Throughout her career, she achieved milestones that cemented her reputation as one of the greatest mathematicians of her time, such as the "magic wand theorem", which tied together fields such as dynamical systems, geometry, and topology.[12] After completing her PhD at Harvard University in 2004, Mirzakhani became a research fellow at the Clay Mathematics Institute and later joined Princeton University as a professor. In 2009, she moved to Stanford University, where she continued her pioneering research until her death. Her work focused on the intricate and complex dynamics of geometric structures, with particular emphasis on moduli spaces and Riemann surfaces. Her approaches and profound insights significantly advanced the field, earning her widespread acclaim and recognition, leading her to win the Fields Medal, the highest honor in mathematics.[8]
Born and raised in Tehran, Mirzakhani's passion for mathematics began at a young age. She earned her undergraduate degree from Sharif University of Technology and went on to pursue her PhD at Harvard University under the mentorship of Fields Medalist Curtis T. McMullen. Her academic journey led her to positions at Princeton University and Stanford University, where she became a full professor in 2009. Despite her death at the age of 40 due to breast cancer,[13] her legacy endures through numerous accolades in her honor, including the Maryam Mirzakhani New Frontiers Prize and the 12 May Initiative, both dedicated to promoting women in mathematics.
Early life and education
Mirzakhani was born on 12 May 1977[14][3] in Tehran, Iran.[15] As a child, she attended Tehran Farzanegan School, part of the National Organization for Development of Exceptional Talents (NODET). In her junior and senior years of high school, she won the gold medal for mathematics in the Iranian National Olympiad, thus allowing her to bypass the national college entrance exam.[16] In 1994, Mirzakhani became the first Iranian woman to win a gold medal at the International Mathematical Olympiad in Hong Kong, scoring 41 out of 42 points.[17] The following year, in Toronto, she became the first Iranian to achieve the full score and to win two gold medals in the International Mathematical Olympiad.[18][19] Later in her life, she collaborated with friend, colleague, and Olympiad silver medalist, Roya Beheshti Zavareh (Persian: رؤیا بهشتی زواره), on their book Elementary Number Theory, Challenging Problems, (in Persian) which was published in 1999.[16] Mirzakhani and Zavareh together were the first women to compete in the Iranian National Mathematical Olympiad and won gold and silver medals in 1995, respectively.
On 17 March 1998, after attending a conference consisting of gifted individuals and former Olympiad competitors, Mirzakhani and Zavareh, along with other attendees, boarded a bus in Ahvaz en route to Tehran. The bus fell off a cliff, killing seven of the passengers, all Sharif University students in what is remebered as a national tragedy in Iran. Mirzakhani and Zavareh were two of the few survivors.[20]
In 1999, she obtained a Bachelor of Science in mathematics from the Sharif University of Technology. During her time there, she developed a simpler proof of a theorem of Schur.[21][22] She then went to the United States for graduate work, earning a PhD in 2004 from Harvard University, where she worked under the supervision of the Fields Medalist, Curtis T. McMullen.[23] At Harvard, she is said to have been "distinguished by determination and relentless questioning". She used to take her class notes in her native language Persian.[24][25]
Mirzakhani made several contributions to the theory of moduli spaces of Riemann surfaces. Mirzakhani's early work solved the problem of counting simple closed geodesics on hyperbolic Riemann surfaces by finding a relationship to volume calculations on moduli space. Geodesics are the natural generalization of the idea of a "straight line" to "curved spaces". Slightly more formally, a curve is a geodesic if no slight deformation can make it shorter. Closed geodesics are geodesics which are also closed curves—that is, they are curves that close up into loops. A closed geodesic is simple if it does not cross itself.[29]
