Nicholas Mayall

Nicholas U. Mayall
Upper body of a serious and dignified man in his fifties, with graying hair combed back and in a dress jacket with white shirt and a bolo tie and with his hands coupled together on top of some books.
Born (1906-05-09)May 9, 1906
Moline, Illinois, U.S.
Died January 5, 1993(1993-01-05) (aged 86)
Tucson, Arizona
Residence U.S.
Nationality American
Fields Astronomy
Institutions Mount Wilson Observatory
Lick Observatory
Kitt Peak National Observatory
Cerro Tololo Inter-American Observatory
Alma mater University of California, Berkeley

Nicholas Ulrich Mayall (May 9, 1906 – January 5, 1993) was an American observational astronomer. After obtaining his doctorate from the University of California, Berkeley, Mayall worked at the Lick Observatory, where he remained from 1934–1960, except for a brief period at MIT's Radiation Laboratory during World War II.

During his time at Lick, Mayall contributed to astronomical knowledge of nebulae, supernovae, spiral galaxy internal motions, the redshifts of galaxies, and the origin, age, and size of the Universe.[1][2] He played a significant role in the planning and construction of Lick's 120-inch (3.0 m) reflector, which represented a major improvement over its earlier 36-inch (0.91 m) telescope.

From 1960, Mayall spent 11 years as director of the Kitt Peak National Observatory until his retirement in 1971. Under his leadership KPNO, and the Cerro Tololo Inter-American Observatory, developed into two of the world's top research observatories, equipped with premier telescopes.[3] Mayall was responsible for the construction of the 4-meter (160 in) Kitt Peak reflector, which was named after him. When Mayall died in 1993, his ashes were spread high on an empty ridge of Kitt Peak.

Early life

Mayall's father, Edwin L. Mayall, Sr., was an engineer for a manufacturing company in Illinois. His mother, Olive Ulrich Mayall, despite never attending college herself, set high educational standards for Mayall and his younger brother (Edwin, Jr., born 1907).[4] Sometime between his brother's birth and 1913, the family moved to California's Modesto area, where Mayall entered first grade. Some time before 1917, they moved again, to Stockton where they remained until 1924 and Mayall's graduation from Stockton High School (except for a brief return to Peoria, Illinois during 19181919).[5] During this period, presumably during his high school years, Mayall's parents divorced.[6]

Time-lapse photograph of white buildings on top of a mountain at night with stars streaking across the sky.
The Lick Observatory at night.

During his senior year,[4] in the fall of 1923, Mayall was secretary of the school science club and set up a club visit to the Lick Observatory. His father permitted him to use his car, a Moline Knight, to transport the club members up the dirt and gravel winding mountain road leading to the observatory. This was Mayall's first visit to the observatory where he would spend much of his career. After visiting, he read all the astronomy books available in the local libraries, although he did not at that time imagine making astronomy his profession.[4][7]

Education

Mayall began college in the fall of 1924 at the University of California, Berkeley, studying for a degree in mining. He took up residence with his mother in an apartment on Durant Avenue, and worked at the UC Berkeley library to help support them both. Mayall generally did well at university, and was eventually elected to the Sigma Xi and Phi Beta Kappa honor societies. However, at mid-term examinations of his second year, he achieved poor grades in mineralogy and chemistry laboratory. At a meeting with the dean to discuss his grades the latter became aware that Mayall was color blind, which prevented him from observing small color changes in bead and flame tests, and also kept him from seeing small color changes in precipitations and titrations. Mayall's adviser recommended that he change his major, as he would not be able to graduate as a mining engineer with such a handicap.[8][9]

Mayall's mother encouraged him to study whatever interested him the most, and to do it well, so he considered astronomy as an alternative to mining. After asking many professors in the astronomy department whether they enjoyed their work and whether they made a satisfactory wage, and being content with their answers, he transferred to the College of Letters and Science to major in astronomy. This did not set him back in his degree requirements because almost all of his first year studies had been in basic physical sciences and mathematics. Eventually Mayall discovered that he greatly enjoyed astronomy, and decided upon a course of graduate level study followed by a career as a research scientist.[10][11]

