the deep Earth to the surface.[40] He speculated that a large enough earthquake would fracture the ground, thus opening up an "escape route" for gas. Gold believed that this would explain the number of unusual phenomena associated with earthquakes, such as fires, flares, earthquake lights and gas emissions. With his colleague Steven Soter, Gold constructed a map of the world depicting major oil-producing regions and areas with historical seismic activity. Several oil-rich regions, such as Alaska, Texas, the Caribbean, Mexico, Venezuela, the Persian Gulf, the Urals, Siberia, and Southeast Asia, were found to be lying on major earthquake belts. Gold and Soter suggested that these belts may explain the upward migration of gases through the ground, and subsequently, the production of oil and gas fields.[40][41]

Gold theorized that since petroleum and its component hydrocarbons were present across the entire universe, there was no reason to believe "that on Earth they must be biological in origin".[39] Gold proposed that fuels were trapped inside the core of the Earth in randomized molecular form nearly 4.5 billion years ago. Over time, the extreme heat of the core "sweated" the rocks that contained these molecules, pushing them up through the porous layers of the Earth. As they move up toward the surface, the hydrocarbons fueled the development of large microbial colonies, which served as the basis for life on Earth. The migrating fossil fuels collect biological remnants before becoming trapped in deep underground reservoirs.[39] Soon after Gold started publishing his theories, researchers discovered a number of ecosystems functioning under "conditions of heat and pressure once thought impossible to sustain life". In addition, Gold discovered that the location of major oil-producing regions in the Middle East and southeast Asia was defined by large scale patterns in surface geology and topography, such as deep fault lines. He also pointed to the abundance of helium in oil and gas reserves as evidence for "a deep source of the hydrocarbons".[40] Moreover, a few oil reserves thought to have been exhausted were suddenly generating vast amounts of crude oil.[42] From this, Gold proposed that the Earth may possess a virtually endless supply – suggesting as much as "at least 500 million years' worth of gas" – of fossil fuels.[43][44]

Gold was accused of plagiarizing the abiogenic theory from Soviet geologists who first published it in the 1950s, but the accusations were refuted.[45][46] After first publishing his views on abiogenic petroleum in 1979, Gold began finding the papers on the subject by Soviet geologists and had them translated. He was both disappointed (that his ideas were not original) and delighted (because such independent formulation of these ideas added weight to the hypothesis). He always credited the Soviet work once he knew about it.[4] His 1987 book Power from the Earth devoted five pages to describing important Russian contributions to the field, including those by Mendeleev, Sokoloff, Vernadsky, Kudryavtsev, Beskrovny, Porfir'ev, Kravtsov, Kropotkin, Valyaev, Voronoy, and Chekaliuk.[45]

Drilling in Siljan

Sweden's Lake Siljan is a large lake created from an eroded impact crater, the Siljan Ring, that was formed by a meteorite impact about 370 million years ago. It was at this lake that Gold proposed as the most likely place to test the hypothesis on the origin of petroleum because it was one of the few places in the world where the granite basement was cracked sufficiently to allow oil to seep up from the mantle.

Gold began testing his theory in 1986 when, with the backing of a group of investors, Vattenfall and the Gas Research Institute, he commenced efforts to drill a deep borehole – named Gravberg-1 – into the earth near Lake Siljan in search of abiogenic gas in the mantle. The region was the site of a large meteor crater, which would have "opened channels deep enough for the methane to migrate upward" and formed deposits in caprock just a few miles beneath the surface.[47] He estimated that the fractures near Lake Siljan reached down nearly 40 kilometres (25 mi) into the earth.[48]

