Alicia Boole Stott, linocut print, 9.25" x 12.5" by Ele Willoughby, 2026
The 9th prompt for #PrinterSolstice2526 is volume, so I thought I would portray a mathematician. Not satisfied with regular old three dimensional volumes, I made a portrait of Anglo-Irish mathematician Alicia Boole Stott (1860-1940), so let's talk about four and more dimensions.
Alicia Boole Stott (1860-1940), the third of five daughters, came to mathematics honestly. Her father George Boole, like her, was an autodidact mathematician, philosopher and logician, who served as the first professor of mathematics at Queen's College, Cork, in Ireland and developed Boolean logic, which would later prove so essential to computer programming. Likewise, her mother Mary Everest Boole was an autodidact mathematician and educator, who was further tutored by George and who edited his book on algebraic language, Laws of Thought. When she was only four years old, her father died, and facing poverty, Mary returned to England with Alicia's sisters, where she found a job as a librarian at Queen's College, London and worked as a mathematics tutor. Mary developed her own novel ideas about fostering imagination in teaching mathematics and science to children. She believed that physical manipulation of objects like sticks and stones, or stitching curves onto cards could help children form an understanding of mathematical concepts. She integrated fables, history, philosophy and literature and a fanciful writing style into teaching mathematics to appeal to children. Her ideas on education were not the only way Mary was unconventional; she organized discussion groups with Queen's College students with John Hinton a promulgator of polygamy, much to the disapproval of the authorities. She was a believer in parapsychology and the occult and was the first woman to join the Society of Psychical Research. She wrote about topics which were controversial at the time, like the occult, eastern philosophy, evolution and animal rights, as well as the pedagogy of mathematics, so most of her books were published long after they were written.
Unlike her sisters, Alicia stayed in Cork with her grandmother and great-uncle, until she was 11, when she rejoined her mother and sisters in London. Alicia had felt repressed and unhappy living in Cork, but the lodgings her mother could afford in London were "poor, dark, dirty and uncomfortable." The five girls had to share a room. Her mother sold George's Royal Society Gold Medal, to buy a harmonium so they could have music at home. Alicia went to the school attached to Queen's College London. Mary brought up her daughters doing things like projecting shapes of things such as hanging pendulums onto paper "to acquaint them with the flow of geometry." Alicia learned mathematics from her mother and the first two books of Euclid. She did not attend university. Mary had to leave her job as librarian and become a secretary for John Hinton. When she was 17, Alicia returned briefly to Cork, where she worked in a children's hospital but soon returned to London. She learned about higher-dimensional spaces from her future brother-in-law, mathematician Charles Howard Hinton (son of John Hinton). Charles had mystical beliefs about the fourth dimension and thought we humans inhabit a 4D space we will eventually perceive. He had crafted 4D models with hundreds of small coloured cubes of wood, each labelled with its own Latin name, which he shared with the Boole sisters. He used his cubes to try and get the sisters to visualize a 4D hypercube, for which he coined the word tesseract. His cubes became a popular, but notoriously difficult approach to grappling with 4D geometry; Alicia was the only one who mastered them, becoming more adept than Hinton himself. Among other books, Hinton went on to write The Fourth Dimension.
There are analogues to 3D shapes in 4D. Imagine the five Platonic solids: the cube, the tetrahedron (a pyramid with a triangular base so it has 4 equilateral triangle sides), the octahedron (like two pyramids glued together at the square base so it has 8 equilateral triangles as faces), the dodecahedron (with 12 pentagonal faces) and the icosahedron (with 20 equilateral triangle faces). These are 3D shapes bound with regular polygons with the same number of edges at each vertex. If you relax the rule that the faces must all be the same, you get the collection of semiregular polyhedra. Each of the Platonic solids, along with the the familiar convex regular polygons (equilateral triangle, square, regular pentagon, regular hexagon and so on) has what is called a 4-polytope, which is an analogue in 4D where faces are replaced with 3D cells of identical Platonic solids. Similarly, there are semiregular polytopes you can define from the semiregular polyhedra.
