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| Harriet Brooks, linocut 9.25" x 12.5" by Ele Willoughby, 2018 |
Born July 2, 1876, in Exeter, Ontario, Harriet was one of nine children. Her family was not wealthy and after her father's flour mill burned down and was not covered by insurance, occasionally food was a bit scarce. Only she and her sister Elizabeth, who both had an aptitude for mathematics, attended university. Harriet entered McGill in 1894, only 6 years after the university had admitted its first female student. She graduated in 1898 with a B.A. in mathematics and natural science just as Rutherford arrived from England. He took her on as his first graduate student. He was careful not to assign her a problem in the new and technically difficult field of radioactivity right away, because he felt it was important that young researchers have some appreciated and acknowledged success at the beginning of their carreers, or they might become mistakenly disappointed in their abilities. So after publishing her results in 1899 in the Transactions of the Canadian section of the Royal Society, Harriet completed her master's degree in 1901 on the "Damping of Electrical Oscillations," before embarking on radioactivity research. As a promising researcher, she was appointed a non-resident mathematics tutor for the new women's college Royal Victorian College at McGill in 1899.
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| Apparatus and schematics of their thorium emanations research, Cabinet B of the Rutherford Museum at McGill |
Assigned to on the puzzle of the thorium "emanation" she discovered some of the earliest evidence of transmutation! At that time, physicists knew that some elements gave off alpha particles (which we now know are helium nuclei, two protons and two neutrons bound together), beta particles (which we now know are electrons) and gamma rays, but these "emanations" were different. They knew it might be a radioactive gas, vapour or even a fine powder, but she concluded that it must be a gas of lower atomic weight than thorium - something chemists of the day believed impossible. She co-authored the paper with Rutherford, "The New Gas from Radium" in 1901. This new gas was Radon. She went on to work on measuring the atomic mass of this new gas. Assigning the discovering of a new element to a given individual, especially at this heady time, is tricky, though history is often told much more simply. Some argue that Friedrich Ernst Dorn discovered the element, as he published that Radium compounds emanate a radioactive gas he named Radium Emanation (Ra Em) in 1900. This however, is merely an observation of the existence of a specific isotope of Radon. Rutherford and Brooks themselves credited the Curies for first observing the "emanation". Today, many credit Rutherford with the "true" discovery of Radon as an element (i.e. a "New Gas"), though he himself was always careful to reference Brooks' work. Between his sole-authored Nature paper of 1901, and his towering reputation, Brooks' role in this discovery was been largely forgotten for decades and only recently, has her role been rediscovered.* While the complete story is messy, a strong case can be made that Harriet Brooks discovered Radon, a new element with a lower atomic mass. It is incontestable that she was amongst the first in the world to observe any form of the element and to attempt to measure its atomic mass.
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| This 2015 issue of the Canadian Journal of Physics had the cover caption: Harriet Brooks, pioneering Canadian nuclear physicist, discovered radon in 1901. Her Ph.D. supervisor, Ernest Rutherford, compared her to Marie Curie. On the faculty of Barnard College, she was forced to resign when she became engaged, as marriage was forbidden for female faculty, a great loss to physics (photo courtesy of Wm. Notman & Son; II-123880, McCord Museum). |
Instead of returning to Bryn Mawr to complete her doctorate, she went back to McGill to work with Rutherford for a year. Her biographers Marelene Rayner-Canham and Geoff Rayner-Canham suggest this may have due to her loss of confidence. While back at McGill, she noticed what she called the 'volatility' of radioactive substances, and how a non-radioactive plate placed in a radioactive container would become radioactive. She was seeing the first evidence of her discovery of atomic recoil. When the radioactive element emitted an alpha particle in one direction, the daughter nuclei would be propelled in the opposite direction - sometimes with such force that they became embedded in the plate (which hence becomes radioative). This method was later used by Otto Hahn and Lise Meitner to separate daugther nuclei and identify new elements. Hahn (who alone was granted the Nobel for the discover of nuclear fission he and Meitner made)*** claimed to have discovered atomic recoil, but Rutherford wrote to him to point out it was in fact Brooks. During this time she also charted the decays of Thorium, Radium, and Actinium and discovered not only did radioactive elements transmutate into new elements, but that these products in turn decayed, laying the groundwork for the discovery of nuclear decay series. She published her results in 1904.