In 1987, approximately 900 barrels (140 m3) of drilling lubricant disappeared nearly 20,000 feet (6,100 m) into the ground, leading Gold to believe that the lubricant had fallen into a methane reservoir.[49] Soon after, the team brought up nearly 100 liters of black oily sludge to the surface. Gold claimed that the sludge contained both oil and remnants of archaebacteria. He argued that "it suggests there is an enormous sphere of life, of biology, at deeper levels in the ground than we have had any knowledge of previously" and that this evidence would "destroy the orthodox argument that since oil contains biological molecules, oil reserves must have derived from biological material". The announcement of Gold's findings was met with mixed reactions, ranging from "furious incredulity" to "deep skepticism".[50] Geochemist Geoffrey P. Glasby speculated that the sludge could have been formed from the Fischer–Tropsch process, a catalyzed chemical reaction in which synthesis gas, a mixture of carbon monoxide and hydrogen, is converted into liquid hydrocarbons.[51] Critics also dismissed Gold's archaebacteria finding, stating that "since micro-organisms cannot survive at such depth, the bacteria prove that the well has been contaminated from the surface".[52] Geochemist Paul Philp analyzed the sludge and concluded that he could not differentiate between the samples of sludge and oil seep found in sedimentary shale rocks near the surface. He reasoned that oil had migrated from the shale down to the granite deep in the ground.[53] Gold disputed Philp's finding, believing that the oil and gas could have just as easily migrated up to the surface: "They would have it that the oil and gas we found down there was from the five feet of sediments on the top – had seeped all the way down six kilometres down into the granite. I mean, such complete absurdity: you can imagine sitting there with five feet of soil and six kilometres underneath of dense granitic rock, and that methane produced up there has crawled all the way down in preference to water. Absolute nonsense."[52]

In light of the controversy surrounding the sludge and possible drill contamination, Gold abandoned the project at Gravberg-1, calling it a "complete fiasco", and redesigned the experiment by replacing his oil-based drilling lubricant with a water-based one.[54]

The drill hit oil in the spring of 1989, but only collected about 80 barrels (13 m3). Gold stated, "It was not coming up at a rate at which you could sell it, but it showed there was oil down there." The drill then ran into technical problems and was stopped at a depth of 6.8 kilometres (4.2 mi). The hole was closed, but a second hole was opened for drilling closer to the "center of the impact ring where there was even less sedimentary rock". By October 1991, the drill hit oil 3.8 kilometres (2.4 mi) into the ground, but many skeptics remained unconvinced of the site's prospects.[48][55] One skeptic, Christer Akerman, the chief geologist of the Geological Survey of Sweden, remarked, "[t]here is every reason to stay calm and await the analysis of what they have found. The point is also that they will have to find commercially viable amounts, and it may be a long time before we know if they do."[56] Geologist John R. Castaño concluded that there was insufficient evidence of the mantle as the hydrocarbon source and that it was unlikely that the Siljan site could be used as a commercial gas field.[57] Some skeptics countered Gold's claims by suggesting that the oil found was actually contamination from the drilling.[33] In 2019, a study of gases and secondary carbonate minerals revealed that long-term microbial methanogenesis has occurred in situ deep within the fracture system of the crater (for at least 80 million years) and with an obvious spatial link to seep oils of surficial sedimentary origin,[58] at odds with Gold's theories of deep abiotic gas migration.

The Deep Hot Biosphere

In a 1992 paper "The Deep Hot Biosphere" in the Proceedings of the National Academy of Sciences,[59] Gold first suggested that microbial life is widespread in the porosity of the crust of the Earth, down to depths of several kilometers, where rising temperatures finally set a limit. The subsurface life obtains its energy not from photosynthesis but from chemical sources in fluids migrating upwards through the crust. The mass of the deep biosphere may be comparable to that of the surface biosphere. Subsurface life may be widespread on other bodies in the solar system and throughout the universe, even on worlds unaccompanied by other stars.

Gold also published a book of the same title in 1999, which expanded on the arguments in his 1992 paper and included speculations on the origin of life.[60]

According to Gold, bacteria feeding on the oil accounts for the presence of biological debris in hydrocarbon fuels, obviating the need to resort to a biogenic theory for the origin of the latter. The flows of underground hydrocarbons may also explain oddities in the concentration of other mineral deposits.