Alicia discovered that there are exactly 6 regular convex 4-polytopes. Swiss mathematician Ludwig Schläli had beat her to this discovery, in 1850 before she was born, but he had not published his work. He had submitted his manuscript for publication, but it was rejected as it was too lengthy. It was finally published 6 years after he died. He named these shapes polyscheme, but Alicia introduced her term polytope (based on the German term polytop) as she was unaware of Schläli's work (and her term was the one adopted). American mathematician Washington Irving Stringham rediscovered 6 regular convex 4-polytopes and published his results in 1880, but Alicia was unaware of his paper and working in isolation. In 1884, English theologian and schoolmaster Edwin Abbott Abbott published a satirical novella called Flatland: A Romance of Many Dimensions in which lines and 2D polyhedral characters living on a plane encounter a 3D sphere; as it moves through the plane the sphere appears as cross-sections, a sequence of growing and shrinking circles. Analogously, Alicia was able to visualize 4-polytopes as 3D cross-sections, allowing her to unfold a 4D problem into 3D problems. Simply using Euclidean constructions and synthetic methods (the only tools at her disposal, having never learned analytic geometry) she was able to produce 3D central cross-sections of all 6 regular polytypes in 4D, and make coloured drawings and cardboard models of each. Of these 6, 5 are 4D analogues of the Platonic solids (the hypercube or 8-cell, the hyperoctahedron or 16-cell, the hypertetrahedron or 5-cell, the 120-cell and the 600-cell) and 6th, called the 24-cell, has no 3D analogue.
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| From left to right, from top to bottom: Mary Stott, G.I. Taylor, Margaret Taylor, P.H. Schoute, A. Boole Stott [Boole Stott, undated(b)]. (Courtesy of the University of Bristol.) |
She contributed to Hinton's 1888 book A New Era of Thought, about higher-dimensional reasoning, writing about sections of 3D solids and part of the preface. (By the time the book came out, Hinton and his wife Mary Ellen Boole Hinton had gone to Japan, following his conviction for bigamy for marrying a second wife under an assumed name. This surprising fact is perhaps less so when we recall he was the son of the radical proponent of polygamy, John Hinton). In 1889, she began secretarial work near Liverpool, working for lawyer and amateur mathematician H. John Falk, who was editing Hinton's book. In 1890 she met actuary Walter Stott, who joined Alicia and Falk on editing a new edition of Hinton's book. The pair married had two children: Mary in 1891 and Leonard in 1892. According to Coxeter, "for some years she led a life of drudgery, rearing her two children on a very small income." In 1895 Walter told her of Dutch mathematician Pieter Schoute's work on central sections of the regular polytopes and she saw that his drawings matched her 3D models, so she mailed him photographs of her work. Schoute replied, asking to meet and collaborate which they did until he died two decades later. They wrote letters back and forth and some summers Schoute would come to stay with the Stott family in England so they could work together. He eventually convinced her to publish, which she did in two papers published in Amsterdam in 1900 and 1910. In her second paper, she was there first person to enumerate all 45 semi-regular polytopes. They also co-authored papers in 1908 and 1910. In 1907, they presented her models at the annual British Association of the Advancement of Science in Leicester. In 1912 Schoute presented his work on semiregular polytopes to the 5th International Congress of Mathematicians in Cambridge, crediting her with the roots of his proof. She made complete sets of models of 120-cell and 600-cell polytopes and left them with Schoute. When he died in 1913, Alicia took a hiatus from mathematics. The University of Groningen granted her an honorary doctorate in 1914, and exhibited her models. She was invited to the ceremony but not able to attend. When the degree arrived in the mail in a cardboard cylinder, she exclaimed, "This will be a good place to keep sticks of macaroni!"
In 1930, when Alicia was 70, her nephew, physicist Geoffrey Ingram Taylor introduced her to the now famed British-Canadian mathematician Harold Scott MacDonald Coxeter who was 23 and a graduate student at Cambridge at the time. Despite their age difference they two became good friends. Like Taylor, Coxeter called her Aunt Alice. Coxeter wrote, "The strength and simplicity of her character combined with the diversity of her interests made her an inspiring friend." The two met regularly and began working together on topics in 4D geometry. He invited her to one of his supervisor H.F. Baker's celebrated geometry tea parties, where they presented a joint paper and she brought a set of her models, which she then donated to the department of mathematics. They collaborated on the investigation of a special kind of 4D polytope (Gosset's 4D polytope s{3,4,3}) for which she made models of its sections. Alicia made two more important discoveries about constructions for polyhedra related to the golden section. With Coxeter, she presented a joint paper at the University of Cambridge. When Coxeter moved to Toronto in 1936 to take up a professorship at U of T, Alicia gave him an antique stained-glass Archimedean solid shade and wrote to him, "My dear! I don't know how to write to you - words seem so futile besides so great a separation! But indeed one can rejoice, for your sake, that it happened so... While I have been writing my mind has gone back to the lovely world we have visited together, and which you have made so much your own. I wonder where you will get to in it! How I wish I could follow." They managed to continue their collaboration, despite their separation, until her death in 1940. Coxeter when on to work at U of T for 60 years and become regarded as one of the greatest geometers of the 20th century. Much of what we know about Alicia's life is thanks to Coxeter's reminiscing about his dear Aunt Alice.