A previous result, known as the "prime number theorem for geodesics", established that the number of closed geodesics of length less than grows exponentially with – it is asymptotic to . However, the analogous counting problem for simple closed geodesics remained open, despite being "the key object to unlocking the structure and geometry of the whole surface," according to University of Chicago topologist Benson Farb.[30] Mirzakhani's 2004 PhD thesis solved this problem, showing that the number of simple closed geodesics of length less than is polynomial in . Explicitly, it is asymptotic to , where is the genus (roughly, the number of "holes") and is a constant depending on the hyperbolic structure. This result can be seen as a generalization of the theorem of the three geodesics for spherical surfaces.[31][32]
Mirzakhani solved this counting problem by relating it to the problem of computing volumes in moduli space—a space whose points correspond to different complex structures on a surface genus . In her thesis, Mirzakhani found a volume formula for the moduli space of bordered Riemann surfaces of genus with geodesic boundary components. From this formula followed the counting for simple closed geodesics mentioned above, as well as a number of other results. This led her to obtain a new proof for the formula discovered by Edward Witten and Maxim Kontsevich on the intersection numbers of tautological classes on moduli space.[6][33]
Her subsequent work focused on Teichmüller dynamics of moduli space. In particular, she was able to prove the long-standing conjecture that William Thurston's earthquake flow on Teichmüller space is ergodic.[34] One can construct a simple earthquake map by cutting a surface along a finite number of disjoint simple closed geodesics, sliding the edges of each of these cut past each other by some amount, and closing the surface back up. One can imagine the surface being cut by strike-slip faults. An earthquake is a sort of limit of simple earthquakes, where one has an infinite number of geodesics, and instead of attaching a positive real number to each geodesic, one puts a measure on them.
In 2014, with Alex Eskin and with input from Amir Mohammadi, Mirzakhani proved that complex geodesics and their closures in moduli space are surprisingly regular, rather than irregular or fractal.[35][36] The closures of complex geodesics are algebraic objects defined in terms of polynomials and therefore, they have certain rigidity properties, which is analogous to a celebrated result that Marina Ratner arrived at during the 1990s.[36] The International Mathematical Union said in its press release that "It is astounding to find that the rigidity in homogeneous spaces has an echo in the inhomogeneous world of moduli space."[36]
Awarding of Fields Medal
Mirzakhani was awarded the Fields Medal in 2014 for "her outstanding contributions to the dynamics and geometry of Riemann surfaces and their moduli spaces".[37] The award was made in Seoul at the International Congress of Mathematicians on 13 August.[38] At the time of the award, Jordan Ellenberg explained her research to a popular audience:
[Her] work expertly blends dynamics with geometry. Among other things, she studies billiards. But now, in a move very characteristic of modern mathematics, it gets kind of meta: She considers not just one billiard table, but the universe of all possible billiard tables. And the kind of dynamics she studies doesn't directly concern the motion of the billiards on the table, but instead a transformation of the billiard table itself, which is changing its shape in a rule-governed way; if you like, the table itself moves like a strange planet around the universe of all possible tables ... This isn't the kind of thing you do to win at pool, but it's the kind of thing you do to win a Fields Medal. And it's what you need to do in order to expose the dynamics at the heart of geometry; for there's no question that they're there.[39]
In 2014, President Hassan Rouhani of Iran congratulated her for winning the award.[40]
Personal life
In 2008, Mirzakhani married Jan Vondrák, a Czech theoretical computer scientist and applied mathematician who currently is a professor at Stanford University.[41][42] They had a daughter.[43] Mirzakhani lived in Palo Alto, California.[44]
Mirzakhani described herself as a "slow" mathematician, saying that "you have to spend some energy and effort to see the beauty of math." To solve problems, Mirzakhani would draw doodles on sheets of paper and write mathematical formulas around the drawings. Her daughter described her mother's work as "painting".[24][45]
She declared:
