Emmy Noether

Emmy Noether
Born Amalie Emmy Noether
(1882-03-23)23 March 1882
Erlangen, Bavaria, Germany
Died 14 April 1935(1935-04-14) (aged 53)
Bryn Mawr, Pennsylvania, US
Nationality German
Fields Mathematics and physics
Institutions
Alma mater University of Erlangen
Doctoral advisor Paul Gordan
Doctoral students
Known for
Notable awards Ackermann–Teubner Memorial Award (1932)

Amalie Emmy Noether (German: [ˈnøːtɐ]; 23 March 1882 – 14 April 1935) was a German mathematician known for her landmark contributions to abstract algebra and theoretical physics.[1]

She was described by Pavel Alexandrov, Albert Einstein, Jean Dieudonné, Hermann Weyl, and Norbert Wiener as the most important woman in the history of mathematics.[2][3] As one of the leading mathematicians of her time, she developed the theories of rings, fields, and algebras. In physics, Noether's theorem explains the connection between symmetry and conservation laws.[4]

Introduction

Noether was born to a Jewish family in the Franconian town of Erlangen; her father was a mathematician, Max Noether. She originally planned to teach French and English after passing the required examinations, but instead studied mathematics at the University of Erlangen, where her father lectured. After completing her dissertation in 1907 under the supervision of Paul Gordan, she worked at the Mathematical Institute of Erlangen without pay for seven years. At the time, women were largely excluded from academic positions. In 1915, she was invited by David Hilbert and Felix Klein to join the mathematics department at the University of Göttingen, a world-renowned center of mathematical research. The philosophical faculty objected, however, and she spent four years lecturing under Hilbert's name. Her habilitation was approved in 1919, allowing her to obtain the rank of Privatdozent.

Noether remained a leading member of the Göttingen mathematics department until 1933; her students were sometimes called the "Noether boys". In 1924, Dutch mathematician B. L. van der Waerden joined her circle and soon became the leading expositor of Noether's ideas: her work was the foundation for the second volume of his influential 1931 textbook, Moderne Algebra. By the time of her plenary address at the 1932 International Congress of Mathematicians in Zürich, her algebraic acumen was recognized around the world. The following year, Germany's Nazi government dismissed Jews from university positions, and Noether moved to the United States to take up a position at Bryn Mawr College in Pennsylvania. In 1935 she underwent surgery for an ovarian cyst and, despite signs of a recovery, died four days later at the age of 53.

Noether's mathematical work has been divided into three "epochs".[5] In the first (1908–19), she made contributions to the theories of algebraic invariants and number fields. Her work on differential invariants in the calculus of variations, Noether's theorem, has been called "one of the most important mathematical theorems ever proved in guiding the development of modern physics".[6] In the second epoch (1920–26), she began work that "changed the face of [abstract] algebra".[7] In her classic paper Idealtheorie in Ringbereichen (Theory of Ideals in Ring Domains, 1921) Noether developed the theory of ideals in commutative rings into a tool with wide-ranging applications. She made elegant use of the ascending chain condition, and objects satisfying it are named Noetherian in her honor. In the third epoch (1927–35), she published works on noncommutative algebras and hypercomplex numbers and united the representation theory of groups with the theory of modules and ideals. In addition to her own publications, Noether was generous with her ideas and is credited with several lines of research published by other mathematicians, even in fields far removed from her main work, such as algebraic topology.

Private life

Noether grew up in the Bavarian city of Erlangen, depicted here in a 1916 postcard
Emmy Noether with her brothers Alfred, Fritz, and Robert, before 1918

Emmy's father, Max Noether, was descended from a family of wholesale traders in Germany. At 14, he had been paralyzed by polio. He regained mobility, but one leg remained affected. Largely self-taught, he was awarded a doctorate from the University of Heidelberg in 1868. After teaching there for seven years, he took a position in the Bavarian city of Erlangen, where he met and married Ida Amalia Kaufmann, the daughter of a prosperous merchant.[8][9][10][11] Max Noether's mathematical contributions were to algebraic geometry mainly, following in the footsteps of Alfred Clebsch. His best known results are the Brill–Noether theorem and the residue, or AF+BG theorem; several other theorems are associated with him; See Max Noether's theorem.

Emmy Noether was born on 23 March 1882, the first of four children.[12] Her first name was "Amalie", after her mother and paternal grandmother, but she began using her middle name at a young age. As a girl, Noether was well liked. She did not stand out academically although she was known for being clever and friendly. She was near-sighted and talked with a minor lisp during childhood. A family friend recounted a story years later about young Noether quickly solving a brain teaser at a children's party, showing logical acumen at that early age.[13] She was taught to cook and clean, as were most girls of the time, and she took piano lessons. She pursued none of these activities with passion, although she loved to dance.[9][14]

She had three younger brothers. The eldest, Alfred, was born in 1883, was awarded a doctorate in chemistry from Erlangen in 1909, but died nine years later. Fritz Noether, born in 1884, is remembered for his academic accomplishments: after studying in Munich he made a reputation for himself in applied mathematics. The youngest, Gustav Robert, was born in 1889. Very little is known about his life; he suffered from chronic illness and died in 1928.[15][16]

Teaching

University of Erlangen

Paul Gordan supervised Noether's doctoral dissertation on invariants of biquadratic forms.

Noether showed early proficiency in French and English. In the spring of 1900 she took the examination for teachers of these languages and received an overall score of sehr gut (very good). Her performance qualified her to teach languages at schools reserved for girls, but she chose instead to continue her studies at the University of Erlangen.

This was an unconventional decision; two years earlier, the Academic Senate of the university had declared that allowing mixed-sex education would "overthrow all academic order".[17] One of only two women students in a university of 986, Noether was only allowed to audit classes rather than participate fully, and required the permission of individual professors whose lectures she wished to attend. Despite these obstacles, on 14 July 1903 she passed the graduation exam at a Realgymnasium in Nuremberg.[18][19][20]

During the 1903–04 winter semester, she studied at the University of Göttingen, attending lectures given by astronomer Karl Schwarzschild and mathematicians Hermann Minkowski, Otto Blumenthal, Felix Klein, and David Hilbert. Soon thereafter, restrictions on women's participation in that university were rescinded.

Noether returned to Erlangen. She officially reentered the university on 24 October 1904, and declared her intention to focus solely on mathematics. Under the supervision of Paul Gordan she wrote her dissertation, Über die Bildung des Formensystems der ternären biquadratischen Form (On Complete Systems of Invariants for Ternary Biquadratic Forms, 1907). Although it had been well received, Noether later described her thesis as "crap".[21][22][23]

For the next seven years (1908–15) she taught at the University of Erlangen's Mathematical Institute without pay, occasionally substituting for her father when he was too ill to lecture. In 1910 and 1911 she published an extension of her thesis work from three variables to n variables.

Noether sometimes used postcards to discuss abstract algebra with her colleague, Ernst Fischer. this card is postmarked 10 April 1915.

Gordan retired in the spring of 1910, but continued to teach occasionally with his successor, Erhard Schmidt, who left shortly afterward for a position in Breslau. Gordan retired from teaching altogether in 1911 with the arrival of Schmidt's successor Ernst Fischer, and died in December 1912.

According to Hermann Weyl, Fischer was an important influence on Noether, in particular by introducing her to the work of David Hilbert. From 1913 to 1916 Noether published several papers extending and applying Hilbert's methods to mathematical objects such as fields of rational functions and the invariants of finite groups. This phase marks the beginning of her engagement with abstract algebra, the field of mathematics to which she would make groundbreaking contributions.