In short, Gold said about the origin of natural hydrocarbons (petroleum and natural gas): Hydrocarbons are not biology reworked by geology (as the traditional view would hold), but rather geology reworked by biology.[45]

Academic legacy

Carl Sagan, hired by Gold after Sagan was denied tenure at Harvard University in 1968

Throughout his academic career, Gold received a number of honors and distinctions. He was a Fellow of the Royal Astronomical Society (1948), the Royal Society (1964),[4] the American Geophysical Union (1962), the American Academy of Arts and Sciences (1974), and the American Astronautical Society, a member of the American Philosophical Society (1972), the United States National Academy of Sciences (1974) and the International Academy of Astronautics, and an Honorary Fellow of Trinity College, Cambridge (1986).[61] In addition, he served as President of the New York Astronomical Society from 1981 to 1986.[25] Gold won the John Frederick Lewis Prize from the American Philosophical Society in 1972 for his paper "The Nature of the Lunar Surface: Recent Evidence"[62] and the Humboldt Prize from the Alexander von Humboldt Foundation in 1979.[61] In 1985, Gold won the prestigious Gold Medal of the Royal Astronomical Society, an award whose recipients include Fred Hoyle, Hermann Bondi, Martin Ryle, Edwin Hubble, James Van Allen, Fritz Zwicky, Hannes Alfvén and Albert Einstein.[63] Gold did not earn a doctorate, but received an honorary Doctor of Science degree from Cambridge University in 1969.[64]

Astrophysicists Geoffrey and Margaret Burbidge remarked that Gold "was one of the outstanding physicists of his time" and that his "versatility was unmatched".[65] In his foreword to Gold's book The Deep Hot Biosphere, theoretical physicist Freeman Dyson stated, "Gold's theories are always original, always important, usually controversial – and usually right."[66]

In the journal Nature, Hermann Bondi wrote "Tommy Gold will long be remembered as a singular scientist who stepped into any field where he thought an option was being overlooked. He was also unusual in working mainly theoretically, but using little mathematics, relying instead on his profound intuitive understanding of physics."[24] Stanley F. Dermott wrote "Tommy was a handsome, charming and generous man and a loyal colleague who formed many long-lasting friendships. A witty and articulate speaker, he was regarded by some as a scientific maverick who delighted in controversy. In reality, he was an iconoclast whose strength was in penetrating analysis of the assumptions on which some of our most important theories are based."[67] Anthony Tucker of The Guardian said, "Throughout his life he would dive into new territory to open up problems unseen by others – in biophysics, astrophysics, space engineering, or geophysics. Controversy followed him everywhere. Possessing profound scientific intuition and open-minded rigour, he usually ended up challenging the cherished assumptions of others and, to the discomfiture of the scientific establishment, often found them wanting. His stature and influence were international."[10] Harvard biologist Stephen Jay Gould labeled Gold as "one of America's most iconoclastic scientists".[39] Gold has been derided by geologists, such as Harmon Craig and John Hunt,[39] who are strongly opposed to Gold's abiogenic petroleum theory. Others had even started campaigns to prevent Gold from publishing his findings.[39]

Personal life

Gold married his first wife, Merle Eleanor Tuberg, an American astrophysicist who had worked with Subrahmanyan Chandrasekhar, in Cambridge in 1947. He had three daughters with her – Linda, Lucy, and Tanya. After divorcing her, Gold married Carvel Lee Beyer in 1972.[5][9][10] With her, he had a daughter Lauren.

