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Lise Meitner

Lise Meitner (7 November 1878 – 27 October 1968) was an Austrian-born who advanced the understanding of and nuclear processes through empirical experimentation and theoretical insight. Working in from 1907, she collaborated with to isolate the element in 1917 and contributed to early studies of and interactions. In 1938, as a Jew facing Nazi , she escaped for , where she continued research at the Nobel Institute. Her most enduring achievement came in December 1938, when she interpreted experimental results from Hahn and showing production from bombardment as evidence of , calculating the energy release and coining the term "fission" with her nephew Otto Frisch. Meitner's theoretical framework, published in 1939, demonstrated that the uranium nucleus deformed like a liquid drop under impact, splitting into lighter elements with the emission of s and gamma rays, releasing approximately 200 million volts per event. This explanation enabled the concept central to both nuclear reactors and atomic bombs, though she expressed ethical reservations about weapon applications. Hahn received the 1944 for the discovery, crediting Meitner in private correspondence but not sufficiently in his publication amid wartime constraints and Nazi-era publication restrictions on Jewish collaborators; subsequent archival analysis of deliberations revealed her exclusion stemmed from procedural delays, postwar politics, and evaluator assessments prioritizing experimental over theoretical contributions, despite her multiple nominations. Postwar, Meitner worked at the University of until retirement in 1955, then resided in , receiving accolades including the Medal and , though she declined Israel's offer of a position due to health. Her legacy endures in nuclear and , with element 109 named in 1997, recognizing her foundational role in revealing atomic energy's causal mechanisms.

Early Life and Education

Family Background and Childhood

Lise Meitner was born on November 7, 1878, in , , into an assimilated Jewish upper-middle-class family residing at 27 Kaiser Josefstraße in the district. Her father, Philipp Meitner, was a and chess master whose family originated from . Her mother, Hedwig Skovran, came from a family that had emigrated from to and was a talented amateur musician who fostered a culturally rich home environment. As the third of eight children, Meitner grew up in a household emphasizing intellectual pursuits, though the family did not actively practice Judaism. Philipp Meitner supported advanced education for his daughters despite Austrian legal restrictions barring women from university matriculation until 1897, arranging private tutoring for Lise starting at age 14 to prepare her for scientific studies. The family's progressive stance contrasted with prevailing societal norms, enabling Meitner's early exposure to mathematics and physics amid a Viennese cultural milieu that valued arts and sciences.

Academic Training and Barriers Faced

Meitner completed her in by 1897, but Austrian restrictions limited girls' formal schooling to age 14, necessitating private tutoring from that point to prepare for . Her family, intellectually supportive despite cultural norms confining women to domestic roles, enabled this unconventional path amid broader gender barriers that had only recently eased with the 1897 legalization of women's attendance at the University of Vienna's Philosophical Faculty. In 1901, aged 23, Meitner enrolled at the to pursue physics and mathematics, studying under experimentalists Anton Lampa and Stefan Meyer, as well as theorist . Her doctoral thesis, titled "Thermal Conduction in Inhomogeneous Bodies," addressed phenomena, earning her the in physics on February 1, 1906—the second such degree awarded to a woman by the university. These achievements occurred against systemic obstacles for women in Austrian , including segregated facilities, exclusion from certain labs, and scant postdoctoral prospects, which compelled Meitner to seek opportunities abroad despite her strong performance. Post-graduation, offered no suitable research positions for women physicists, underscoring how norms prioritized male access to institutional resources and mentorship networks essential for scientific advancement.

Early Scientific Career

Initial Research in Vienna

Meitner conducted her doctoral research at the under the supervision of Franz Exner, professor of experimental physics, and his assistant Hans Benndorf. Her thesis, Wärmeleitung in inhomogenen Körpern (Heat Conduction in Inhomogeneous Bodies), examined thermal conductivity in solids featuring non-uniform structures, applying experimental methods to test theoretical predictions for such materials. Submitted on 20 November 1905 and approved shortly thereafter, the work was published as an offprint in the Sitzungsberichte der Mathematisch-Naturwissenschaftlichen Classe der kaiserlichen Akademie der Wissenschaften in February 1906. Earlier, during her studies, Meitner produced her first independent publication: a paper titled "Some Conclusions Derived from the Fresnel Reflection Formula," which appeared in the proceedings of the Academy of Sciences and explored optical reflection principles. This optical work reflected her foundational training in physics but marked a preliminary step toward independent inquiry. Upon earning her on 1 1906—the second woman to do so in physics at the university—Meitner encountered limited prospects for advanced research in , particularly for women. Following Ludwig Boltzmann's suicide in September 1906, Stefan Meyer, Boltzmann's former assistant and director of the newly established Institute for Research, introduced her to , a nascent field involving the study of and emissions from elements like . Though Meitner initially viewed it as peripheral to her interests in theoretical and , Meyer's demonstrations of radium's properties—such as alpha and —sparked her curiosity about transformations. This exposure in represented Meitner's pivot from classical to phenomena, though no formal publications or extended experiments in originated there. Lacking paid positions or resources for independent radioactive assays at the time, she departed for in 1907 to access better facilities and collaborate with leading physicists like , building directly on the foundational interest ignited by Meyer.

Collaboration Beginnings in Berlin

In late 1907, following her doctoral degree from the , Lise Meitner relocated to to advance her studies in under at the Friedrich Wilhelm University. Prussian universities at the time prohibited women from formal enrollment or laboratory access, compelling Meitner to audit Planck's lectures informally from the hallway or through private arrangements facilitated by Planck himself. During this period, she encountered chemist , who had returned to in and was conducting research on radioactive elements in Emil Fischer's laboratory at the university. Their shared interest in prompted the initiation of a collaborative effort by the end of 1907, marking the start of a partnership that would endure for over three decades. Meitner, working unpaid as an unofficial guest researcher, joined Hahn in experiments aimed at isolating and characterizing radioactive substances, including efforts to separate from . This early cooperation yielded nine joint publications: three in 1908 and six in 1909, primarily addressing topics such as radioactive and phenomena in radioactive solutions. These works demonstrated Meitner's physics expertise complementing Hahn's chemical techniques, establishing a productive interdisciplinary dynamic despite institutional barriers to women's participation in science. The collaboration's foundation in Berlin's academic environment, bolstered by Planck's theoretical guidance, positioned them for subsequent breakthroughs in nuclear research.