Noether and Fischer shared lively enjoyment of mathematics and would often discuss lectures long after they were over; Noether is known to have sent postcards to Fischer continuing her train of mathematical thoughts.[24][25][26]

University of Göttingen

In the spring of 1915, Noether was invited to return to the University of Göttingen by David Hilbert and Felix Klein. Their effort to recruit her, however, was blocked by the philologists and historians among the philosophical faculty: women, they insisted, should not become privatdozent. One faculty member protested: "What will our soldiers think when they return to the university and find that they are required to learn at the feet of a woman?"[27][28][29][30] Hilbert responded with indignation, stating, "I do not see that the sex of the candidate is an argument against her admission as privatdozent. After all, we are a university, not a bath house."[27][28][29][30]

In 1915 David Hilbert invited Noether to join the Göttingen mathematics department, challenging the views of some of his colleagues that a woman should not be allowed to teach at a university.

Noether left for Göttingen in late April; two weeks later her mother died suddenly in Erlangen. She had previously received medical care for an eye condition, but its nature and impact on her death is unknown. At about the same time Noether's father retired and her brother joined the German Army to serve in World War I. She returned to Erlangen for several weeks, mostly to care for her aging father.[31]

During her first years teaching at Göttingen she did not have an official position and was not paid; her family paid for her room and board and supported her academic work. Her lectures often were advertised under Hilbert's name, and Noether would provide "assistance".

Soon after arriving at Göttingen, however, she demonstrated her capabilities by proving the theorem now known as Noether's theorem, which shows that a conservation law is associated with any differentiable symmetry of a physical system.[29][30] American physicists Leon M. Lederman and Christopher T. Hill argue in their book Symmetry and the Beautiful Universe that Noether's theorem is "certainly one of the most important mathematical theorems ever proved in guiding the development of modern physics, possibly on a par with the Pythagorean theorem".[6]

The mathematics department at the University of Göttingen allowed Noether's habilitation in 1919, four years after she had begun lecturing at the school.

When World War I ended, the German Revolution of 1918–19 brought a significant change in social attitudes, including more rights for women. In 1919 the University of Göttingen allowed Noether to proceed with her habilitation (eligibility for tenure). Her oral examination was held in late May, and she successfully delivered her habilitation lecture in June.

Three years later she received a letter from the Prussian Minister for Science, Art, and Public Education, in which he conferred on her the title of nicht beamteter ausserordentlicher Professor (an untenured professor with limited internal administrative rights and functions[32]). This was an unpaid "extraordinary" professorship, not the higher "ordinary" professorship, which was a civil-service position. Although it recognized the importance of her work, the position still provided no salary. Noether was not paid for her lectures until she was appointed to the special position of Lehrbeauftragte für Algebra a year later.[33][34][35]

Seminal work in abstract algebra

Although Noether's theorem had a profound effect upon physics, among mathematicians she is best remembered for her seminal contributions to abstract algebra. In his Introduction to Noether's Collected Papers, Nathan Jacobson wrote that "The development of abstract algebra, which is one of the most distinctive innovations of twentieth century mathematics, is largely due to her – in published papers, in lectures, and in personal influence on her contemporaries."[36]

Noether's groundbreaking work in algebra began in 1920. In collaboration with W. Schmeidler, she then published a paper about the theory of ideals in which they defined left and right ideals in a ring. The following year she published a landmark paper called Idealtheorie in Ringbereichen, analyzing ascending chain conditions with regard to (mathematical) ideals. Noted algebraist Irving Kaplansky called this work "revolutionary";[37] the publication gave rise to the term "Noetherian ring" and the naming of several other mathematical objects as Noetherian.[37][38][39]

In 1924 a young Dutch mathematician, B. L. van der Waerden, arrived at the University of Göttingen. He immediately began working with Noether, who provided invaluable methods of abstract conceptualization. Van der Waerden later said that her originality was "absolute beyond comparison".[40] In 1931 he published Moderne Algebra, a central text in the field; its second volume borrowed heavily from Noether's work. Although Noether did not seek recognition, he included as a note in the seventh edition "based in part on lectures by E. Artin and E. Noether".[41][42][43] She sometimes allowed her colleagues and students to receive credit for her ideas, helping them develop their careers at the expense of her own.[43][44]

Van der Waerden's visit was part of a convergence of mathematicians from all over the world to Göttingen, which became a major hub of mathematical and physical research. From 1926 to 1930 Russian topologist Pavel Alexandrov lectured at the university, and he and Noether quickly became good friends. He began referring to her as der Noether, using the masculine German article as a term of endearment to show his respect. She tried to arrange for him to obtain a position at Göttingen as a regular professor, but was only able to help him secure a scholarship from the Rockefeller Foundation.[45][46] They met regularly and enjoyed discussions about the intersections of algebra and topology. In his 1935 memorial address, Alexandrov named Emmy Noether "the greatest woman mathematician of all time".[47]

Lecturing and students

Noether c. 1930

In Göttingen, Noether supervised more than a dozen doctoral students; her first was Grete Hermann, who defended her dissertation in February 1925. She later spoke reverently of her "dissertation-mother".[48] Noether also supervised Max Deuring, who distinguished himself as an undergraduate and went on to contribute significantly to the field of arithmetic geometry; Hans Fitting, remembered for Fitting's theorem and the Fitting lemma; and Zeng Jiongzhi (also rendered "Chiungtze C. Tsen" in English), who proved Tsen's theorem. She also worked closely with Wolfgang Krull, who greatly advanced commutative algebra with his Hauptidealsatz and his dimension theory for commutative rings.[49]

In addition to her mathematical insight, Noether was respected for her consideration of others. Although she sometimes acted rudely toward those who disagreed with her, she nevertheless gained a reputation for constant helpfulness and patient guidance of new students. Her loyalty to mathematical precision caused one colleague to name her "a severe critic", but she combined this demand for accuracy with a nurturing attitude.[50] A colleague later described her this way: "Completely unegotistical and free of vanity, she never claimed anything for herself, but promoted the works of her students above all."[51]

Her frugal lifestyle at first was due to being denied pay for her work; however, even after the university began paying her a small salary in 1923, she continued to live a simple and modest life. She was paid more generously later in her life, but saved half of her salary to bequeath to her nephew, Gottfried E. Noether.[52]

Mostly unconcerned about appearance and manners, biographers suggest she focused on her studies. A distinguished algebraist Olga Taussky-Todd described a luncheon, during which Noether, wholly engrossed in a discussion of mathematics, "gesticulated wildly" as she ate and "spilled her food constantly and wiped it off from her dress, completely unperturbed".[53] Appearance-conscious students cringed as she retrieved the handkerchief from her blouse and ignored the increasing disarray of her hair during a lecture. Two female students once approached her during a break in a two-hour class to express their concern, but they were unable to break through the energetic mathematics discussion she was having with other students.[54]

According to van der Waerden's obituary of Emmy Noether, she did not follow a lesson plan for her lectures, which frustrated some students. Instead, she used her lectures as a spontaneous discussion time with her students, to think through and clarify important cutting-edge problems in mathematics. Some of her most important results were developed in these lectures, and the lecture notes of her students formed the basis for several important textbooks, such as those of van der Waerden and Deuring.

Several of her colleagues attended her lectures, and she allowed some of her ideas, such as the crossed product (verschränktes Produkt in German) of associative algebras, to be published by others. Noether was recorded as having given at least five semester-long courses at Göttingen:[55]

These courses often preceded major publications in these areas.

Noether spoke quickly—reflecting the speed of her thoughts, many said—and demanded great concentration from her students. Students who disliked her style often felt alienated.[56][57] Some pupils felt that she relied too much on spontaneous discussions. Her most dedicated students, however, relished the enthusiasm with which she approached mathematics, especially since her lectures often built on earlier work they had done together.