Thomas Gold died at the age of 84 from complications due to heart disease, at Cayuga Medical Center in Ithaca, New York. He was buried in the Pleasant Grove Cemetery in Ithaca.[25] He was survived by his wife, four daughters, and six grandchildren.[33]

Selected publications

  • Pumphrey, R. J.; Gold, T. (1947), "Transient reception and the degree of resonance of the human ear", Nature, 160 (4056): 124–125, Bibcode:1947Natur.160..124P, doi:10.1038/160124b0, ISSN 0028-0836, PMID 20344383.
  • Pumphrey, R. J.; Gold, T. (1948), "Hearing. I. The Cochlea as a Frequency Analyzer", Proceedings of the Royal Society B, 135 (881): 462–491, Bibcode:1948RSPSB.135..462G, doi:10.1098/rspb.1948.0024, ISSN 0080-4649, JSTOR 82558.
  • Gold, T. (1948), "Hearing. II. The Physical Basis of the Action of the Cochlea", Proceedings of the Royal Society B, 135 (881): 492–498, Bibcode:1948RSPSB.135..492G, doi:10.1098/rspb.1948.0025, ISSN 0080-4649, JSTOR 82559.
  • Bondi, H.; Gold, T. (1948), "The Steady-State Theory of the Expanding Universe", Monthly Notices of the Royal Astronomical Society, 108 (3): 252–270, Bibcode:1948MNRAS.108..252B, doi:10.1093/mnras/108.3.252, ISSN 1365-2966.
  • Gold, T. (1955), "Instability of the Earth's Axis of Rotation", Nature, 175 (4456): 526–529, Bibcode:1955Natur.175..526G, doi:10.1038/175526a0, ISSN 0028-0836.
  • Gold, T. (1959), "Motions in the Magnetosphere of the Earth", Journal of Geophysical Research, 64 (9): 1219–1224, Bibcode:1959JGR....64.1219G, CiteSeerX 10.1.1.431.8096, doi:10.1029/JZ064i009p01219, ISSN 0148-0227.
  • Gold, T.; Hoyle, F. (1960), "On the origin of solar flares", Monthly Notices of the Royal Astronomical Society, 120 (2): 89–105, Bibcode:1960MNRAS.120...89G, doi:10.1093/mnras/120.2.89, ISSN 1365-2966.
  • Gold, T. (1962), "The Arrow of Time", American Journal of Physics, 30 (6): 403–410, Bibcode:1962AmJPh..30..403G, doi:10.1119/1.1942052, ISSN 0002-9505.
  • Gold, T. (1969), "Rotating neutron stars and the nature of pulsars", Nature, 221 (5175): 25–27, Bibcode:1969Natur.221...25G, doi:10.1038/221025a0, ISSN 0028-0836.
  • Gold, T. (1971), "The Nature of the Lunar Surface: Recent Evidence", Proc. Am. Philos. Soc., 115 (2): 74–82, ISSN 0003-049X, JSTOR 985848.
  • Gold, T. (1979), "Terrestrial sources of carbon and earthquake outgassing", Journal of Petroleum Geology, 1 (3): 3–19, Bibcode:1979JPetG...1....3G, doi:10.1111/j.1747-5457.1979.tb00616.x, ISSN 0141-6421.
  • Gold, T.; Soter, S. (1980), "The deep earth gas hypothesis", Scientific American, 242 (6): 155–161, Bibcode:1980SciAm.242f.154G, doi:10.1038/scientificamerican0680-154, ISSN 0036-8733.
  • Gold, T.; Soter, S. (1982), "Abiogenic methane and the origin of petroleum", Energy Exploration & Exploitation, 1 (2): 89–104, doi:10.1177/014459878200100202, ISSN 0144-5987.
  • Gold, T. (1987), Power From the Earth: Deep Earth Gas - Energy for the Future, London: Dent & Sons, ISBN 978-0-460-04462-2.
  • Gold, T. (1992), "The deep, hot biosphere", Proceedings of the National Academy of Sciences, 89 (13): 6045–6049, Bibcode:1992PNAS...89.6045G, doi:10.1073/pnas.89.13.6045, ISSN 1091-6490, PMC 49434, PMID 1631089.
  • Gold, T. (1999), "The Deep Hot Biosphere", Proceedings of the National Academy of Sciences of the United States of America, New York: Springer, 89 (13): 6045–9, doi:10.1073/pnas.89.13.6045, ISBN 978-0-387-98546-6, PMC 49434, PMID 1631089.
  • Gold, T. (2012), Taking the Back Off the Watch: A Personal Memoir, New York: Springer, ISBN 9783642275876.
gollark: Observe, my laser. It accelerates light to speeds so high that it's not actually rendered.
gollark: With great difficulty, or subframe?
gollark: Oh, right. You're limited to however much fits on the screen.
gollark: moev?
gollark: Click the little page-with-folded-corner button.