Major Pre-Fission Discoveries

Discovery of Protactinium

Lise Meitner and succeeded in isolating the long-lived protactinium-231 (^{231}Pa) in late 1917, confirming its existence as the radioactive precursor to in the decay series. This built on prior work, including the 1913 identification of the short-lived ^{234}Pa (brevium) by Kasimir Fajans and Oswald Helmuth Göhring, which decayed too rapidly for sustained study. Hahn's expertise in complemented Meitner's knowledge of radioactive emissions, allowing them to target and purify the more stable parent from pitchblende residues after laboratory constraints eased their access to materials. The isolation process relied on repeated chemical separations from extracts. They treated pitchblende with to yield an insoluble silica fraction associated with and , then iteratively precipitated and redissolved these to concentrate the target substance, yielding trace amounts sufficient for spectroscopic and decay analysis. Meitner conducted measurements to verify ^{231}Pa's of approximately 32,000 years, distinguishing it from fleeting decay products and confirming its 91 through genetic links to known series. Their results were published in early , naming the element protactinium (from Greek protos, "before," and ) to denote its sequential position. This discovery occurred independently of British chemists and John Cranston, who reported similar findings from Scottish pitchblende around the same period, though Hahn and Meitner achieved the first unambiguous isolation of macroscopic traces. The work advanced understanding of decay chains and heavy element chemistry, positioning as a rare, highly radioactive metal with no isotopes, later formalized in the periodic table. Meitner's contributions earned her the 1917 Leibniz Medal from the , recognizing her pivotal role in interpreting the physical properties.

Studies on Beta Radiation

Meitner began her investigations into beta radiation shortly after joining Otto Hahn in Berlin in 1907, focusing on the properties of beta rays emitted from radioactive sources in the thorium and radium decay series. Collaborating with Hahn, she employed ionization chambers and absorption techniques to measure beta particle penetration in materials like aluminum, confirming that beta rays consist of electrons with velocities approaching the speed of light and exhibiting a continuous energy distribution rather than discrete lines. These early experiments, conducted around 1911, demonstrated exponential absorption with foil thickness, consistent with charged particle interactions, and highlighted the puzzling continuity of the energy spectrum, which extended from near-zero up to a sharp endpoint but averaged below the expected total decay energy. By the early 1920s, Meitner advanced her research using magnetic spectrometers to resolve energies with higher precision, targeting beta emitters such as UX1 (234Th), Th B (212Pb), Ra D (210Pb), and Th X (224Ra). Her 1922 detailed spectra from 234Th decay, revealing a continuous up to approximately 0.15 MeV alongside electron groups at specific energies, such as 0.063 MeV and 0.092 MeV, which did not align with pure beta emission. These findings challenged prevailing views of as a simple two-body process and contributed to the beta-ray energy , where the spectrum's continuity appeared to violate conservation, prompting debates over whether energy was or if additional particles were involved. Meitner argued that observed line intensities and positions indicated nuclear processes beyond standard beta emission, rejecting hypotheses like multiple sequential decays without . In interpreting the discrete lines, Meitner proposed in that they arose from non-radiative electromagnetic transitions within the , where excitation energy from gamma-like de-excitations directly ejects orbital electrons from the atom—a process akin to the but originating nuclearly. She extended this in 1923, analyzing Th B spectra to show that these "conversion electrons" carried energies matching expected gamma quanta minus atomic binding energies, thus conserving momentum and energy without photon emission. This mechanism explained the lines' sharpness and relative intensities, distinguishing them from the broad continuum, and laid groundwork for the formal theory of electrons, later termed Meitner-Ellis electrons after corroborative work by Charles Ellis. Her measurements, achieving resolutions down to 1% in energy, underscored the composite nature of decay chains, with transitions interspersed by isomeric states resolved via these lines. Meitner's beta studies persisted through 1926, influencing quantum mechanical models of and , though the continuous spectrum's energy deficit remained unresolved until Wolfgang Pauli's 1930 . Her empirical emphasis on spectroscopic data over theoretical speculation prioritized verifiable momenta, providing foundational datasets for later detection efforts and affirming 's role in sequences.

Institutional Roles and World War I

Positions at Kaiser Wilhelm Institute

In October 1912, Lise Meitner relocated her research to the newly established Institute for Chemistry in Berlin-Dahlem, alongside , beginning as an unpaid scientific guest. This honorary position reflected the institutional barriers for women in academia at the time, though it allowed her to continue collaborative studies on . By 1913, Meitner secured a paid role, becoming the first woman appointed as a Scientific Member of the , marking a formal advancement within the institute. Her work persisted amid disruptions; research halted in 1914 but resumed in 1916, focusing on radioactive substances with Hahn. In , Meitner was tasked with organizing and heading the institute's new radiophysics department, establishing her as director of the physics section dedicated to radioactivity investigations. This leadership role, which she held from approximately to 1938, paralleled Hahn's oversight of the section, fostering their long-term partnership. The dual structure enabled specialized yet complementary research, contributing to discoveries like that year.

Wartime Contributions and Interruptions

During , which began in July 1914, was drafted into the German Army's service, interrupting their collaborative research at the Kaiser Wilhelm Institute for Chemistry in . Meitner, as an Austrian citizen, volunteered for medical service with the , training as an technician to assist in diagnosing wounded soldiers using radiographic equipment. This role leveraged her expertise in radiation physics, contributing to frontline medical efforts by enabling precise imaging of fractures and internal injuries amid resource shortages and high casualties. She served from mid-1914 until her discharge in 1916, after which she returned to the institute to resume experimental work. The war imposed broader interruptions on scientific activities at the Kaiser Wilhelm Institute, including material scarcities, reduced staffing, and redirection of resources toward military applications, though Meitner focused on non-weapons rather than offensive technologies. Despite these constraints, she maintained productivity; in 1917, she received the Leibniz Medal from the for her radioactivity research and was granted her own physics section within the institute's chemistry department, solidifying her institutional role. Hahn, on intermittent leave from military duties, rejoined her efforts, allowing limited progress on transuranic element investigations even as correspondence and travel were hampered by wartime censorship and blockades. Meitner's wartime medical service highlighted the intersection of physics and practical exigencies, but it temporarily sidelined her pursuits, delaying publications until post-1916 reunions. By war's end in November 1918, these interruptions had not derailed her career trajectory, as evidenced by her expanded responsibilities and ongoing Hahn collaboration, though the conflict underscored vulnerabilities in international scientific exchange.