She developed a close circle of colleagues and students who thought along similar lines and tended to exclude those who did not. "Outsiders" who occasionally visited Noether's lectures usually spent only 30 minutes in the room before leaving in frustration or confusion. A regular student said of one such instance: "The enemy has been defeated; he has cleared out."[58]

Noether showed a devotion to her subject and her students that extended beyond the academic day. Once, when the building was closed for a state holiday, she gathered the class on the steps outside, led them through the woods, and lectured at a local coffee house.[59] Later, after she had been dismissed by the Third Reich, she invited students into her home to discuss their plans for the future and mathematical concepts.[60]

Moscow

Noether taught at the Moscow State University during the winter of 1928–29.

In the winter of 1928–29 Noether accepted an invitation to Moscow State University, where she continued working with P. S. Alexandrov. In addition to carrying on with her research, she taught classes in abstract algebra and algebraic geometry. She worked with the topologists, Lev Pontryagin and Nikolai Chebotaryov, who later praised her contributions to the development of Galois theory.[61][62][63]

Although politics was not central to her life, Noether took a keen interest in political matters and, according to Alexandrov, showed considerable support for the Russian Revolution (1917). She was especially happy to see Soviet advancements in the fields of science and mathematics, which she considered indicative of new opportunities made possible by the Bolshevik project. This attitude caused her problems in Germany, culminating in her eviction from a pension lodging building, after student leaders complained of living with "a Marxist-leaning Jewess".[64]

Noether planned to return to Moscow, an effort for which she received support from Alexandrov. After she left Germany in 1933 he tried to help her gain a chair at Moscow State University through the Soviet Education Ministry. Although this effort proved unsuccessful, they corresponded frequently during the 1930s, and in 1935 she made plans for a return to the Soviet Union.[64] Meanwhile, her brother, Fritz accepted a position at the Research Institute for Mathematics and Mechanics in Tomsk, in the Siberian Federal District of Russia, after losing his job in Germany.[65][66]

Recognition

In 1932 Emmy Noether and Emil Artin received the Ackermann–Teubner Memorial Award for their contributions to mathematics.[67] The prize carried a monetary reward of 500 Reichsmarks and was seen as a long-overdue official recognition of her considerable work in the field. Nevertheless, her colleagues expressed frustration at the fact that she was not elected to the Göttingen Gesellschaft der Wissenschaften (academy of sciences) and was never promoted to the position of Ordentlicher Professor[68][69] (full professor).[32]

Noether's colleagues celebrated her fiftieth birthday in 1932, in typical mathematicians' style. Helmut Hasse dedicated an article to her in the Mathematische Annalen, wherein he confirmed her suspicion that some aspects of noncommutative algebra are simpler than those of commutative algebra, by proving a noncommutative reciprocity law.[70] This pleased her immensely. He also sent her a mathematical riddle, the "mμν-riddle of syllables", which she solved immediately; the riddle has been lost.[68][69]

In November of the same year, Noether delivered a plenary address (großer Vortrag) on "Hyper-complex systems in their relations to commutative algebra and to number theory" at the International Congress of Mathematicians in Zürich. The congress was attended by 800 people, including Noether's colleagues Hermann Weyl, Edmund Landau, and Wolfgang Krull. There were 420 official participants and twenty-one plenary addresses presented. Apparently, Noether's prominent speaking position was a recognition of the importance of her contributions to mathematics. The 1932 congress is sometimes described as the high point of her career.[69][71]

Expulsion from Göttingen

When Adolf Hitler became the German Reichskanzler in January 1933, Nazi activity around the country increased dramatically. At the University of Göttingen the German Student Association led the attack on the "un-German spirit" attributed to Jews and was aided by a privatdozent named Werner Weber, a former student of Noether. Antisemitic attitudes created a climate hostile to Jewish professors. One young protester reportedly demanded: "Aryan students want Aryan mathematics and not Jewish mathematics."[72]

One of the first actions of Hitler's administration was the Law for the Restoration of the Professional Civil Service which removed Jews and politically suspect government employees (including university professors) from their jobs unless they had "demonstrated their loyalty to Germany" by serving in World War I. In April 1933 Noether received a notice from the Prussian Ministry for Sciences, Art, and Public Education which read: "On the basis of paragraph 3 of the Civil Service Code of 7 April 1933, I hereby withdraw from you the right to teach at the University of Göttingen."[73][74] Several of Noether's colleagues, including Max Born and Richard Courant, also had their positions revoked.[73][74] Noether accepted the decision calmly, providing support for others during this difficult time. Hermann Weyl later wrote that "Emmy Noether—her courage, her frankness, her unconcern about her own fate, her conciliatory spirit—was in the midst of all the hatred and meanness, despair and sorrow surrounding us, a moral solace."[72] Typically, Noether remained focused on mathematics, gathering students in her apartment to discuss class field theory. When one of her students appeared in the uniform of the Nazi paramilitary organization Sturmabteilung (SA), she showed no sign of agitation and, reportedly, even laughed about it later.[73][74] This, however, was before the bloody events of Krystallnacht in 1935, and their praise from Propaganda Minister Joseph Goebels.

Bryn Mawr

Bryn Mawr College provided a welcoming home for Noether during the last two years of her life.

As dozens of newly unemployed professors began searching for positions outside of Germany, their colleagues in the United States sought to provide assistance and job opportunities for them. Albert Einstein and Hermann Weyl were appointed by the Institute for Advanced Study in Princeton, while others worked to find a sponsor required for legal immigration. Noether was contacted by representatives of two educational institutions, Bryn Mawr College in the United States and Somerville College at the University of Oxford in England. After a series of negotiations with the Rockefeller Foundation, a grant to Bryn Mawr was approved for Noether and she took a position there, starting in late 1933.[75][76]

At Bryn Mawr, Noether met and befriended Anna Wheeler, who had studied at Göttingen just before Noether arrived there. Another source of support at the college was the Bryn Mawr president, Marion Edwards Park, who enthusiastically invited mathematicians in the area to "see Dr. Noether in action!"[77][78] Noether and a small team of students worked quickly through van der Waerden's 1930 book Moderne Algebra I and parts of Erich Hecke's Theorie der algebraischen Zahlen (Theory of algebraic numbers).[79]

In 1934, Noether began lecturing at the Institute for Advanced Study in Princeton upon the invitation of Abraham Flexner and Oswald Veblen. She also worked with and supervised Abraham Albert and Harry Vandiver.[80] However, she remarked about Princeton University that she was not welcome at the "men's university, where nothing female is admitted".[81]

Her time in the United States was pleasant, surrounded as she was by supportive colleagues and absorbed in her favorite subjects.[82][83] In the summer of 1934 she briefly returned to Germany to see Emil Artin and her brother Fritz before he left for Tomsk. Although many of her former colleagues had been forced out of the universities, she was able to use the library as a "foreign scholar".[84][85]

Death

Noether's remains were placed under the walkway surrounding the cloisters of Bryn Mawr's M. Carey Thomas Library.