See also

Notes

  1. "John Frederick Lewis Award: Recipients". American Philosophical Society. Retrieved 4 May 2020.
  2. "Milestones". Science. 305 (5680): 39b–. 2004. doi:10.1126/science.305.5680.39b..
  3. Who Was Tommy Gold? Published by aip.org Retrieved on April 28, 2019
  4. Bondi, H. (2006). "Thomas Gold. 22 May 1920 – 22 June 2004: Elected FRS 1964". Biographical Memoirs of Fellows of the Royal Society. 52: 117–135. doi:10.1098/rsbm.2006.0009.
  5. Mitton 2004.
  6. Burbidge & Burbidge 2006, p. 3.
  7. Burbidge & Burbidge 2006, pp. 3–4.
  8. Burbidge & Burbidge 2006, p. 4.
  9. The Telegraph 2004.
  10. Tucker 2004.
  11. Burbidge & Burbidge 2006, p. 5.
  12. Hall, James W. (2000), Handbook of otoacoustic emissions, San Diego: Singular/Thomson Learning, p. 546, ISBN 978-1-56593-873-1.
  13. Burbidge & Burbidge 2006, p. 6.
  14. Silk, Joseph (September 5, 1994), Fundamental Issues in Cosmology, University of California, Berkeley, retrieved June 17, 2009.
  15. Bondi & Gold 1948, pp. 253–254.
  16. Bondi & Gold 1948, p. 255.
  17. Bondi & Gold 1948, p. 256.
  18. Bondi & Gold 1948, p. 262.
  19. Burbidge & Burbidge 2006, p. 7.
  20. Hawking, Stephen (2003), "Sixty years in a nutshell", in Gibbons, G. W.; Shellard, E. Paul S.; Rankin, Stuart J. (eds.), The future of theoretical physics and cosmology, Cambridge: Cambridge University Press, p. 109, ISBN 978-0-521-82081-3.
  21. Gold, T. "Cosmic Garbage," Air Force and Space Digest, 65 (May 1960).
  22. Burbidge & Burbidge 2006, pp. 6–7.
  23. Wilford 1980.
  24. Bondi 2004.
  25. Pearce 2004.
  26. Dermott 2004, p. 1674.
  27. Bondi 2004b.
  28. Gold 1959, p. 1219.
  29. Lang, Kenneth R. (2006), A Companion to Astronomy and Astrophysics: Chronology and Glossary with Data Tables, New York: Springer, p. 77, ISBN 978-0-387-30734-3.
  30. Lang, Kenneth R. (2008), The Sun from Space (2nd ed.), New York: Springer, p. 326, ISBN 978-3-540-76952-1.
  31. Burbidge & Burbidge 2006, pp. 9–10.
  32. Levy, David H. (2000). Shoemaker by Levy: The Man Who Made an Impact. Princeton University Press. p. 106. ISBN 978-0691002255.
  33. Bernstein 2004.
  34. Burbidge & Burbidge 2006, p. 8.
  35. Apollo Lunar Surface Closeup Camera (ALSCC) Image Catalog, Apollo Image Atlas, Lunar and Planetary Institute
  36. Burbidge & Burbidge 2006, p. 9.
  37. Oral History Transcript – Thomas Gold, American Institute of Physics Niels Bohr Library & Archives, retrieved June 19, 2009.
  38. Gold 1999, p. 53.
  39. Ringle 1999.
  40. Glasby 2006, p. 89.
  41. Gold & Soter 1980.
  42. Cooper, Christopher (16 April 1999). "Odd Reservoir Off Louisiana Prods Oil Experts to Seek a Deeper Meaning". Wall Street Journal. Houston, TX. Retrieved 18 May 2015. Something mysterious is going on at Eugene Island 330
  43. Vielvoye, Roger (February 5, 1979), "Gold's gas theory", Oil & Gas Journal, p. 30.