Interwar Research and Transmutation Experiments

Nuclear Transmutation Investigations

In the mid-1930s, Lise Meitner and initiated systematic studies on the of nuclei via bombardment, building on Enrico Fermi's 1934 reports of suggesting transuranic elements. Their experiments at the Kaiser Wilhelm Institute for Chemistry involved irradiating salts with s from radon-beryllium sources, followed by chemical to isolate potential new isotopes. Hahn conducted the radiochemical separations, grouping products by solubility and precipitation characteristics akin to known elements, while Meitner measured half-lives and spectra to characterize nuclear transitions. Initial results, published in 1936, identified short-lived activities such as those with half-lives of about 13 hours and 2.5 minutes, which they tentatively assigned to followed by beta s producing isotopes of elements 93 and beyond . These findings supported the hypothesis of stepwise to heavier nuclei, though Meitner emphasized caution, noting discrepancies in decay chains compared to natural patterns. By 1937, further irradiations with revealed additional activities, including longer-lived ones, but chemical tests indicated some products behaved like lighter elements such as or rather than expected actinides. Meitner interpreted these through models, predicting sequences but questioning the stability of purported transuranics due to insufficient Coulomb barrier penetration for . The persistence of lighter chemical fractions challenged the transuranic narrative, prompting rigorous re-examination of separation purity and effects. These investigations highlighted the limitations of contemporaneous nuclear theory in explaining heavy-element reactions, as empirical data increasingly pointed to anomalous mass yields incompatible with simple capture processes. Meitner's physics-driven scrutiny ensured that interpretations remained tied to observable energies and half-lives, avoiding unsubstantiated extensions of the periodic table.

Collaboration with Otto Hahn

Lise Meitner and 's scientific partnership, initiated in late 1907, persisted through the at the Institute for Chemistry in , where Hahn directed and Meitner led radiophysics following a 1919 division of their joint laboratory. Their complementary skills—Hahn's in chemical separation of radioactive substances and Meitner's in physical analysis of nuclear processes—enabled joint investigations into and emerging nuclear reactions. In the 1930s, prompted by James Chadwick's 1932 and Enrico Fermi's demonstrations of neutron-induced artificial radioactivity, Meitner and Hahn, assisted by from 1929, turned to bombarding and with s. They conducted extensive experiments involving neutron irradiation, chemical purification, and measurement of decay products, publishing over a dozen papers on observed radioactivities. Initially, these were interpreted as evidence for transuranic elements with atomic numbers exceeding uranium's 92, including reports of element 93 in 1937. Hahn performed the radiochemical extractions and identifications, while Meitner contributed theoretical frameworks and beta-spectra analyses to interpret the results, such as the of uranium-239. These efforts built on their earlier work, including the basis for and through artificial activation of . Despite mounting Nazi-era restrictions on Meitner due to her Jewish heritage, their collaboration continued until her emigration, with Hahn relying on her physical insights for experimental design and data evaluation.

Nazi Persecution and Emigration

Professional Demotion and Isolation

In April 1933, shortly after the Nazi regime's enactment of the Law for the Restoration of the Professional Civil Service on April 7, Meitner was dismissed from her lecturing position at the University of owing to her Jewish ancestry, alongside other female Jewish academics. Her Austrian citizenship, however, initially shielded her from similar immediate action at the Kaiser Wilhelm for Chemistry, where she continued as head of the physics section, benefiting from the institute's semi-autonomous status and her established scientific prominence. Despite retaining formal access to her , Meitner faced escalating in the ensuing years; Nazi policies barred the assignment of new research assistants or doctoral students to Jewish scientists, confining her collaborations largely to , who conducted experiments in a makeshift basement setup to evade scrutiny. Publications bearing her name risked or rejection, and social intensified as colleagues distanced themselves to safeguard their own positions, rendering her a "prominent exception" amid the broader of Jewish researchers from institutions. The of September 1935, which racially defined Jews regardless of religious conversion—Meitner having become Protestant in 1908—heightened her vulnerability, though enforcement at was deferred due to her foreign status. This changed abruptly with the on March 12, 1938, annexing and stripping her exemption; reclassified as a German Jew, she was compelled to submit her resignation from the Kaiser Wilhelm Institute under regime pressure, effective prior to her departure. By mid-1938, emigration restrictions for valuable scientists like her compounded the isolation, leaving her professionally stranded until clandestine assistance enabled her flight.

Escape to Sweden in 1938

In the spring of 1938, following the annexation of on March 12, Lise Meitner faced intensified pressure from Nazi authorities, who sought to exploit her expertise in nuclear research while subjecting her to professional isolation as a Jew under the . Her colleague , aware of surveillance and emigration bans imposed on prominent Jewish scientists, repeatedly urged her to leave Berlin during visits in early July, providing her with a small sum of money and a diamond ring to sell for funds. Despite her reluctance to abandon ongoing experiments at the Institute for Chemistry, Meitner relented after consultations with international contacts, including , who facilitated discreet arrangements. On , 1938, Meitner departed under the pretext of a short , traveling by train to the Dutch border with the assistance of Hahn and Dutch physicist Dirk Coster, who met her at to evade border checks. Crossing into the on July 14 without a valid exit visa—relying on forged papers and Coster's connections—she spent a brief period in hiding before proceeding northward. From the , Meitner sailed to , arriving in around July 20, where she had secured a temporary research position at the Laboratory through Bohr's intervention, though resources were scarce and her status precarious. Meitner's flight severed her direct ties to German laboratories, forcing her to continue correspondence with Hahn via intermediaries to interpret fission-related remotely, while authorities granted her a provisional appointment at the University of amid the 1938 refugee influx. This exile, executed in secrecy to avoid retaliation against remaining Jewish colleagues, marked the end of her 30-year tenure in and her integration into a neutral but resource-limited scientific environment.

Nuclear Fission Breakthrough

Experimental Results from

In late , following Lise Meitner's departure from , Otto and Fritz at the Institute for Chemistry in persisted with experiments bombarding with slow , initially seeking to produce transuranic elements beyond 's of 92. Their setup involved neutron sources such as radon-beryllium mixtures to generate , irradiating salts dissolved in solutions, followed by chemical separation techniques to identify reaction products. By mid-December 1938, specifically around December 17, the pair detected radioactive substances in the irradiated that exhibited chemical properties aligning not with expected heavier radium-like elements but with (atomic number 56) and neighboring rare earths such as and . Carrier tests confirmed the presence of , as the co-precipitated with barium salts and resisted separation from them, yielding half-lives consistent with known barium isotopes like 6.6-hour ^{139}Ba. This result defied conventional expectations, as the products had roughly half the mass of or , suggesting an unprecedented splitting of the rather than simple capture or alpha emission. On December 19, 1938, Hahn communicated these baffling findings to Meitner via letter, noting the apparent formation of medium-weight elements and seeking her physical interpretation, as chemical analysis alone could not account for the process. The duo's inability to reconcile the results with known physics led them to describe it as a "bursting" or new reaction type in their report, emphasizing the energy considerations that ruled out radium formation under slow neutron bombardment. These observations were formally documented in a paper submitted on December 22, 1938, and published on January 6, 1939, in Die Naturwissenschaften, titled "Über den Nachweis und das Verhalten der bei der Bestrahlung des Urans mittels Neutronen entstehenden Erdalkalimetalle," highlighting the detection of alkaline earth metals like barium from uranium irradiation.