In April 1935 doctors discovered a tumor in Noether's pelvis. Worried about complications from surgery, they ordered two days of bed rest first. During the operation they discovered an ovarian cyst "the size of a large cantaloupe".[86] Two smaller tumors in her uterus appeared to be benign and were not removed, to avoid prolonging surgery. For three days she appeared to convalesce normally, and she recovered quickly from a circulatory collapse on the fourth. On 14 April she fell unconscious, her temperature soared to 109 °F (42.8 °C), and she died. "[I]t is not easy to say what had occurred in Dr. Noether", one of the physicians wrote. "It is possible that there was some form of unusual and virulent infection, which struck the base of the brain where the heat centers are supposed to be located."[86]

A few days after Noether's death her friends and associates at Bryn Mawr held a small memorial service at College President Park's house. Hermann Weyl and Richard Brauer traveled from Princeton and spoke with Wheeler and Taussky about their departed colleague. In the months that followed, written tributes began to appear around the globe: Albert Einstein[87] joined van der Waerden, Weyl, and Pavel Alexandrov in paying their respects. Her body was cremated and the ashes interred under the walkway around the cloisters of the M. Carey Thomas Library at Bryn Mawr.[88]

Contributions to mathematics and physics

Noether's work in abstract algebra and topology was influential in mathematics, while in physics, Noether's theorem has far-ranging consequences for theoretical physics and dynamic systems. She showed an acute propensity for abstract thought, which allowed her to approach problems of mathematics in fresh and original ways.[89][24] Her friend and colleague Hermann Weyl described her scholarly output in three epochs:

Emmy Noether's scientific production fell into three clearly distinct epochs:

(1) the period of relative dependence, 1907–1919;
(2) the investigations grouped around the general theory of ideals 1920–1926;

(3) the study of the non-commutative algebras, their representations by linear transformations, and their application to the study of commutative number fields and their arithmetics.

Weyl 1935

In the first epoch (1907–19), Noether dealt primarily with differential and algebraic invariants, beginning with her dissertation under Paul Gordan. Her mathematical horizons broadened, and her work became more general and abstract, as she became acquainted with the work of David Hilbert, through close interactions with a successor to Gordan, Ernst Sigismund Fischer. After moving to Göttingen in 1915, she produced her seminal work for physics, the two Noether's theorems.

In the second epoch (1920–26), Noether devoted herself to developing the theory of mathematical rings.[90]

In the third epoch (1927–35), Noether focused on noncommutative algebra, linear transformations, and commutative number fields.[91]

Historical context

In the century from 1832 to Noether's death in 1935, the field of mathematics—specifically algebra—underwent a profound revolution, whose reverberations are still being felt. Mathematicians of previous centuries had worked on practical methods for solving specific types of equations, e.g., cubic, quartic, and quintic equations, as well as on the related problem of constructing regular polygons using compass and straightedge. Beginning with Carl Friedrich Gauss's 1832 proof that prime numbers such as five can be factored in Gaussian integers,[92] Évariste Galois's introduction of permutation groups in 1832 (although, because of his death, his papers were only published in 1846 by Liouville), William Rowan Hamilton's discovery of quaternions in 1843, and Arthur Cayley's more modern definition of groups in 1854, research turned to determining the properties of ever-more-abstract systems defined by ever-more-universal rules. Noether's most important contributions to mathematics were to the development of this new field, abstract algebra.[93]

Abstract algebra and begriffliche Mathematik (conceptual mathematics)

Two of the most basic objects in abstract algebra are groups and rings.

A group consists of a set of elements and a single operation which combines a first and a second element and returns a third. The operation must satisfy certain constraints for it to determine a group: It must be closed (when applied to any pair of elements of the associated set, the generated element must also be a member of that set), it must be associative, there must be an identity element (an element which, when combined with another element using the operation, results in the original element, such as adding zero to a number or multiplying it by one), and for every element there must be an inverse element.

A ring likewise, has a set of elements, but now has two operations. The first operation must make the set a group, and the second operation is associative and distributive with respect to the first operation. It may or may not be commutative; this means that the result of applying the operation to a first and a second element is the same as to the second and first—the order of the elements does not matter. If every non-zero element has a multiplicative inverse (an element x such that ax = xa = 1), the ring is called a division ring. A field is defined as a commutative division ring.

Groups are frequently studied through group representations. In their most general form, these consist of a choice of group, a set, and an action of the group on the set, that is, an operation which takes an element of the group and an element of the set and returns an element of the set. Most often, the set is a vector space, and the group represents symmetries of the vector space. For example, there is a group which represents the rigid rotations of space. This is a type of symmetry of space, because space itself does not change when it is rotated even though the positions of objects in it do. Noether used these sorts of symmetries in her work on invariants in physics.

A powerful way of studying rings is through their modules. A module consists of a choice of ring, another set, usually distinct from the underlying set of the ring and called the underlying set of the module, an operation on pairs of elements of the underlying set of the module, and an operation which takes an element of the ring and an element of the module and returns an element of the module. The underlying set of the module and its operation must form a group. A module is a ring-theoretic version of a group representation: Ignoring the second ring operation and the operation on pairs of module elements determines a group representation. The real utility of modules is that the kinds of modules that exist and their interactions, reveal the structure of the ring in ways that are not apparent from the ring itself. An important special case of this is an algebra. (The word algebra means both a subject within mathematics as well as an object studied in the subject of algebra.) An algebra consists of a choice of two rings and an operation which takes an element from each ring and returns an element of the second ring. This operation makes the second ring into a module over the first. Often the first ring is a field.

Words such as "element" and "combining operation" are very general, and can be applied to many real-world and abstract situations. Any set of things that obeys all the rules for one (or two) operation(s) is, by definition, a group (or ring), and obeys all theorems about groups (or rings). Integer numbers, and the operations of addition and multiplication, are just one example. For example, the elements might be computer data words, where the first combining operation is exclusive or and the second is logical conjunction. Theorems of abstract algebra are powerful because they are general; they govern many systems. It might be imagined that little could be concluded about objects defined with so few properties, but precisely therein lay Noether's gift: to discover the maximum that could be concluded from a given set of properties, or conversely, to identify the minimum set, the essential properties responsible for a particular observation. Unlike most mathematicians, she did not make abstractions by generalizing from known examples; rather, she worked directly with the abstractions. As van der Waerden recalled in his obituary of her,[94]

The maxim by which Emmy Noether was guided throughout her work might be formulated as follows: "Any relationships between numbers, functions, and operations become transparent, generally applicable, and fully productive only after they have been isolated from their particular objects and been formulated as universally valid concepts."

This is the begriffliche Mathematik (purely conceptual mathematics) that was characteristic of Noether. This style of mathematics was consequently adopted by other mathematicians, especially in the (then new) field of abstract algebra.

Integers as an example of a ring

The integers form a commutative ring whose elements are the integers, and the combining operations are addition and multiplication. Any pair of integers can be added or multiplied, always resulting in another integer, and the first operation, addition, is commutative, i.e., for any elements a and b in the ring, a + b = b + a. The second operation, multiplication, also is commutative, but that need not be true for other rings, meaning that a combined with b might be different from b combined with a. Examples of noncommutative rings include matrices and quaternions. The integers do not form a division ring, because the second operation cannot always be inverted; there is no integer a such that 3 × a = 1.

The integers have additional properties which do not generalize to all commutative rings. An important example is the fundamental theorem of arithmetic, which says that every positive integer can be factored uniquely into prime numbers. Unique factorizations do not always exist in other rings, but Noether found a unique factorization theorem, now called the Lasker–Noether theorem, for the ideals of many rings. Much of Noether's work lay in determining what properties do hold for all rings, in devising novel analogs of the old integer theorems, and in determining the minimal set of assumptions required to yield certain properties of rings.

First epoch (1908–19)

Algebraic invariant theory

Table 2 from Noether's dissertation [95] on invariant theory. This table collects 202 of the 331 invariants of ternary biquadratic forms. These forms are graded in two variables x and u. The horizontal direction of the table lists the invariants with increasing grades in x, while the vertical direction lists them with increasing grades in u.