After graduating in 1928,[11] Mayall decided to remain at Berkeley, as it had the best astronomy graduate program of the day. However, he took a hiatus from pursuing his advanced degree and went to work as a human computer at the Mount Wilson Observatory from 19291931, where he assisted luminaries such as Edwin Hubble, Paul W. Merrill, and Milton L. Humason.[12][13] This activity resulted in him co-authoring papers on Pluto's mass[14][15] and orbit with Seth Barnes Nicholson and others, shortly after Pluto's discovery[2][16][17][18][19]

Mayall returned to Berkeley in 1931 to pursue graduate studies. His thesis topic, suggested by Hubble, was to count the number of galaxies per unit area on the sky as a function of position on direct plates taken with the Crossley reflector at Lick. This should have supplemented the counts Hubble himself was making using the 60-inch (1.5 m) and 100-inch (2.5 m) telescopes at Mt. Wilson. Mayall successfully completed his thesis and was awarded his PhD degree in 1934.[20] Hubble complimented Mayall for his work, although significant results were never achieved (nor by Hubble either) due to the lack of accurate magnitude standards for the faint galaxies that were measured and by the (then unrealized) very strong tendency of galaxies to cluster.[21][22]

While working on his thesis, Mayall had an idea of designing a small, fast slitless spectrograph,[23] optimized for nebulae and galaxies. He believed that if it were used in conjunction with the Crossley reflector it would make that facility competitive for at least some of the work that Humason and Hubble were doing with the larger Mt. Wilson telescopes. It was never expected to compete with the Mt. Wilson 100-inch (2.5 m) instrument for stars or elliptical galaxies, which have condensed and relatively bright nuclei. The spectrograph was to be used instead to study extended, low-surface-brightness gaseous nebulae or irregular galaxies. Mayall's thesis advisor, William Hammond Wright, and the then head of the Lick stellar spectroscopy program, Joseph Haines Moore, encouraged him to develop his spectrograph. The device was constructed by the Lick Observatory's own workshop, and proved to be more efficient for extended, low-surface-brightness objects, particularly in the ultraviolet part of the spectrum, thus confirming the expectations of Mayall. With Wright's strong encouragement, Mayall had used fused quartz to make ultraviolet transmitting optics, whereas the Mt. Wilson spectrographs used heavy glass lenses and prisms, which absorb ultraviolet radiation.[24][25][26]

Lick Observatory

A white one story building with tall thin windows and an alcove entrance; at the right far end, a white domed building is present.
The main Lick Observatory building and the South (large) Dome that houses the south telescope

While Mayall hoped to join the Mount Wilson team upon earning his doctorate, there were no openings during the Great Depression. Instead, he began his career at Lick, which was afforded by the number two janitor resigning and Mayall being given a one-year position as observing assistant with janitorial duties limited to maintaining the darkrooms and keeping instrument rooms clean. The following year, one of the senior astronomers joined the Berkeley department and his salary was split between Mayall and another young astronomer, Arthur Bambridge Wyse.[24][27]

On June 30, 1934, Mayall married Kathleen (Kay) Boxall from Los Angeles, who he had met during his two years in Pasadena. They lived in a small apartment that was part of the little astronomy village on the Mount Hamilton summit, where all Lick astronomers resided at that time.[28][29]

Using his newly built spectrograph, Mayall was the first to determine the radial velocities of many knots of gas in the Crab Nebula.[17] Using these data and the previously published angular rate of expansion of the nebula, he was able to estimate its distance. Consequently, he became the first person to recognize and demonstrate that the Crab Nebula was the remnant of a supernova observed and recorded in 1054 (SN 1054), rather than a classical nova.[30][31] Walter Baade was instrumental in stimulating and counseling Mayall after around 1939, taking on the role previously filled by Hubble.[32]

In 1941, together with Arthur Wyse and Lawrence Aller, Mayall studied the rotation of nearby galaxies and found that there was much matter that was too faint to be observed, but which could be detected by way of its gravitational effect.[33] He spent about three years until 1942 researching 50 Milky Way globular clusters, and found the Milky Way had about one half of the mass previously supposed.[34]

While at the Lick Observatory, Mayall collaborated on a 20-year project with astronomers at Mount Palomar and Mount Wilson on the Big Bang theory of the beginning of the Universe. Together with Milton L. Humason and Allan R. Sandage, he wrote a 1956 paper concluding that the age of the Universe was six billion years (three times the prior estimate, and about half the modern value), and its size three times larger than thought.[2][35]