Theoretical Explanation by Meitner and Frisch

In late December 1938, Lise Meitner, then residing in after fleeing , received a letter from her long-time collaborator detailing the unexpected chemical detection of isotopes following bombardment of . This result, which Hahn and had cautiously interpreted as possible rather than a full nuclear rupture, prompted Meitner to consult with her nephew, the physicist , during their Christmas holiday meeting in , . Over a walk in the snowy woods, Meitner and Frisch applied the liquid drop model of the —originally developed by in the 1920s and refined by —to reinterpret the experimental data. They hypothesized that the by the induced a highly , causing the to behave like a charged liquid drop under tension. The additional positive charge from during deformation would elongate the until could no longer counter the repulsion, leading to asymmetric into two lighter fragments—such as and —along with the release of 2-3 neutrons and substantial from the defect. Meitner performed back-of-the-envelope calculations using Einstein's mass-energy equivalence (E=mc²), estimating the energy yield at approximately 200 million electron volts (MeV) per event, far exceeding typical alpha or energies and aligning with the observed production. This quantitative match validated their model, as the fragments' rapid separation would convert roughly 0.1% of the 's into , consistent with the liquid drop's predicted deformation and rupture dynamics. Frisch, drawing an analogy to biological cell division, proposed the term "fission" for this nuclear process, emphasizing its binary splitting mechanism. Their theoretical framework, outlined in a manuscript submitted in mid-January 1939, predicted chain reactions if emitted neutrons triggered further fissions, a possibility with profound implications for energy release but not yet linked to weaponry in their initial analysis. The explanation appeared as "Disintegration of Uranium by Neutrons: a New Type of Nuclear Reaction" in Nature on February 11, 1939, providing the first coherent physical interpretation of the phenomenon and bridging experimental chemistry with nuclear theory. Frisch subsequently verified the energy release experimentally at the Bohr Institute in Copenhagen, measuring ionization consistent with ~200 MeV, corroborating the theory.

World War II and Ethical Stance

Refusal to Participate in Bomb Development

In 1943, amid escalating Allied efforts to develop atomic weapons, Lise Meitner received an invitation from the to join the at , where she would collaborate with her nephew and British scientists on harnessing for military purposes. Meitner, who had foreseen the explosive potential of fission shortly after its 1938 discovery, declined the offer outright, declaring, "I will have nothing to do with a !" Her refusal stemmed from a deep-seated and ethical opposition to weaponizing scientific breakthroughs, viewing such applications as a profound misuse of knowledge that could lead to unprecedented destruction. Remaining in Sweden at Manne Siegbahn's Nobel for Physics, Meitner focused her wartime research on fundamental processes rather than bomb-related , adhering to her that should serve rather than enable mass killing. This stance isolated her from the intensive, secretive bomb programs but aligned with her lifelong aversion to , which had already prompted her to prioritize emigration over continued work in . British intelligence reports noted her non-involvement, confirming she provided no assistance to or Allied weaponization efforts despite her unparalleled expertise in theory. Meitner's decision underscored a rare moral consistency among nuclear pioneers; unlike many contemporaries who rationalized participation as a defensive necessity against Nazi threats, she prioritized universal ethical constraints over national security imperatives, later expressing horror at the 1945 bombing as a perversion of her theoretical insights. Her epitaph, chosen from the —"Praise the Lord for He is good; His love endures forever"—reflected this enduring commitment to non-violence, even as her work indirectly facilitated the bomb's realization through public dissemination of principles.

Correspondence and Post-War Reflections

Meitner resumed correspondence with Hahn after World War II, amid lingering strains from her 1938 emigration and the circumstances surrounding the nuclear fission discovery. In exchanges during the late 1940s, she conveyed dismay at Hahn's postwar reticence to fully credit her pivotal theoretical contributions—particularly the liquid-drop model explanation of barium formation—and his avoidance of explicit condemnation of Nazi-era atrocities, including the persecution of Jewish scientists. These letters highlighted her view that Hahn's continued work under the Nazi regime, without public protest, compromised ethical integrity in science, even as she acknowledged their long collaboration's scientific value. The 1944 Nobel Prize award to Hahn alone, announced in November 1945, intensified these tensions; Meitner drafted but ultimately did not send a letter to him expressing profound personal anguish over the omission of her role, framing it as a tied to the gendered and political biases she had endured. In a sent letter dated June 6, 1948, she reflected critically on her own perseverance in from 1933 to 1938, describing it as a "struggle... waged with very little success" against institutional complicity, underscoring her postwar conviction that moral clarity should supersede professional survival. Meitner's ethical opposition to weaponizing fission manifested clearly in her refusal of Allied invitations to join atomic bomb efforts, including the ; she declared, "I will have nothing to do with a bomb," citing her experiences as a nurse amid carnage and a principled aversion to enabling mass death. Upon news of the bombing on August 6, 1945, she undertook a five-hour solitary walk to grapple with the realization that her 1939 insights had enabled unprecedented destruction, later articulating in reflections—such as a 1946 exchange with President Truman—that scientists bore responsibility for foreseeing and mitigating such applications, while expressing hope the device would never be deployed again. By 1953, she reiterated in public statements that true scientific pursuit aimed at truth and human betterment, not devastation, reinforcing her lifelong despite the irreversible military legacy of her work.