Much of Noether's work in the first epoch of her career was associated with invariant theory, principally algebraic invariant theory. Invariant theory is concerned with expressions that remain constant (invariant) under a group of transformations. As an everyday example, if a rigid yardstick is rotated, the coordinates (x1, y1, z1) and (x2, y2, z2) of its endpoints change, but its length L given by the formula L2 = Δx2 + Δy2 + Δz2 remains the same. Invariant theory was an active area of research in the later nineteenth century, prompted in part by Felix Klein's Erlangen program, according to which different types of geometry should be characterized by their invariants under transformations, e.g., the cross-ratio of projective geometry. The archetypal example of an invariant is the discriminant B2 − 4AC of a binary quadratic form Ax2 + Bxy + Cy2. This is called an invariant because it is unchanged by linear substitutions xax + by, ycx + dy with determinant adbc = 1. These substitutions form the special linear group SL2. (There are no invariants under the general linear group of all invertible linear transformations because these transformations can be multiplication by a scaling factor. To remedy this, classical invariant theory also considered relative invariants, which were forms invariant up to a scale factor.) One can ask for all polynomials in A, B, and C that are unchanged by the action of SL2; these are called the invariants of binary quadratic forms, and turn out to be the polynomials in the discriminant. More generally, one can ask for the invariants of homogeneous polynomials A0xry0 + ... + Arx0yr of higher degree, which will be certain polynomials in the coefficients A0, ..., Ar, and more generally still, one can ask the similar question for homogeneous polynomials in more than two variables.

One of the main goals of invariant theory was to solve the "finite basis problem". The sum or product of any two invariants is invariant, and the finite basis problem asked whether it was possible to get all the invariants by starting with a finite list of invariants, called generators, and then, adding or multiplying the generators together. For example, the discriminant gives a finite basis (with one element) for the invariants of binary quadratic forms. Noether's advisor, Paul Gordan, was known as the "king of invariant theory", and his chief contribution to mathematics was his 1870 solution of the finite basis problem for invariants of homogeneous polynomials in two variables.[96][97] He proved this by giving a constructive method for finding all of the invariants and their generators, but was not able to carry out this constructive approach for invariants in three or more variables. In 1890, David Hilbert proved a similar statement for the invariants of homogeneous polynomials in any number of variables.[98][99] Furthermore, his method worked, not only for the special linear group, but also for some of its subgroups such as the special orthogonal group.[100] His first proof caused some controversy because it did not give a method for constructing the generators, although in later work he made his method constructive. For her thesis, Noether extended Gordan's computational proof to homogeneous polynomials in three variables. Noether's constructive approach made it possible to study the relationships among the invariants. Later, after she had turned to more abstract methods, Noether called her thesis Mist (crap) and Formelngestrüpp (a jungle of equations).

Galois theory

Galois theory concerns transformations of number fields that permute the roots of an equation. Consider a polynomial equation of a variable x of degree n, in which the coefficients are drawn from some ground field, which might be, for example, the field of real numbers, rational numbers, or the integers modulo 7. There may or may not be choices of x, which make this polynomial evaluate to zero. Such choices, if they exist, are called roots. If the polynomial is x2 + 1 and the field is the real numbers, then the polynomial has no roots, because any choice of x makes the polynomial greater than or equal to one. If the field is extended, however, then the polynomial may gain roots, and if it is extended enough, then it always has a number of roots equal to its degree. Continuing the previous example, if the field is enlarged to the complex numbers, then the polynomial gains two roots, i and −i, where i is the imaginary unit, that is, i 2 = −1. More generally, the extension field in which a polynomial can be factored into its roots is known as the splitting field of the polynomial.

The Galois group of a polynomial is the set of all ways of transforming the splitting field, while preserving the ground field and the roots of the polynomial. (In mathematical jargon, these transformations are called automorphisms.) The Galois group of x2 + 1 consists of two elements: The identity transformation, which sends every complex number to itself, and complex conjugation, which sends i to −i. Since the Galois group does not change the ground field, it leaves the coefficients of the polynomial unchanged, so it must leave the set of all roots unchanged. Each root can move to another root, however, so transformation determines a permutation of the n roots among themselves. The significance of the Galois group derives from the fundamental theorem of Galois theory, which proves that the fields lying between the ground field and the splitting field are in one-to-one correspondence with the subgroups of the Galois group.

In 1918, Noether published a seminal paper on the inverse Galois problem.[101] Instead of determining the Galois group of transformations of a given field and its extension, Noether asked whether, given a field and a group, it always is possible to find an extension of the field that has the given group as its Galois group. She reduced this to "Noether's problem", which asks whether the fixed field of a subgroup G of the permutation group Sn acting on the field k(x1, ... , xn) always is a pure transcendental extension of the field k. (She first mentioned this problem in a 1913 paper,[102] where she attributed the problem to her colleague Fischer.) She showed this was true for n = 2, 3, or 4. In 1969, R. G. Swan found a counter-example to Noether's problem, with n = 47 and G a cyclic group of order 47[103] (although this group can be realized as a Galois group over the rationals in other ways). The inverse Galois problem remains unsolved.[104]

Physics

Noether was brought to Göttingen in 1915 by David Hilbert and Felix Klein, who wanted her expertise in invariant theory to help them in understanding general relativity, a geometrical theory of gravitation developed mainly by Albert Einstein. Hilbert had observed that the conservation of energy seemed to be violated in general relativity, because gravitational energy could itself gravitate. Noether provided the resolution of this paradox, and a fundamental tool of modern theoretical physics, with Noether's first theorem, which she proved in 1915, but did not publish until 1918.[105] She not only solved the problem for general relativity, but also determined the conserved quantities for every system of physical laws that possesses some continuous symmetry.

Upon receiving her work, Einstein wrote to Hilbert: "Yesterday I received from Miss Noether a very interesting paper on invariants. I'm impressed that such things can be understood in such a general way. The old guard at Göttingen should take some lessons from Miss Noether! She seems to know her stuff."[106]

For illustration, if a physical system behaves the same, regardless of how it is oriented in space, the physical laws that govern it are rotationally symmetric; from this symmetry, Noether's theorem shows the angular momentum of the system must be conserved.[107] The physical system itself need not be symmetric; a jagged asteroid tumbling in space conserves angular momentum despite its asymmetry. Rather, the symmetry of the physical laws governing the system is responsible for the conservation law. As another example, if a physical experiment has the same outcome at any place and at any time, then its laws are symmetric under continuous translations in space and time; by Noether's theorem, these symmetries account for the conservation laws of linear momentum and energy within this system, respectively.

Noether's theorem has become a fundamental tool of modern theoretical physics, both because of the insight it gives into conservation laws, and also, as a practical calculation tool.[4] Her theorem allows researchers to determine the conserved quantities from the observed symmetries of a physical system. Conversely, it facilitates the description of a physical system based on classes of hypothetical physical laws. For illustration, suppose that a new physical phenomenon is discovered. Noether's theorem provides a test for theoretical models of the phenomenon: if the theory has a continuous symmetry, then Noether's theorem guarantees that the theory has a conserved quantity, and for the theory to be correct, this conservation must be observable in experiments.

Second epoch (1920–26)

Although the results of Noether's first epoch were impressive and useful, her fame as a mathematician rests more on the groundbreaking work she did in her second and third epochs, as noted by Hermann Weyl and B. L. van der Waerden in their obituaries of her.

In these epochs, she was not merely applying ideas and methods of earlier mathematicians; rather, she was crafting new systems of mathematical definitions that would be used by future mathematicians. In particular, she developed a completely new theory of ideals in rings, generalizing earlier work of Richard Dedekind. She is also renowned for developing ascending chain conditions, a simple finiteness condition that yielded powerful results in her hands. Such conditions and the theory of ideals enabled Noether to generalize many older results and to treat old problems from a new perspective, such as elimination theory and the algebraic varieties that had been studied by her father.