  44. Laskoski, Gregg (14 September 2011). "Abiotic Oil a Theory Worth Exploring". U.S. News & World Report. Retrieved 18 May 2015. Oil may not be formed the way we think it is.
  45. DeRosa, Neil (15 September 2007). "Black Gold: Thomas Gold's Deep Hot Biosphere and the Deep-Earth theories of the Origin of Petroleum". Meta Research Bulletin. Archived from the original on 20 May 2015. Retrieved 18 May 2015.
  46. "Plagiarism Overview". Gas Resources. Retrieved 18 May 2015. The attempted plagiarism of the modern Russian–Ukrainian theory of deep, abiotic petroleum origins
  47. Sullivan, Walter (July 6, 1986), "Swedish Search for Methane Tests Radical Theory of Fuels", The New York Times.
  48. Shiry, John (May 30, 1991), "Gold Drills For Gas In 'The Basement': Weird science?", Financial Post.
  49. Sullivan, Walter (March 22, 1987), "Natural Gas Well Is Believed Found", The New York Times.
  50. Hodgkinson, Neville (June 12, 1988), "Sludge at core of earth boosts deep oil theory", The Sunday Times.
  51. Glasby 2006, p. 90.
  52. Cole 1996, p. 748.
  53. Aldhous, Peter (1991), "Black Gold Causes a Stir", Nature, 353 (593): 55, Bibcode:1991Natur.353..593A, doi:10.1038/353593a0, ISSN 0028-0836.
  54. Cole 1996, p. 747.
  55. Haliechuk, Rick (February 14, 1992), "Scientist says our bedrock contains vast oil reserves", Toronto Star.
  56. "Swedish–U.S. team believes it has proof of non-fossil oil, gas", Reuters, October 16, 1991.
  57. Castaño, John R. (1993), "Prospects for commercial abiogenic gas production: Implications from the Siljan Ring area, Sweden.", U.S. Geological Survey Professional Paper (1570): 133–154.
  58. Drake, Henrik; Roberts, Nick M. W.; Heim, Christine; Whitehouse, Martin J.; Siljeström, Sandra; Kooijman, Ellen; Broman, Curt; Ivarsson, Magnus; Åström, Mats E. (2019-10-18). "Timing and origin of natural gas accumulation in the Siljan impact structure, Sweden". Nature Communications. 10 (1): 4736. doi:10.1038/s41467-019-12728-y. ISSN 2041-1723. PMC 6802084. PMID 31628335.
  59. Gold 1992.
  60. Thomas Gold, 1999, The Deep Hot Biosphere, Springer, ISBN 0-387-95253-5
  61. Todd, Louise (May 2006), Royal Society: Gold, Thomas (1920–2004), AIM25, retrieved June 21, 2009.
  62. Recipients of the John Frederick Lewis Award, American Philosophical Society, January 7, 2009, archived from the original on December 29, 2008, retrieved June 21, 2009.
  63. Winners of the Gold Medal of the Royal Astronomical Society, Royal Astronomical Society, February 15, 2005, archived from the original on November 22, 2005, retrieved June 21, 2009.
  64. Dermott 2004, p. 1675.
  65. Burbidge & Burbidge 2006, p. 11.
  66. Gold 1999, p. xi.
  67. Dermott 2004, p. 1677.

References

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