Nobel Prize Assessment

1944 Award to Otto Hahn

In November 1944, the Royal Swedish Academy of Sciences awarded the to alone "for his discovery of the of heavy nuclei." The decision recognized Hahn's experimental work in late 1938, where he and irradiated with neutrons and chemically identified lighter elements like among the products, leading Hahn to conclude that the had split into fragments of comparable size. This breakthrough, building on prior radiochemical investigations Hahn conducted with Lise Meitner from onward, provided the first evidence of , a process releasing enormous energy. Due to disruptions, Hahn could not travel to until December 10, 1945, when he formally received the prize from King Gustaf V. In the presentation speech by Professor Arne Westgren, Hahn's long-term collaboration with Meitner—spanning nearly 30 years—was explicitly acknowledged, noting their joint studies on neutron-induced transmutations in and other heavy elements up to 1938. Westgren emphasized Hahn's cautious approach in interpreting the anomalous results, which ultimately confirmed the splitting of atomic nuclei rather than mere transmutation into neighboring elements, distinguishing it from earlier alpha and processes. The award's focus on aligned with Hahn's radiochemical methods for detecting products, as opposed to purely physical interpretations. Hahn dedicated his Nobel lecture, delivered on December 11, 1945, to detailing the step-by-step experiments, including the use of the newly discovered as a probe, and expressed surprise at the wartime applications of in atomic bombs, which he had not foreseen. While Strassmann's technical contributions to the separations were integral, the committee credited Hahn as the principal investigator driving the recognition of 's chemical implications.

Case for Meitner's Recognition

Lise Meitner provided the pivotal theoretical interpretation of the experimental results obtained by and , framing their observation of from neutron-bombarded as rather than mere . In late December 1938, after fleeing to , Meitner received Hahn's correspondence detailing the unexpected presence of , which contradicted expectations of radium formation. During a walk with her nephew on December 26, she proposed applying Niels Bohr's liquid-drop model to the : upon neutron absorption, the deformed overcomes electrostatic repulsion and splits into two fragments, such as and , releasing approximately 200 megaelectronvolts of per due to mass defect converted via E=mc². This explanation, co-authored with Frisch and published in on January 16, 1939, coined the term "" by analogy to biological division and predicted neutron emission enabling chain reactions. Meitner's long-standing leadership of the uranium research group, spanning over two decades with Hahn since , underscored her indispensable role; she directed the experiments remotely post-exile and had co-authored key papers with Hahn and Strassmann from 1935 to 1938, establishing the foundational radiochemical framework. Hahn's own December 22, 1938, publication in Naturwissenschaften acknowledged Meitner's suggestion to pursue identification but remained tentative without her physics-based resolution, as the results initially appeared anomalous under prevailing transuranic hypotheses. Her interdisciplinary expertise as a complemented Hahn's , providing causal clarity: the release and fragment asymmetry were inexplicable without deformation and rupture, directly linking experiment to broader implications like sustained reactions. Historians of science argue that crediting fission solely to Hahn overlooks the symbiotic necessity of theory and experiment, with Meitner's insight enabling global recognition of the phenomenon's significance by early , influencing figures like Bohr and Fermi. Her exclusion from the 1944 Nobel Prize in Chemistry, despite nominations alongside Hahn as early as and up to 48 times total, stemmed partly from Nazi-era persecution distorting collaboration records and post-war narratives minimizing her contributions, yet empirical validation of her model through subsequent experiments affirms co-discovery status. This reassessment aligns with causal realism: without her framework, Hahn's data risked obscurity, as evidenced by initial skepticism until the Nature publication.

Counterarguments and Committee Rationale

The Nobel Committee for Chemistry awarded the 1944 prize solely to Otto Hahn for "his discovery of the fission of heavy nuclei," emphasizing that the achievement stemmed from "purely chemical experimental research" conducted by Hahn and his collaborator Fritz Strassmann, which identified as a product of bombardment. This rationale positioned the core discovery as Hahn's chemical demonstration that nuclei fragmented into lighter elements, an unforeseen outcome verified through radiochemical analysis rather than physical theory. The committee's presentation speech acknowledged Hahn's long-term collaboration with Meitner but attributed the fission insight to Hahn's laboratory persistence in interpreting anomalous results from late 1938 experiments, after which Hahn published the chemical evidence in January 1939 without a full theoretical framework. Counterarguments to including Meitner highlight that her primary contribution involved theoretical interpretation developed in exile in Sweden during December 1938, after Hahn had communicated preliminary experimental data to her via letter; she and Otto Robert Frisch proposed the fission mechanism and energy release calculations only in a February 1939 publication, building on but subsequent to the empirical findings. Proponents of Hahn's sole credit argue that Nobel recognition in Chemistry prioritizes novel experimental observations—here, the chemical proof of nuclear splitting into identifiable isotopes like barium—over interpretive models, which might align more with Physics but were not awarded as such for fission. Similarly, Strassmann's hands-on role in the irradiations and separations was not rewarded, underscoring the committee's focus on Hahn as the senior investigator who directed the work and grappled with its implications amid wartime constraints. Further rationale from archival nominations and deliberations, revealed post-50-year embargo, indicates the committee viewed Hahn's 1938-1939 results as the foundational "" warranting Chemistry recognition, with Meitner's absence from the Kaiser Wilhelm Institute during the decisive experiments limiting her direct involvement to prior collaborative context rather than the breakthrough phase. Some historical analyses contend that emphasizing chemical evidence avoided diluting the prize across physics and chemistry boundaries, as Meitner and Frisch's liquid-drop model analogy explained why splitting occurred but did not establish the fact of , which Hahn's radiochemical purity tests confirmed. While personal factors, such as Swedish physicist Manne Siegbahn's reported reservations toward Meitner, may have influenced evaluations, the official justification centered on crediting the empirical origination of as a chemical phenomenon under Hahn's leadership.

Later Career and Recognition

Swedish and Post-War Work

Upon arriving in Sweden in July 1938 after fleeing Nazi Germany, Meitner was hosted by physicist Manne Siegbahn at his laboratory in Stockholm, where she initially continued experimental work on nuclear reactions despite limited resources and institutional focus on X-ray spectroscopy rather than her expertise in radioactivity. Siegbahn's lab, geared toward applied defense-related research during the war, provided Meitner with shared space but no independent facilities or funding, leading to professional isolation; she described her situation as an "exile from physics" due to Siegbahn's emphasis on practical applications over theoretical nuclear studies and his reported prejudices against women in science. Her output during this period was constrained, with publications limited to a few papers on beta decay and neutron interactions, supplemented by correspondence with international colleagues like Niels Bohr. Post-war, Meitner gained slight institutional traction, becoming a citizen in 1949 and serving as a full member of the Royal Swedish Academy of Sciences from 1945, though her research remained hampered by inadequate equipment for high-energy nuclear experiments. In the late 1940s, she transitioned from Siegbahn's institute to advisory roles, including consultations on Sweden's early development, such as the subterranean R1 reactor project initiated in 1947 at the Royal Institute of Technology, where she contributed insights on fission chain reactions without direct involvement in construction. She conducted modest experimental work on isotope separation and moderation but produced no major breakthroughs, shifting toward lecturing and mentoring students amid declining health and resources; by the , her efforts focused on educational outreach, including visits to the for talks at institutions like in 1946 and 1950. Meitner retired formally around 1960 but continued informal collaborations until her death in 1968, reflecting a career phase marked by recognition abroad rather than prolific Swedish-based innovation.