Ascending and descending chain conditions

In this epoch, Noether became famous for her deft use of ascending (Teilerkettensatz) or descending (Vielfachenkettensatz) chain conditions. A sequence of non-empty subsets A1, A2, A3, etc. of a set S is usually said to be ascending, if each is a subset of the next

Conversely, a sequence of subsets of S is called descending if each contains the next subset:

A chain becomes constant after a finite number of steps if there is an n such that for all m  n. A collection of subsets of a given set satisfies the ascending chain condition if any ascending sequence becomes constant after a finite number of steps. It satisfies the descending chain condition if any descending sequence becomes constant after a finite number of steps.

Ascending and descending chain conditions are general, meaning that they can be applied to many types of mathematical objects—and, on the surface, they might not seem very powerful. Noether showed how to exploit such conditions, however, to maximum advantage: for example, how to use them to show that every set of sub-objects has a maximal/minimal element or that a complex object can be generated by a smaller number of elements. These conclusions often are crucial steps in a proof.

Many types of objects in abstract algebra can satisfy chain conditions, and usually if they satisfy an ascending chain condition, they are called Noetherian in her honor. By definition, a Noetherian ring satisfies an ascending chain condition on its left and right ideals, whereas a Noetherian group is defined as a group in which every strictly ascending chain of subgroups is finite. A Noetherian module is a module in which every strictly ascending chain of submodules becomes constant after a finite number of steps. A Noetherian space is a topological space in which every strictly ascending chain of open subspaces becomes constant after a finite number of steps; this definition makes the spectrum of a Noetherian ring a Noetherian topological space.

The chain condition often is "inherited" by sub-objects. For example, all subspaces of a Noetherian space, are Noetherian themselves; all subgroups and quotient groups of a Noetherian group are likewise, Noetherian; and, mutatis mutandis, the same holds for submodules and quotient modules of a Noetherian module. All quotient rings of a Noetherian ring are Noetherian, but that does not necessarily hold for its subrings. The chain condition also may be inherited by combinations or extensions of a Noetherian object. For example, finite direct sums of Noetherian rings are Noetherian, as is the ring of formal power series over a Noetherian ring.

Another application of such chain conditions is in Noetherian induction—also known as well-founded induction—which is a generalization of mathematical induction. It frequently is used to reduce general statements about collections of objects to statements about specific objects in that collection. Suppose that S is a partially ordered set. One way of proving a statement about the objects of S is to assume the existence of a counterexample and deduce a contradiction, thereby proving the contrapositive of the original statement. The basic premise of Noetherian induction is that every non-empty subset of S contains a minimal element. In particular, the set of all counterexamples contains a minimal element, the minimal counterexample. In order to prove the original statement, therefore, it suffices to prove something seemingly much weaker: For any counterexample, there is a smaller counterexample.

Commutative rings, ideals, and modules

Noether's paper, Idealtheorie in Ringbereichen (Theory of Ideals in Ring Domains, 1921),[108] is the foundation of general commutative ring theory, and gives one of the first general definitions of a commutative ring.[109] Before her paper, most results in commutative algebra were restricted to special examples of commutative rings, such as polynomial rings over fields or rings of algebraic integers. Noether proved that in a ring which satisfies the ascending chain condition on ideals, every ideal is finitely generated. In 1943, French mathematician Claude Chevalley coined the term, Noetherian ring, to describe this property.[109] A major result in Noether's 1921 paper is the Lasker–Noether theorem, which extends Lasker's theorem on the primary decomposition of ideals of polynomial rings to all Noetherian rings. The Lasker–Noether theorem can be viewed as a generalization of the fundamental theorem of arithmetic which states that any positive integer can be expressed as a product of prime numbers, and that this decomposition is unique.

Noether's work Abstrakter Aufbau der Idealtheorie in algebraischen Zahl- und Funktionenkörpern (Abstract Structure of the Theory of Ideals in Algebraic Number and Function Fields, 1927)[110] characterized the rings in which the ideals have unique factorization into prime ideals as the Dedekind domains: integral domains that are Noetherian, 0 or 1-dimensional, and integrally closed in their quotient fields. This paper also contains what now are called the isomorphism theorems, which describe some fundamental natural isomorphisms, and some other basic results on Noetherian and Artinian modules.

Elimination theory

In 1923–24, Noether applied her ideal theory to elimination theory—in a formulation that she attributed to her student, Kurt Hentzelt—showing that fundamental theorems about the factorization of polynomials could be carried over directly.[111][112][113] Traditionally, elimination theory is concerned with eliminating one or more variables from a system of polynomial equations, usually by the method of resultants. For illustration, a system of equations often can be written in the form of a matrix M (missing the variable x) times a vector v (having only different powers of x) equaling the zero vector, M•v = 0. Hence, the determinant of the matrix M must be zero, providing a new equation in which the variable x has been eliminated.

Invariant theory of finite groups

Techniques such as Hilbert's original non-constructive solution to the finite basis problem could not be used to get quantitative information about the invariants of a group action, and furthermore, they did not apply to all group actions. In her 1915 paper,[114] Noether found a solution to the finite basis problem for a finite group of transformations G acting on a finite-dimensional vector space over a field of characteristic zero. Her solution shows that the ring of invariants is generated by homogeneous invariants whose degree is less than, or equal to, the order of the finite group; this is called Noether's bound. Her paper gave two proofs of Noether's bound, both of which also work when the characteristic of the field is coprime to |G|!, the factorial of the order |G| of the group G. The degrees of generators need not satisfy Noether's bound when the characteristic of the field divides the |G|,[115] but Noether was not able to determine whether this bound was correct when the characteristic of the field divides |G|! but not |G|. For many years, determining the truth or falsehood of this bound for this particular case was an open problem, called "Noether's gap". It was finally solved independently by Fleischmann in 2000 and Fogarty in 2001, who both showed that the bound remains true.[116][117]

In her 1926 paper,[118] Noether extended Hilbert's theorem to representations of a finite group over any field; the new case that did not follow from Hilbert's work is when the characteristic of the field divides the order of the group. Noether's result was later extended by William Haboush to all reductive groups by his proof of the Mumford conjecture.[119] In this paper Noether also introduced the Noether normalization lemma, showing that a finitely generated domain A over a field k has a set x1, ... , xn of algebraically independent elements such that A is integral over k[x1, ... , xn].

Contributions to topology

A continuous deformation (homotopy) of a coffee cup into a doughnut (torus) and back

As noted by Pavel Alexandrov and Hermann Weyl in their obituaries, Noether's contributions to topology illustrate her generosity with ideas and how her insights could transform entire fields of mathematics. In topology, mathematicians study the properties of objects that remain invariant even under deformation, properties such as their connectedness. A common joke is that a topologist cannot distinguish a donut from a coffee mug, since they can be continuously deformed into one another.