My portrait contains her 3D unfolding of part of a hypercube, her colour drawings of some of the 3-principle sections of the 600-cell, her expansion of the octahedron - a truncated octahedron, sections of of the 16-cell.
p.s. I have related Alicia's life to some of her family, including mathematician father George Boole, mathematician, educator and activist mother Mary Everest Boole, brother-in-law mathematician (and bigamist) Charles Hinton, nephew physicist Geoffrey Ingram Taylor (who went on to be knighted and win the gold medal of the Royal Society, like his grandfather). But, I recommend reading Moira Chas' article 'The Extraordinary Case of the Boole Family' to also learn about further surprising and fascinating family. Alicia's sister Mary Ellen, first wife of Charles Hinton, was a poet. Charles Hinton also invented a baseball-pitching machine and wrote mathematical romances. Her sister Margaret (mother of Geoffrey Ingram Taylor) was a painter. Her sister Lucy Everest Boole was a Lecturer in chemistry at the London School of Medicine for Women and the first woman elected a Fellow of the Institute of Chemistry. Her sister Ethel was an activist concerned about the plight of the Russian people under Tsarist rule and travelled to Russian where she visited prisons, smuggled propaganda, composed music and wrote wildly successful novels (one of which was made into a film with music by Shostakovich). She married Polish exile and rare book expert Wilfred Voynich, who bought the famed, mysterious, medieval manuscript in an as-of-yet-undeciphered text illustrated with dreamlike images of strange plants and creatures, known as the Voynich manuscript. Alicia's son Leonard was a medical doctor and pioneer in the treatment of tuberculosis who inked a portable x-ray machine, an artificial pneumothorax apparatus and a system of navigation based on spherical geometry. Alicia's nephew Sebastian Hinton invented the jungle gym (inspired by the bamboo structures his father built while in self-imposed exile in Japan to teach his children about 3- and 4-D shapes). Sebastian married Carmelita Chase who founded the progressive Putney School, a boarding school in Vermont (where Coxeter was invited and considered working). Alicia's grandniblings Howard Everest Hinton became a distinguished entomologist, William Hinton a Marxist writer and Joan Hinton a nuclear physicist involved in the Manhattan Project who was so appalled by the consequences of the atomic bombing of Hiroshima she became a pacifist, gave up physics, moved to China and became a Maoist. Alicia's great-grandniblings include award-winning documentarian Carma Hinton and 2018 Turing Award-winning A.I. researcher Geoffrey Everest Hinton.
References
Alicia Boole Stott, Wikipedia, accessed February, 2026.
Boole Stott, Alicia. On Certain Series of Sections of the Regular Four Dimensional Hypersolids. Verhnadelingen Natuurkunde, Eerste Sectie, deel 7, nummer 3 (1900), pp. 1-21.
Chas, Moira. The Extraordinary Case of the Boole Family. Notices of the American Mathematical Society. DOI: https://dx.doi.org/10.1090/noti1996. December, 2019.
O'Connor, J.J. and E.F. Robertson, Alicia Boole Stott, MacTutor Archive, University of St Andrews. July 2014.
Polo-Blanco, Irene. Alicia Boole Stott, a geometer in higher dimension. Historia Mathematica. Volume 35, Issue 2. pp. 123-139. May, 2008.
Polo-Blanco, Irene. Alicia Boole Stott's models of sections of polytypes. Lettera Mathematica. Volume 2, pp. 149-154. September 9, 204.
Riddle, Larry. Alicia Boole Stott. Biographies of Women Mathematicians. Agnes Scott College. February 19, 2025