Awards and Honors Received

Meitner received the Lieben Prize in 1925 from the for her early work on and . In 1949, the awarded her the Max Planck Medal, recognizing her lifetime contributions to , making her the first woman to receive this distinction. She was also granted the Otto Hahn Prize in 1955 by the City of for achievements in chemistry and physics. In 1966, the U.S. Atomic Energy Commission presented the jointly to Meitner, , and for their collaborative and its implications for . This $50,000 prize, established to honor advancements in nuclear science, acknowledged their 1938-1939 experiments that elucidated the process.

Scientific Legacy and Debates

Impact on Nuclear Physics

Lise Meitner's theoretical explanation of , developed in collaboration with during her exile in in late 1938, provided the first physical interpretation of the experimental results obtained by and , who had observed among bombardment products. Applying Niels Bohr's liquid drop model to the nucleus, Meitner deduced that absorption induced asymmetric division into two fragments of comparable mass, such as and , with a mass defect yielding approximately 200 MeV of kinetic energy per event through conversion via E=mc². This insight, detailed in their February 11, 1939, paper "Disintegration of by s: a New Type of ," coined the term "" and predicted sufficient for potential chain reactions, shifting from passive observation of natural decay to engineered heavy-element transmutations. The Meitner-Frisch framework validated fission as a viable endothermic barrier-crossing process, stimulating theoretical advancements in nuclear stability and reaction dynamics, including Fermi's subsequent chain reaction experiments and the Manhattan Project's weapon designs. Her calculation of energy release—about one-fifth the uranium nucleus mass converted—quantified fission's efficiency over chemical reactions by five orders of magnitude, foundational for reactor criticality models and accelerator-based heavy-ion studies. Earlier, Meitner's co-discovery of protactinium-231 with Hahn in November 1917 extended the actinide series, revealing alpha decay chains beyond uranium and informing models of nuclear shell structure. Her independent observation of the Auger effect in 1922, involving non-radiative electron cascades following inner-shell ionization, clarified beta decay's atomic aftermath, influencing quantum treatments of nuclear-electron interactions. By establishing fission's causal mechanism—surface tension overcoming repulsion in deformed nuclei—Meitner's work catalyzed the field's pivot toward harnessing binding energies, underpinning postwar developments in fission-track dating, isotope production, and theoretical , despite her ethical stance against bomb applications.

Criticisms and Reassessments of Contributions

While was awarded the 1944 solely for the , debates have persisted regarding the precise attribution of contributions among Hahn, , and Lise Meitner. The Nobel Committee's rationale emphasized Hahn's chemical of as a fission product from irradiation, viewing this experimental evidence—conducted by Hahn and Strassmann in late 1938—as the foundational , with Meitner's subsequent theoretical deemed interpretive rather than originary. Critics of expanding credit to Meitner have argued that her physical absence from the after fleeing in July 1938 limited her direct involvement in the decisive experiments, positioning her role as advisory via correspondence rather than hands-on execution. This perspective holds that the Nobel's focus on chemical justified Hahn's singular recognition, as Meitner's physics-oriented explanation, published in on February 11, 1939, with nephew Otto Frisch, built upon rather than initiated the empirical findings. Reassessments by historians of science, however, have elevated Meitner's foundational influence, portraying her as the intellectual architect of the bombardment research initiated in 1934. She directed the collaborative effort at the Kaiser Wilhelm Institute, interpreting early anomalous results as potential transuranic elements before guiding the team toward recognizing fission-like processes, and her December 1938 correspondence with Hahn prompted the critical analysis. Crucially, reassessments credit her application of the liquid drop model—proposed by in 1935—to theorize deformation and splitting, calculating the ~200 MeV energy release that confirmed the process's viability and distinguished it from mere . These analyses counter earlier dismissals by underscoring causal interdependence: without Meitner's persistent theoretical framing, Hahn and Strassmann's chemical observations might have remained unexplained artifacts, as evidenced by the team's prior misattributions to new elements. Further scrutiny has questioned whether institutional biases, including disciplinary divides between and physics, undervalued Meitner's integrative approach, with some scholars attributing the Nobel omission to a preference for verifiable wartime contributions over insights. Despite her 48 nominations across physics and , no reassessment has uncovered substantive scientific flaws in her work; instead, they affirm its predictive power, as her Frisch collaboration's model anticipated chain reactions later realized in reactors and weapons. This body of reevaluation, drawn from archival letters and lab records, reframes the as a synergistic triad—Hahn-Strassmann's empirics validated by Meitner's theory—challenging the isolated experimental narrative.