Noether is credited with fundamental ideas that led to the development of algebraic topology from the earlier combinatorial topology, specifically, the idea of homology groups.[120] According to the account of Alexandrov, Noether attended lectures given by Heinz Hopf and by him in the summers of 1926 and 1927, where "she continually made observations which were often deep and subtle"[121] and he continues that,

When... she first became acquainted with a systematic construction of combinatorial topology, she immediately observed that it would be worthwhile to study directly the groups of algebraic complexes and cycles of a given polyhedron and the subgroup of the cycle group consisting of cycles homologous to zero; instead of the usual definition of Betti numbers, she suggested immediately defining the Betti group as the complementary (quotient) group of the group of all cycles by the subgroup of cycles homologous to zero. This observation now seems self-evident. But in those years (1925–28) this was a completely new point of view.[122]

Noether's suggestion that topology be studied algebraically was adopted immediately by Hopf, Alexandrov, and others,[122] and it became a frequent topic of discussion among the mathematicians of Göttingen.[123] Noether observed that her idea of a Betti group makes the Euler–Poincaré formula simpler to understand, and Hopf's own work on this subject[124] "bears the imprint of these remarks of Emmy Noether".[125] Noether mentions her own topology ideas only as an aside in a 1926 publication,[126] where she cites it as an application of group theory.[127]

This algebraic approach to topology was also developed independently in Austria. In a 1926–27 course given in Vienna, Leopold Vietoris defined a homology group, which was developed by Walther Mayer, into an axiomatic definition in 1928.[128]

Helmut Hasse worked with Noether and others to found the theory of central simple algebras.

Third epoch (1927–35)

Hypercomplex numbers and representation theory

Much work on hypercomplex numbers and group representations was carried out in the nineteenth and early twentieth centuries, but remained disparate. Noether united these results and gave the first general representation theory of groups and algebras.[129] Briefly, Noether subsumed the structure theory of associative algebras and the representation theory of groups into a single arithmetic theory of modules and ideals in rings satisfying ascending chain conditions. This single work by Noether was of fundamental importance for the development of modern algebra.[130]

Noncommutative algebra

Noether also was responsible for a number of other advancements in the field of algebra. With Emil Artin, Richard Brauer, and Helmut Hasse, she founded the theory of central simple algebras.[131]

A seminal paper by Noether, Helmut Hasse, and Richard Brauer pertains to division algebras,[132] which are algebraic systems in which division is possible. They proved two important theorems: a local-global theorem stating that if a finite-dimensional central division algebra over a number field splits locally everywhere then it splits globally (so is trivial), and from this, deduced their Hauptsatz ("main theorem"): every finite dimensional central division algebra over an algebraic number field F splits over a cyclic cyclotomic extension. These theorems allow one to classify all finite-dimensional central division algebras over a given number field. A subsequent paper by Noether showed, as a special case of a more general theorem, that all maximal subfields of a division algebra D are splitting fields.[133] This paper also contains the Skolem–Noether theorem which states that any two embeddings of an extension of a field k into a finite-dimensional central simple algebra over k, are conjugate. The Brauer–Noether theorem[134] gives a characterization of the splitting fields of a central division algebra over a field.

Assessment, recognition, and memorials

The Emmy Noether Campus at the University of Siegen is home to its mathematics and physics departments.

Noether's work continues to be relevant for the development of theoretical physics and mathematics and she is consistently ranked as one of the greatest mathematicians of the twentieth century. In his obituary, fellow algebraist BL van der Waerden says that her mathematical originality was "absolute beyond comparison",[135] and Hermann Weyl said that Noether "changed the face of algebra by her work".[7] During her lifetime and even until today, Noether has been characterized as the greatest woman mathematician in recorded history by mathematicians[136][3][137] such as Pavel Alexandrov,[138] Hermann Weyl,[139] and Jean Dieudonné.[140]

In a letter to The New York Times, Albert Einstein wrote:[2]

In the judgment of the most competent living mathematicians, Fräulein Noether was the most significant creative mathematical genius thus far produced since the higher education of women began. In the realm of algebra, in which the most gifted mathematicians have been busy for centuries, she discovered methods which have proved of enormous importance in the development of the present-day younger generation of mathematicians.

On 2 January 1935, a few months before her death, mathematician Norbert Wiener wrote that [141]

Miss Noether is... the greatest woman mathematician who has ever lived; and the greatest woman scientist of any sort now living, and a scholar at least on the plane of Madame Curie.

At an exhibition at the 1964 World's Fair devoted to Modern Mathematicians, Noether was the only woman represented among the notable mathematicians of the modern world.[142]

Noether has been honored in several memorials,

In fiction, Emmy Nutter, the physics professor in "The God Patent" by Ransom Stephens, is based on Emmy Noether.[150]

Farther from home,

List of doctoral students

Date Student name Dissertation title and English translation University Publication
1911.12.16 Falckenberg, Hans Verzweigungen von Lösungen nichtlinearer Differentialgleichungen
Ramifications of Solutions of Nonlinear Differential Equations§
Erlangen Leipzig 1912
1916.03.04 Seidelmann, Fritz Die Gesamtheit der kubischen und biquadratischen Gleichungen mit Affekt bei beliebigem Rationalitätsbereich
Complete Set of Cubic and Biquadratic Equations with Affect in an Arbitrary Rationality Domain§
Erlangen Erlangen 1916
1925.02.25 Hermann, Grete Die Frage der endlich vielen Schritte in der Theorie der Polynomideale unter Benutzung nachgelassener Sätze von Kurt Hentzelt
The Question of the Finite Number of Steps in the Theory of Ideals of Polynomials using Theorems of the Late Kurt Hentzelt§
Göttingen Berlin 1926
1926.07.14 Grell, Heinrich Beziehungen zwischen den Idealen verschiedener Ringe
Relationships between the Ideals of Various Rings§
Göttingen Berlin 1927
1927 Doräte, Wilhelm Über einem verallgemeinerten Gruppenbegriff
On a Generalized Conceptions of Groups§
Göttingen Berlin 1927
died before defense Hölzer, Rudolf Zur Theorie der primären Ringe
On the Theory of Primary Rings§
Göttingen Berlin 1927
1929.06.12 Weber, Werner Idealtheoretische Deutung der Darstellbarkeit beliebiger natürlicher Zahlen durch quadratische Formen
Ideal-theoretic Interpretation of the Representability of Arbitrary Natural Numbers by Quadratic Forms§
Göttingen Berlin 1930
1929.06.26 Levitski, Jakob Über vollständig reduzible Ringe und Unterringe
On Completely Reducible Rings and Subrings§
Göttingen Berlin 1931
1930.06.18 Deuring, Max Zur arithmetischen Theorie der algebraischen Funktionen
On the Arithmetic Theory of Algebraic Functions§
Göttingen Berlin 1932
1931.07.29 Fitting, Hans Zur Theorie der Automorphismenringe Abelscher Gruppen und ihr Analogon bei nichtkommutativen Gruppen
On the Theory of Automorphism-Rings of Abelian Groups and Their Analogs in Noncommutative Groups§
Göttingen Berlin 1933
1933.07.27 Witt, Ernst Riemann-Rochscher Satz und Zeta-Funktion im Hyperkomplexen
The Riemann-Roch Theorem and Zeta Function in Hypercomplex Numbers§
Göttingen Berlin 1934
1933.12.06 Tsen, Chiungtze Algebren über Funktionenkörpern
Algebras over Function Fields§
Göttingen Göttingen 1934
1934 Schilling, Otto Über gewisse Beziehungen zwischen der Arithmetik hyperkomplexer Zahlsysteme und algebraischer Zahlkörper
On Certain Relationships between the Arithmetic of Hypercomplex Number Systems and Algebraic Number Fields§
Marburg Braunschweig 1935
1935 Stauffer, Ruth The construction of a normal basis in a separable extension field Bryn Mawr Baltimore 1936
1935 Vorbeck, Werner Nichtgaloissche Zerfällungskörper einfacher Systeme
Non-Galois Splitting Fields of Simple Systems§
Göttingen
1936 Wichmann, Wolfgang Anwendungen der p-adischen Theorie im Nichtkommutativen
Applications of the p-adic Theory in Noncommutative Algebras§
Göttingen Monatshefte für Mathematik und Physik (1936) 44, 203–24.