World War II

After the United States entered World War II, Mayall accepted a position at the MIT's Radiation Laboratory in Cambridge, Massachusetts to work on radar development. He began his work early in 1942 in Cambridge, which was the only time during his adult life that he resided outside California or Arizona. However, the climate of Massachusetts was unlike that of California, which he and his family were accustomed to, and in the middle of 1943 he arranged a transfer to the Pasadena Mt. Wilson Observatory offices. Many wartime Office of Scientific Research and Development (OSRD) projects related to optics, aerial gunnery, aerial photography, and bombing tactics were already in progress there. Unhappy with the management of his project and feeling his talents were not being well used, he transferred again in February 1944 to Caltech to work on the development of large rockets. There he became an expert on high-speed photography, which was used to analyze rocket trajectories. In the spring of 1945, he was transferred to a secret atomic bomb project that also required high-speed photography. He visited Los Alamos twice, including once around the time of the Trinity test. By October 1, 1945, the war had ended and Mayall had returned to astronomical research at Lick.[36][37][38]

120-inch (3.0 m) telescope

A very large, hollow metal framed cylindrical structure pointing straight up with a man standing underneath working on the many electronic components at the bottom.
The 120-inch (3.0 m) Lick telescope, with the dome open for maintenance

During World War II Mayall became an important influence on Lick Observatory's future. Ever since 1931, when he had returned to Lick and Berkley after serving two years as an assistant at Mount Wilson, he had felt strongly that Mount Hamilton required a larger telescope.[39] The astronomers at Lick were proud of their ability to achieve important results with Lick's small 36-inch (0.91 m) Crossley reflector. Its diminutive size first became apparent in 1908, when Mount Wilson's 60-inch (1.5 m) telescope saw first light. This was accentuated by the opening of the 72-inch (1.8 m) Dominion Astrophysical Observatory in 1917, and Mount Wilson's even larger 100-inch (2.5 m) Hooker telescope in 1919. Mayall was adept at working with the small Crossley, but understood that it could never really stand up to a competing telescope that collected nine times the amount of light. This was only going to get worse when the 200-inch (5.1 m) Hale Telescope was completed at Palomar Observatory. Mayall and other young faculty at Lick thought that the older faculty such as Moore and Wright were too committed to the small telescopes and should have tried harder to obtain a larger reflector.[40]

Unknown to Mayall, Lick observatory director William H. Wright and his predecessor, Robert G. Aitken, had both tried in secret to raise money for a larger reflector to replace the 36-inch (0.91 m) Crossley Reflector. They tried both private sources as well as trying to get Robert Gordon Sproul, the University of California President, to provide for one in the budget. Despite multiple attempts, they continued to fail, primarily due to the Great Depression. However, in 1942, Sproul asked Paul W. Merrill from Mt. Wilson to succeed Wright, but was turned down. Agitated by the refusal, Sproul changed his stance and told the regents that they had to find a way to raise money for a new telescope once the war ended. At about this time, Sproul promised or secretly appointed C. Donald Shane as director of Lick, to take over when the war ended.[40]

The plan for a large telescope was leaked around September 1944 in the form of the University's budget proposals. Wright and Joseph H. Moore, interim wartime Lick director, imagined an 85-inch (2.2 m) or 90-inch (2.3 m) reflector based upon the funds proposed in the budget by Sproul. Mayall and Gerald E. Kron sent a letter to Sproul representing the younger Lick staff members, in which they requested a meeting to discuss the kind of telescope to be built. They met with Sproul in December 1944 in Sproul's Los Angeles office. Mayall spoke of the key need for a telescope exceeding 90 inches (2.3 m). At the Caltech optical shop in Pasadena he had seen the nearly completed 120-inch (3.0 m) Pyrex glass disc that was initially planned to be used as a flat in the auto-collimation test of the 200-inch (5.1 m) Palomar mirror[41] and urged Sproul to have the Lick telescope use a mirror of that size. Much to their surprise, Sproul agreed.[40][42]

Shane was appointed chairman of a committee formed by Sproul in the beginning of 1945, to plan the new reflector. Other committee members included Mayall, Moore, Walter S. Adams and Ira S. Bowen. The committee functioned primarily through correspondence. Mayall's first letter helped to convince Shane that 120 inches (3.0 m) was feasible instead of just 90-inch (2.3 m). Mayall helped to bridge the gap between the experienced team of telescope designers in Pasadena and Shane, who was more experienced as a university administrator and professor. Adams and the executive officer of the 200-inch (5.1 m) project, John August Anderson, shared their experience, drawings and plans with the Lick design committee. On March 6, 1945, with both Mayall and Shane present, the committee decided upon the basic parameters of what would become the 120-inch (3.0 m) C. Donald Shane telescope. On March 7, Mayall joined Shane, Wright and Moore (not present at the March 6 meeting), at Mt. Hamilton to choose the location upon which to build the reflector.[40]