References

  1. [1]
    Women in Radiation History: Lise Meitner | US EPA
    Mar 10, 2025 · ​In 1926 Lise Meitner became the first female professor of physics in Germany. Because she was Jewish, her physicist friends helped sneak her ...
  2. [2]
    Lise Meitner by Ruth Lewin Sime - University of California Press
    Lise Meitner (1878-1968) was a pioneer of nuclear physics and co-discoverer, with Otto Hahn and Fritz Strassmann, of nuclear fission. Braving the sexism of the ...
  3. [3]
    Women of the Manhattan Project: Lise Meitner (U.S. National Park ...
    May 28, 2024 · Born in Vienna in 1878, Lise Meitner enrolled at the University of Vienna in 1901 and became only the second woman to earn a PhD in Physics from there in 1905.
  4. [4]
    Lise Meitner's fantastic explanation: nuclear fission
    Feb 14, 2012 · The letter provided the first theoretical explanation for the splitting of the atom, and coined a new term in physics: fission.
  5. [5]
    Manhattan Project: The Discovery of Fission, 1938-1939 - OSTI.gov
    Calculations made by Hahn's former colleague, Lise Meitner (above, with Otto Hahn), a refugee from Nazism then staying in Sweden, and her nephew, Otto Frisch, ...
  6. [6]
    Lise Meitner, the scientist who changed medicine through the ... - NIH
    May 29, 2024 · Dr Lise Meitner was a nuclear physicist whose research explained how unstable atoms produced radiation. Her discovery of nuclear fission in 1939 ...
  7. [7]
    A Nobel Tale of Postwar Injustice - Physics Today
    Recently released Swedish documents reveal why Lise Meitner, codiscoverer of nuclear fission, did not receive the 1946 physics prize for her theoretical ...
  8. [8]
    Politics, Persecution, and the Prize: Lise Meitner and the Discovery ...
    Dec 14, 2018 · Scholars of the Nobel awards have examined the decision processes that excluded her. And in Germany especially, historians and scientists have ...
  9. [9]
    Lise Meitner | Biographies - Atomic Archive
    Lise Meitner was born on November 7, 1878, in Vienna, Austria. The third of eight children of a Jewish family, she entered the University of Vienna in 1901.
  10. [10]
    Lise Meitner - Biography, Facts and Pictures - Famous Scientists
    Sep 27, 2016 · Her father was Philipp Meitner, a lawyer, and chess master. Her mother was Hedwig Skovran, a talented amateur musician. Lise was the third of ...
  11. [11]
    Lise Meitner | Jewish Women's Archive
    Early Life. Lise's parents were assimilated Viennese Jews, who did not practice Judaism. Her father Philipp was a lawyer whose family stemmed from Moravia.Early Life · Early Research · Work During Nazi RegimeMissing: background | Show results with:background
  12. [12]
    Physics in Vienna in the 19th century | 650 plus
    May 3, 2024 · ... Lise Meitner. Physics in Austria is ... In 1897 women were finally allowed to join the Philosophical Faculty of the University of Vienna.<|separator|>
  13. [13]
    Lise Meitner - AWIS
    In 1901, Meitner enrolled at the University of Vienna to study physics under her mentor, Ludwig Boltzmann. In 1906, she earned her doctorate degree and went on ...Missing: PhD thesis
  14. [14]
    Women in Nuclear History: Lise Meitner
    1) Born in 1878 in Vienna, Elise (she later shortened her name to Lise) was the third of eight children born to a Jewish lawyer, Philipp Meitner, and his wife ...Missing: family background childhood early life<|separator|>
  15. [15]
    Part 2
    Lise Meitner (1878-1968) studied physics and mathematics in Vienna and, in 1906, was the second woman to receive her PhD in physics from the University of ...Missing: training | Show results with:training
  16. [16]
    Lise Meitner: The Forgotten Mother of Nuclear Fission | by Bob Lynn
    Apr 29, 2025 · After completing her studies, Meitner faced limited opportunities in Vienna, where the only position available to women with her qualifications ...
  17. [17]
    [PDF] USE MEITNER LOOKS BACK - International Atomic Energy Agency
    At the invitation of the Agency, Professor Lise. Meitner gave recollections of her career in a lecture in Vienna on 20 September 1963. She spoke as follows:.
  18. [18]
    Full article: News and Views - Taylor & Francis Online
    It was Stefan Meyer, who made Lise Meitner interested in the physics of radioactivity. During his directorship Viktor Hess and Georg V. Hevesy worked at the ...<|separator|>
  19. [19]
    December 1938: Discovery of Nuclear Fission
    Dec 3, 2007 · Meitner suggested they view the nucleus like a liquid drop, following a model that had been proposed earlier by the Russian physicist George ...Missing: primary | Show results with:primary
  20. [20]
    Otto Hahn – Biographical - NobelPrize.org
    At the end of 1907, Dr. Lise Meitner came to Berlin from Vienna and then began more than thirty years' collaboration. Their joint work embraced: investigations ...
  21. [21]
    The Discovery of Nuclear Fission | Jeremy Bernstein | Inference
    In September 1907, Meitner arrived in Berlin hoping to study for a few more semesters. She ended up staying in the German capital for the next thirty years ...
  22. [22]
    For the Sake of Science
    Apr 6, 2021 · Hahn and Meitner had first started working together in 1907, not long after Hahn's return to Germany. Their collaboration began with the study ...
  23. [23]
    Protactinium - Los Alamos National Laboratory
    " In 1917/18, two groups of scientists, Otto Hahn and Lise Meitner of Germany and Frederick Soddy and John Cranston of Great Britain, independently discovered ...
  24. [24]
    Thorium power has a protactinium problem
    Aug 6, 2018 · As discoverers of eka-tantalum's longest-lived isotope, Meitner and Hahn named this new element protactinium. They had isolated protactinium 231 ...
  25. [25]
    5 Women Who Changed History in Nuclear Science
    Mar 24, 2023 · Lise Meitner​​ Meitner was the first female professor of physics in Germany and helped discover the radioactive element protactinium although her ...1. Marie Curie · 2. Lise Meitner · 4. Chien-Shiung Wu
  26. [26]
    Lise Meitner, β-decay and non-radiative electromagnetic transitions
    Sep 9, 2020 · Lise Meitner was one of the key figures in studying β decay by measuring electrons with magnetic spectrometers (as the instruments would be called today).Abstract · Introduction · Electron spectrometry... · The decay ofTh
  27. [27]
    Lise Meitner and the beta‐ray energy controversy - AIP Publishing
    Jun 1, 1983 · This article reviews the sequence of events as they preceded, coincided with, and followed her work on the subject. Topics. Beta particles, News ...
  28. [28]
    Chronicle of the Directors - Max-Planck-Institut für Chemie
    Lise Meitner (1878-1968) worked from 1912, on an honorary basis, as a scientific guest at the Kaiser Wilhelm Institute for Chemistry in Berlin and, in 1913, ...
  29. [29]
    Lise Meitner: the nuclear pioneer who escaped the Nazis
    Dec 3, 2019 · In 1912, Hahn and Meitner moved to the Kaiser Wilhelm Institute for Chemistry (KWIC) to study radioactivity. This was the early 20th Century ...
  30. [30]
    Lise Meitner – Fame without a Nobel Prize