Eponymous mathematical topics

Notes

  1. Emmy is the Rufname, the second of two official given names, intended for daily use. Cf. for example the résumé submitted by Noether to Erlangen University in 1907 (Erlangen University archive, Promotionsakt Emmy Noether (1907/08, NR. 2988); reproduced in: Emmy Noether, Gesammelte Abhandlungen – Collected Papers, ed. N. Jacobson 1983; online facsimile at physikerinnen.de/noetherlebenslauf.html). Sometimes Emmy is mistakenly reported as a short form for Amalie, or misreported as "Emily". e.g. Smolin, Lee, "Special Relativity – Why Can't You Go Faster Than Light?", Edge, Emily Noether, a great German mathematician
  2. 1 2 Einstein, Albert (1 May 1935), "Professor Einstein Writes in Appreciation of a Fellow-Mathematician", New York Times (published 5 May 1935), retrieved 13 April 2008. Also online at the MacTutor History of Mathematics archive.
  3. 1 2 Alexandrov 1981, p. 100.
  4. 1 2 Ne'eman, Yuval. "The Impact of Emmy Noether's Theorems on XXIst Century Physics", Teicher 1999, pp. 83–101.
  5. Weyl 1935
  6. 1 2 Lederman & Hill 2004, p. 73.
  7. 1 2 Dick 1981, p. 128
  8. Kimberling 1981, pp. 3–5.
  9. 1 2 Osen 1974, p. 142.
  10. Lederman & Hill 2004, pp. 70–71.
  11. Dick 1981, pp. 7–9.
  12. Chang, Sooyoung (2011). Academic Genealogy of Mathematicians (illustrated ed.). World Scientific. p. 21. ISBN 978-981-4282-29-1. Extract of page 21
  13. Dick 1981, pp. 9–10.
  14. Dick 1981, pp. 10–11.
  15. Dick 1981, pp. 25, 45.
  16. Kimberling, p. 5.
  17. Kimberling 1981, p. 10.
  18. Dick 1981, pp. 11–12.
  19. Kimberling 1981, pp. 8–10.
  20. Lederman & Hill 2004, p. 71.
  21. Kimberling 1981, pp. 10–11.
  22. Dick 1981, pp. 13–17.
  23. Lederman & Hill 2004, p. 71 write that she completed her doctorate at Göttingen, but this appears to be an error.
  24. 1 2 Kimberling 1981, pp. 11–12.
  25. Dick 1981, pp. 18–24.
  26. Osen 1974, p. 143.
  27. 1 2 Kimberling 1981, p. 14.
  28. 1 2 Dick 1981, p. 32.
  29. 1 2 3 Osen 1974, pp. 144–45.
  30. 1 2 3 Lederman & Hill 2004, p. 72.
  31. Dick 1981, pp. 24–26.
  32. 1 2 Dick 1981, p. 188.
  33. Kimberling 1981, pp. 14–18.
  34. Osen 1974, p. 145.
  35. Dick 1981, pp. 33–34.
  36. Noether 1983.
  37. 1 2 Kimberling 1981, p. 18.
  38. Dick 1981, pp. 44–45.
  39. Osen 1974, pp. 145–46.
  40. van der Waerden 1935, p. 100.
  41. Dick 1981, pp. 57–58.
  42. Kimberling 1981, p. 19.
  43. 1 2 Lederman & Hill 2004, p. 74.
  44. Osen 1974, p. 148.
  45. Kimberling 1981, pp. 24–25.
  46. Dick 1981, pp. 61–63.
  47. Alexandrov 1981, pp. 100, 107.
  48. Dick 1981, p. 51.
  49. Dick 1981, pp. 53–57.
  50. Dick 1981, pp. 37–49.
  51. van der Waerden 1935, p. 98.
  52. Dick 1981, pp. 46–48.
  53. Taussky 1981, p. 80.
  54. Dick 1981, pp. 40–41.
  55. Scharlau, W. "Emmy Noether's Contributions to the Theory of Algebras" in Teicher 1999, p. 49.
  56. Mac Lane 1981, p. 77.
  57. Dick 1981, p. 37.
  58. Dick 1981, pp. 38–41.
  59. Mac Lane 1981, p. 71.
  60. Dick 1981, p. 76.
  61. Dick 1981, pp. 63–64.
  62. Kimberling 1981, p. 26.
  63. Alexandrov 1981, pp. 108–10.
  64. 1 2 Alexandrov 1981, pp. 106–9.
  65. Osen 1974, p. 150.
  66. Dick 1981, pp. 82–83.
  67. "Emmy Amalie Noether" (biography). UK: St And. Retrieved 4 September 2008.
  68. 1 2 Dick 1981, pp. 72–73.
  69. 1 2 3 Kimberling 1981, pp. 26–27.
  70. Hasse 1933, p. 731.
  71. Dick 1981, pp. 74–75.
  72. 1 2 Kimberling 1981, p. 29.
  73. 1 2 3 Dick 1981, pp. 75–76.
  74. 1 2 3 Kimberling 1981, pp. 28–29.
  75. Dick 1981, pp. 78–79.
  76. Kimberling 1981, pp. 30–31.
  77. Kimberling 1981, pp. 32–33.
  78. Dick 1981, p. 80.
  79. Dick 1981, pp. 80–81.
  80. Dick 1981, pp. 81–82.
  81. Dick 1981, p. 81.
  82. Osen 1974, p. 151.
  83. Dick 1981, p. 83.
  84. Dick 1981, p. 82.
  85. Kimberling 1981, p. 34.
  86. 1 2 Kimberling 1981, pp. 37–38.
  87. Einstein, Albert (4 May 1935). "THE LATE EMMY NOETHER.; Professor Einstein Writes in Appreciation of a Fellow-Mathematician.". The New York Times. Retrieved 24 March 2015.
  88. Kimberling 1981, p. 39.
  89. Osen 1974, pp. 148–49.
  90. Gilmer 1981, p. 131.
  91. Kimberling 1981, pp. 10–23.
  92. C. F. Gauss, Theoria residuorum biquadraticorum. Commentatio secunda., Comm. Soc. Reg. Sci. Göttingen 7 (1832) 1-34; reprinted in Werke, Georg Olms Verlag, Hildesheim, 1973, pp. 93–148.
  93. G.E. Noether 1987, p. 168.
  94. Dick 1981, p. 101.
  95. Noether 1908.
  96. Noether 1914, p. 11.
  97. Gordan 1870.
  98. Weyl 1944, pp. 618–21.
  99. Hilbert 1890, p. 531.
  100. Hilbert 1890, p. 532.
  101. Noether 1918.
  102. Noether 1913.
  103. Swan 1969, p. 148.
  104. Malle & Matzat 1999.
  105. Noether 1918b
  106. Kimberling 1981, p. 13.
  107. Lederman & Hill 2004, pp. 97–116.
  108. Noether 1921.
  109. 1 2 Gilmer 1981, p. 133.
  110. Noether 1927.
  111. Noether 1923.
  112. Noether 1923b.
  113. Noether 1924.
  114. Noether 1915.
  115. Fleischmann 2000, p. 24.
  116. Fleischmann 2000, p. 25.
  117. Fogarty 2001, p. 5.
  118. Noether 1926.
  119. Haboush 1975.
  120. Hilton 1988, p. 284.
  121. Dick 1981, p. 173.
  122. 1 2 Dick 1981, p. 174.
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  124. Hopf 1928.
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  126. Noether 1926b.
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  131. Lam 1981, pp. 152–53.
  132. Brauer, Hasse & Noether 1932.
  133. Noether 1933.
  134. Brauer & Noether 1927.
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  136. Osen 1974, p. 152.
  137. James 2002, p. 321.
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References

Selected works by Emmy Noether (in German)

Additional sources

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