Postwar Lick research

Stairs leading up to a small white building with a domed silver roof next to a tree.
The 36-inch (0.91 m) Crossley Reflector at Lick Observatory

During the long period of building the 120-inch (3.0 m) telescope, Mayall continued to use Lick's 36-inch (0.91 m) Crossley Reflector and focused his efforts on utilizing his slitless spectrograph, which was optimized for extended, low-surface-brightness clusters, galaxies, and nebulae. In 1946, he completed his pre-war effort to get integrated spectra of globular clusters and published the work. His paper was key in demonstrating that the system of Milky Way globular clusters shares only slightly the galactic rotation found in the flattened disc of interstellar matter and young stars in our galaxy.[43][44][45] In 1948, Mayall serendipitously discovered a type II supernova while conducting other research.[46][47]

Other research Mayall performed included the 20 year collaboration (formulated in 1935 by Hubble) with Milton Humason, to gather redshift values for all northern galaxies brighter than +13 visual magnitude. Mayall handled the brighter galaxies on the Crossley, while Humason tackled the fainter ones using the Mount Wilson 100-inch (2.5 m). This work resulted in the 1956 paper he co-authored with Humason and Allan Sandage, on the rate of expansion of the Universe. The paper listed over 800 redshift values (300 determined by Mayall) for galaxies measured from 1935 to 1955 at Lick, Wilson and Palomar.[17][35][48][49][50][51]

At Lick, he also studied galactic dynamics, such as the rotational motion of the Andromeda and Triangulum galaxies.[2][17][52] He presented this work at a symposium on the structure of the Milky Way on June 23, 1950, at the University of Michigan in Ann Arbor.[52] This work demonstrated the inner solid-body rotation and the outer Keplerian motion.[17] In 1953, together with O.J. Eggen, Mayall identified six likely globular clusters (including Mayall II) around the Andromeda galaxy in a Palomar 48-inch schmidt plate exposed in 1948 that was provided to them by Hubble.[53]

Gerry Kron marveled at the sensitivity of Mayall's eyes that could reach down to +17 visual magnitude using the 36-inch (0.91 m) telescope.[17] Mayall's eyesight later deteriorated to the point that he could no longer read.[17]

The new 120-inch (3.0 m) telescope became operational at the beginning of 1960. Mayall immediately began using it,[54] although he left Lick in September of that year.[55]

Kitt Peak National Observatory

Panoramic view of a mountain top with trees and some white domed telescope buildings and a road leading up to the top.
Overview of some of the telescopes at the Kitt Peak National Observatory

Mayall moved on from the University of California (after more than 25 years[37] progressing from student to astronomer), to become the second director of Kitt Peak National Observatory (KPNO).[56] With financial support from the National Science Foundation, several universities had formed a consortium — the Association of Universities for Research in Astronomy (AURA). Its purpose was to create and run a research observatory for American astronomers. The first director was Aden B. Meinel, who chose the site near Tucson at the 7,000-foot (2,100 m) Kitt Peak, and oversaw the building of its first telescope, the 84-inch (2.1 m) reflector which was completed in the spring of 1960.

Looking down from the sky at a series of buildings and a large domed telescope building that dwarfs the others. An access road encircles the complex.
Aerial view of the Cerro Tololo Interamerican Observatory

However, the AURA board decided that Meinel was not well suited for the job and chose Mayall to replace him on October 1, 1960,[57] even though he had no previous administrative experience. Mayall had previously been appointed (in 1958) as a consultant to AURA, due to his experience in planning the Lick 120-inch (3.0 m) telescope. The board's president was Shane, who was representing the University of California, and he helped convince Mayall to accept the offer.[58][59][60][61]