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| One of the important examples of a nuclear decay series showing how various Uranium isotopes can transmutate in a series of reaction (i.e. to Thorium to Radium to Radon...) |
In 1904, she became a physics tutor at Columbia's women's college Barnard College. She met physics professor Bergen Davis, fell in love and they became engaged in 1906. The dean Laura Gill demanded her resignation, insisting she couldn't be both a physicist and a wife. Brooks protested, writing, "I think also it is a duty I owe to my profession and to my sex to show that a woman has a right to the practice of her profession and cannot be condemned to abandon it merely because she marries." The head of physics Margaret Maltby defended Brooks and her tremendous skills as a teacher and experimentalist, but the dean insisted she had to choose. Brooks ultimately broke off the engagement, and then nonetheless resigned due to the stress. She then took a step away from the scientific life.
In 1906 she spent her summer with the Fabian socialists at Summerbrook, the utopian commune established by Prestonia Mann Martin in the Adirondacks. She fell in with Marxist writer Maxim Gorky, his (then mistress, eventual second wife) Maria Andreyeva and their entourage and ended up, after a visit to Montreal, travelling with the couple by ship from New York to Naples and Capri! Eventually she seems to have bored of this and went to work with Marie Curie in Paris. Curie offered her a position for another year, but Rutherford, who was returning to England to work in Manchester offered her a fellowship. She accepted, but then suddenly withdrew. While in Montreal she had become reaquainted with her engineering tutor Frank Pitcher. He had been writing her ever since insisting that she should marry him as he could provide a stable future. She had been encouraged by her friends Mrs. Mary Rutherford (Ernest's wife) and Prestonia Martin (who both harboured strong traditional ideas about marriage) and she had ultimately gave in and accepted his proposal. He promptly took off on a mountain climbing tour of Europe, insisted on a religious ceremony despite her wishes and left her to return to Montreal and plan the wedding.
They had three children, but tragically lost one to spinal meningitis in childhood and a second to suicide while a student at McGill. Brooks, now Mrs. Frank Pitcher, never returned to research but took on the vocation of upper middle-class wife and mother until her premature death of leukimia at age 56, likely due to her exposure to Radon. She lived a quiet life after her remarkable 6 year science career, gardening and corresponding with those who had known her when she had been young and free. The social pressures and mores of the time, robbed physics of one of its bright lights.
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| Schematic electron shell diagram for Radon |
I put a lot of thought into how to portray her. There is only a single, easily found, clear photo of her during her scientific career - her graduation photo. Showing her with a schematic diagram of Radon, like the photoillustration used by the Canadian Journal of Physics, seems an obvious choice. I considered that, and also, showing Thorium decaying to Radium to Radon, to allude to her discovery of Radon and chains of transmutations. However while these diagrams of atom are very graphic and make for an interesting image, they're misleading in a few ways. First, by showing the electron shells, we focus on chemistry and what's beyond the nucleus (and neither were what Brooks and colleagues were studying). Secondly, neither the nucleus nor electrons had been discovered during her time, so this is anarchronistic. I thought of showing nuclei undergoing alpha decay, and the daughters likewise decaying (more like my portrait of Lise Meitner), but this too whould be anachronistic; prior to 1906, no one had any idea there were protons and neutrons. So, I specifically showed what she discovered - atomic recoil - and depicted it simply, as it way understood at the time. I show Radium (just as a particle) spontaneously give off an alpha particle in one direction and emitting Radon in the other (what we now call the daughter nuclei). I chose this specific reaction to also reference her discovery of Radon itself. I considered showing the actual apparatus she used to investigate "Thorium emanations" since it's quite amazing that McGill has preserved these and posted photos online, but on its own it doesn't tell much of the story (unless you are already well-versed in the early history of research on radioactivity). I thought about showing our modern understanding of radioactive decay series (like the Uranium series above) but that also would have been anarchronistic. To allude to her third discovery, that these transmutations can occur in chains of reactions, at the bottom I have included a diagram that Rutherford published in 1905, labelled as the team at McGill then understood it: Radium gives off an alpha particle and produces the "Emanation" (now Radon) which in turn gives off an alpha particle to produce "Radium A" (now Polonium), and a series of further transmutations by giving off alpha or beta or gamma particles and producing subsequent daughter nuclei, which at the time were simply labelled "Radium B" through "Radium F". Her discoveries and work in collaboration with Rutherford, Thomson, Curie and others helped form the foundation for the entire field of nuclear physics and I hope my portrait can help bring her some of the attention she deserves as an important pioneer of the field.