I don't have any particular recipe [for developing new proofs] ... It is like being lost in a jungle and trying to use all the knowledge that you can gather to come up with some new tricks, and with some luck, you might find a way out.[24]
Iranian president Hassan Rouhani and other officials offered their condolences and praised Mirzakhani's scientific achievements. Rouhani said in his message that "the unprecedented brilliance of this creative scientist and modest human being, who made Iran's name resonate in the world's scientific forums, was a turning point in showing the great will of Iranian women and young people on the path towards reaching the peaks of glory and in various international arenas."[24]
Upon her death, several Iranian newspapers, along with President Hassan Rouhani, broke taboo and published photographs of Mirzakhani with her hair uncovered. Although most newspapers used photographs with a dark background, digital manipulation, and even paintings to "hide" her hair,[10][48] this gesture was widely noted in the western press and on social media.[49][50] Mirzakhani's death has also renewed debates within Iran regarding matrilineal citizenship for children of mixed-nationality parentage; Fars News Agency reported that, subsequent to Mirzakhani's death, 60 Iranian MPs urged the speeding up of an amendment to a law that would allow children of Iranian mothers married to foreigners to be given Iranian nationality, in order to make it easier for Mirzakhani's daughter to visit Iran.[10][49]
Numerous obituaries and tributes were published in the days following Mirzakhani's death.[51][52] As a result of advocacy carried out by the Women's Committee within the Iranian Mathematical Society (Persian: کمیته بانوان انجمن ریاضی ایران), the International Council for Science agreed to declare Mirzakhani's birthday, 12 May, as International Women in Mathematics Day in respect of her memory.[53][54]
Various establishments have also been named after Mirzakhani to honor her life and achievements. In 2017, Farzanegan High School – the high school Mirzakhani formerly attended – named their amphitheater and library after her. Additionally, Sharif University of Technology, the institute wherein Mirzakhani obtained her bachelor's, has since named their main library in the College of Mathematics after her. Further, the House of Mathematics in Isfahan, in collaboration with the mayor, named a conference hall in the city after her.[55]
In 2014, students at the University of Oxford founded the Mirzakhani Society, a society for women and non-binary students studying mathematics at the University of Oxford. Mirzakhani met the society in September 2015, when she visited Oxford.[56]
In 2016, Mirzakhani was made a member of the National Academy of Sciences (of the United States), making her the first Iranian woman to be officially accepted as a member of the academy.[57]
In February 2020, on International Day of Women and Girls in STEM, Mirzakhani was honored by UN Women as one of seven female scientists dead or alive who have shaped the world.[61]
In 2020, George Csicsery featured her in the documentary film Secrets of the Surface: The Mathematical Vision of Maryam Mirzakhani.[62][63]
In 2022, following a £2.48m donation from XTX Markets, the University of Oxford launched the Maryam Mirzakhani Scholarships, which provide support for female mathematicians pursuing doctoral studies at the university.[65]
Awards and honors
Gold medal. International Mathematical Olympiad (Hong Kong 1994)[18]
Gold medal. International Mathematical Olympiad (Canada 1995)[18]
^"Maryam Mirzakhani". The Mathematics Genealogy Project. Genealogy.math.ndsu.nodak.edu. Archived from the original on 9 May 2016. Retrieved 21 October 2017.
^Ahmed Khan, Sameen (December 2017). "Fields Medallist Maryam Mirzakhani"(PDF). Vol. 7, no. 1. Asia Pacific Mathematics Newsletters. p. 37. Retrieved 2 April 2022. She noted the responses of her professors in her native language, Persian.
^Kehoe, Elaine (April 2013). "Notices of the AMS"(PDF). Archived(PDF) from the original on 6 January 2018. Retrieved 25 September 2018.
^"2014 Fields Medals"(PDF). Notices of the AMS. 61 (9): 1079–1081. October 2014. Archived(PDF) from the original on 5 June 2018. Retrieved 25 September 2018.
^National Academy of Sciences. "Maryam Mirzakhani". National Academy of Sciences. Archived from the original on 26 November 2018. Retrieved 3 December 2018.