As director, Mayall oversaw the building of the 4-meter (160 in) Kitt peak reflector.[62] It was still being built when he retired in 1971, and was completed in 1973,[63] at which point it was named the Nicholas U. Mayall Telescope in his honor.[64][65] Mayall was intimately involved in the expansion of the national observatory to the Southern hemisphere in what eventually became the Cerro Tololo Interamerican Observatory (CTIO). The 4-metre (160 in) Victor M. Blanco Telescope at CTIO (identical to the Mayall Telescope at Kitt Peak) saw first light in 1974 and was completed in 1976.[54][60][64][66][67]

Retirement

Mayall retired in 1971, at the age of 65,[68][69] an event that was honored by a symposium held on his birthday, May 8.[17][70] During his retirement, he continued to play an active role in many organizations, including the overview committee for Fermilab.[17] He died on January 5, 1993, of complications caused by diabetes; his ashes were spread high on an empty ridge of Kitt Peak.[2][71] Mayall was survived by his wife of 58 years, Kathleen Boxall,[2][17] and their two children: Bruce Ian Mayall (1939) and Pamela Ann Mayall,[2][17] their two grandchildren:[2] Shane Nicholas Oakes (1977) and Bryce Oakes Mayall (1979).

Honors

Honor Societies

Named after Mayall

Publications

See also

References

  1. Osterbrock 1996, pp. 208–9
  2. 1 2 3 4 5 6 7 8 Lambert 1993, p. B8
  3. Osterbrock 1996, pp. 205–8
  4. 1 2 3 Osterbrock 1996, p. 190
  5. Mayall 1970, p. 107
  6. Osterbrock 1996, pp. 189–90
  7. Mayall 1970, p. 108
  8. Osterbrock 1996, pp. 190–1
  9. Mayall 1970, pp. 109–10
  10. Osterbrock 1996, p. 191
  11. 1 2 Mayall 1970, p. 110
  12. Osterbrock 1996, p. 192
  13. Associated Press 1933
  14. Nicholson & Mayall 1930
  15. The New York Times 1931
  16. Nicholson & Mayall 1931
  17. 1 2 3 4 5 6 7 8 9 10 11 Abt 1993
  18. Mayall 1970, p. 112
  19. Associated Press 1930
  20. Osterbrock 1996, p. 193
  21. Osterbrock 1996, pp. 193–4
  22. Mayall 1970, pp. 113–4
  23. Wilson 2004, p. 432
  24. 1 2 Osterbrock 1996, p. 195
  25. Osterbrock & Baade 2001, pp. 63, 109, 118
  26. Mayall 1970, pp. 114–5
  27. Mayall 1970, p. 115
  28. Osterbrock 1996, pp. 194–5
  29. Mayall 1970, pp. 115–6
  30. Osterbrock 1996, pp. 195–6
  31. Associated Press 1939
  32. Osterbrock & Baade 2001, pp. 63–4, 90, 124–5
  33. Kaempffert 1941
  34. Callenders 1942
  35. 1 2 Humason, Mayall & Sandage 1956
  36. Osterbrock 1996, pp. 197–200
  37. 1 2 Mayall 1970, p. 116
  38. Osterbrock & Baade 2001, p. 103
  39. Mayall 1970, p. 118
  40. 1 2 3 4 Osterbrock 1996, pp. 200–3
  41. Wilson 2004, p. 452
  42. Mayall 1970, pp. 118–9
  43. Osterbrock 1996, p. 203
  44. Mayall 1946
  45. Kaempffert 1947
  46. The New York Times 1948
  47. Kaempffert 1948
  48. McCray 2004, p. 57
  49. Laurence 1954
  50. Plumb 1955
  51. Kaempffert 1956
  52. 1 2 Federer Jr. 1950
  53. Ma et al. 2007, p. 1621
  54. 1 2 Mayall 1970, p. 119
  55. Osterbrock 1996, p. 205
  56. Associated Press 1960
  57. Lindsley, Edmondson & Kiani 2008, p. 3
  58. Edmondson 1997, pp. 114, 125–6
  59. McCray 2004, p. 55
  60. 1 2 Freeman 1979
  61. Osterbrock 1996, p. 206
  62. Sullivan 1968
  63. McCray 2004, pp. 86, 309
  64. 1 2 Bouchet et al. 2000
  65. Eglin 1973
  66. Osterbrock 1996, pp. 207–8
  67. Gregory & Abbott 2008
  68. Osterbrock 1996, p. 208
  69. McCray 2004, p. 86
  70. Lindsley, Edmondson & Kiani 2008, p. 5
  71. Greenstein 1994

Cited sources

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