* Chemists and biographers Marelene Rayner-Canham and Geoff Rayner-Canham point out the Matthew Effect (named by historian of science Robert Merton) where discoveries are often misattributed to a nearby more famous scientist. Consider the famous 'Rutherford Gold Foil Experiment', for instance, which was actually performed by his graduate students Geiger and Marsden, but by that time he had received the Nobel in chemistry "for his investigations into the disintegration of the elements, and the chemistry of radioactive substances." Historian of science Margaret Rossiter notes this Matthew Effect most commonly targets women and proposes the term Matilda Effect for the erasure of women from memory and the history of science.
Brooks could be poster child for the Matilda Effect.
** Famously pompous Thomson also disbelieved geological evidence for the age of the Earth, because thermal physics suggested the Earth might have cooled within a few thousand years (more in line with the Bible)... unless there was some other source of heat. There was: radioactivity. Remember, in fairness, at this time, neither the nucleus not the electron had been discovered. You may recall being taught Thomson's "raisin bun" model of the atom.
*** Unlike Pierre Curie, who threated to refuse the Nobel when he discovered that only he and Becquerel (and not Marie Curie) were to be credited with discovery of radioactivity, Otto Hahn did not insist that Meitner be included in his Nobel win (nor for that matter did he stand up for their assistant Fritz Straßmann). We now know that Meitner was nominated for a Nobel prize 47 times!
It was mathematician Gösta Mittag-Leffler who alerted Pierre. An early ally to women in science, Gösta Mittag-Leffler also helped mathematician Sofia Kovalevski secure a position as a privat-docent at Stockholm University in Sweden in 1884. Kovalevski developed an intimate "romantic friendship" with his sister, actress, novelist, and playwright Duchess Anne-Charlotte Edgren-Leffler, with whom she lived collaborated on works of literature, for the remainder of her too short life.
References
"The Unstable Nucleus and its uses" American Institute of Physics exhibit on Marie Curie and the Science of Radioactivity - Radioactivity, accessed March 28, 2018
Emanations from Thorium and Radium Rutherford Museum at McGill, acessed March 28, 2018
Marelene Rayner-Canham and Geoff Rayner-Canham, "HARRIET BROOKS(1876-1933): CANADA'S FIRST WOMAN PHYSICIST" LA PHYSIQUE AU CANADA, 2005 - forms.cap.ca
Marelene F. Rayner-Canham and Geoffrey W. Rayner-Canham, comment on RUTHERFORD, THE “TRUE DISCOVERER OF RADON”, Bull. Hist. Chem., VOLUME 29, Number 2 (2004)
Elizabeth Shearly, Harriet Brooks, pioneering Canadian nuclear physicist, The Canadian Science Publishing blog, accessed March 28, 2018
John Geddes, Why Harriet Brooks Fits the Bill, Macleans, March 6, 2016
Ingrid Birker, Remembering Harriet Brooks: Canada’s first female nuclear physicist, McGill Reporter, March 8, 2011
"Harriet Brooks (1876-1933): Radioactivity" virtualmuseum.ca, accessed March 28, 2018
Brooks, Harriet (1876–1933) Women in World History: A Biographical Encyclopedia
COPYRIGHT 2002 Gale Research Inc.
Dale DeBakcsy, Wither: The Many Triumphs and Long Fall of Nuclear Physicist Harriet Brooks. (Women in Science 71), August 24, 2016
Harriet Brooks (Mrs. Frank Pitcher), Obituary, Nature 131, 865 (17 June 1933), doi:10.1038/131865a0
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