    Nov 5, 2015 · In 1917, Lise Meitner was tasked with setting up the physics department at the Kaiser Wilhelm Institute in Berlin. She remained in charge of ...
  31. [31]
    The Discovery of Nuclear Fission - Max-Planck-Institut für Chemie
    Nuclear fission was discovered at the Kaiser Wilhelm Institute for Chemistry in December 1938. While bombarding uranium with neutrons.Missing: primary | Show results with:primary
  32. [32]
    Lise Meitner - Nuclear Museum - Atomic Heritage Foundation
    Lise Meitner (1878-1968) was an Austrian physicist. Meitner was part of the team that discovered and explained nuclear fission and foresaw its explosive ...
  33. [33]
    Otto Hahn, Lise Meitner, and Fritz Strassmann
    In 1938 Hahn, Meitner, and Strassmann became the first to recognize that the uranium atom, when bombarded by neutrons, actually split.
  34. [34]
    Lise Meitner: A Noble Scientist | Office for Science and Society
    Mar 4, 2021 · Meitner was a woman of Jewish ancestry—and thus, was rarely lauded for her critical contributions to physics and chemistry at the time of their ...
  35. [35]
    A Review Essay on "Lise Meitner and the Dawn of the Nuclear Age ...
    Lise Meitner was born in 1878 of a middle-class Jewish family in Vienna. Early on it was clear that she had special ability in science and mathematics, although ...<|separator|>
  36. [36]
    Hahn, Meitner and the discovery of nuclear fission - Chemistry World
    Nov 5, 2018 · 80 years ago, Otto Hahn and Lise Meitner made a discovery that led to nuclear weapons – yet Meitner was never given the recognition she deserved.
  37. [37]
    Meitner and Hahn: Partners and Pioneers in Nuclear Physics
    Feb 15, 2018 · Hahn-Meitner Research Group​​ In 1907, Otto Hahn and Lise Meitner met at the University of Berlin, initiating a life-long collaboration between ...
  38. [38]
    Lise Meitner's escape from Germany | American Journal of Physics
    Mar 1, 1990 · ... until the annexation of Austria in 1938 precipitated her dismissal. Forbidden to emigrate, she narrowly escaped to the Netherlands with the ...Missing: resignation | Show results with:resignation
  39. [39]
    (PDF) Lise Meitner's escape from Germany - ResearchGate
    Sep 14, 2016 · ... Nazi racial laws until the annexation of Austria in 1938 precipitated her dismissal. Forbidden to emigrate, she narrowly escaped to the ...<|control11|><|separator|>
  40. [40]
    Lise Meitner - DPMA
    Jun 25, 2025 · Lise Meitner, who was born 140 years ago and died 50 years ago, was a brilliant scientist who had to fight discrimination throughout her life.Missing: scholarly | Show results with:scholarly
  41. [41]
    Lise Meitner at the Kaiser Wilhelm Institute for Chemistry
    Lise Meitner was associated with the Kaiser Wilhelm Institute for Chemistry from its inception in 1912 until her emigration from Germany in 1938.
  42. [42]
    Lise Meitner and the Walk that Changed the World - Math! Science ...
    She then began attending Max Planck's lectures at the Friedrich Wilhelm University in Berlin. Planck went on the record stating that he did not want women in ...
  43. [43]
    Meitner's escape | IOPSpark - Institute of Physics
    Meitner travelled from the Netherlands to Sweden, but she was treated as an outsider at the University of Stockholm and had to carry out technical work that ...
  44. [44]
    Lise Meitner in Sweden 1938-1960: Exile from physics
    PDF | Lise Meitner fled Germany for Sweden in 1938. Her professional difficulties in Stockholm coupled with her exclusion from the discovery of fission.
  45. [45]
    4: The Discovery of Fission (1938) - Chemistry LibreTexts
    Mar 7, 2023 · From 1935-1938, Hahn, Strassmann, and Meitner in Germany identified at least 10 radioactive products resulting from the neutron bombardment ...
  46. [46]
    [PDF] Discovery of nuclear fission in Berlin 1938
    Hahn and Strassmann (1938) had shown that by the irradiation of uranium in addition to several supposedly transuranium elements other products resulted which ...Missing: details | Show results with:details
  47. [47]
    Disintegration of Uranium by Neutrons: A New Type of Nuclear ...
    Disintegration of Uranium by Neutrons: A New Type of Nuclear Reaction. Lise Meitner and Otto R. Frisch. Nature, 143, 239-240, (Feb. 11, 1939).
  48. [48]
    Hahn and Strassmann discover fission - chemteam.info
    This method worked very well. When uranium is bombarded with slow neutrons, it is not easy to understand from energy considerations how radium isotopes can ...
  49. [49]
    Meitner & Frisch On Nuclear Fission - Atomic Heritage Foundation
    In the spring of 1938, Lise Meitner, being a Jew, had to leave Berlin and went to a job offered her by Manne Siegbahn in the Nobel Institute of Stockholm. Being ...Missing: resignation | Show results with:resignation
  50. [50]
    Disintegration of Uranium by Neutrons: a New Type of Nuclear ...
    Disintegration of Uranium by Neutrons: a New Type of Nuclear Reaction. Lise Meitner &; O. R. Frisch. Nature volume 143, pages 239–240 ( ...
  51. [51]
    Lise Meitner and Otto Frisch, “Disintegration of Uranium by Neutrons ...
    Meitner and Frisch explain how energy was released by neutron bombardment during the fission of the uranium nuclei.
  52. [52]
    Opinion: Lauding Lise Meitner, Who Said 'No' to the Atomic Bomb
    Aug 24, 2023 · And I believe Meitner's refusal to participate in the weaponization of her work on moral grounds makes her more worthy of commemoration than ...
  53. [53]
    Lise Meitner | Biography & Facts | Britannica
    Oct 10, 2025 · Lise Meitner ; Born: November 7, 1878, Vienna, Austria-Hungary [now in Austria] ; Died: October 27, 1968, Cambridge, Cambridgeshire, England (aged ...
  54. [54]
    How Antisemitism and Professional Betrayal Marred Lise Meitner's ...
    Sep 14, 2023 · Meitner, who had fled Germany because of the Nazis, was horrified at the thought of an atomic bomb. She also faulted Hahn for not speaking ...
  55. [55]
    Lise Meitner's Devastating Letter to Otto Hahn - RealClearScience
    Aug 10, 2017 · Meitner and Hahn worked together during some of the most momentous decades in modern history. When the two met in Berlin in 1906 as young, up- ...
  56. [56]
    120 Lise Meitner: Letter to Otto Hahn [June 6, 1948]
    Because Scherrer worked in Switzerland, which was neutral during World War II, his institute was fairly well-off compared to most institutions in Germany or ...
  57. [57]
    The Nobel Prize in Chemistry 1944 - NobelPrize.org
    The Nobel Prize in Chemistry 1944 was awarded to Otto Hahn "for his discovery of the fission of heavy nuclei". Otto Hahn received his Nobel Prize one year ...
  58. [58]
    Otto Hahn – Facts - NobelPrize.org
    Otto Hahn received his Nobel Prize one year later, in 1945. Prize share: 1/1. Work. The discovery of the neutron in 1932 provided a powerful new tool for ...
  59. [59]
    Award ceremony speech: The Nobel Prize in Chemistry 1944
    In collaboration with Lise Meitner, with whom he has worked for nearly thirty years, Hahn studied from 1936 to 1938 the products obtained by projecting neutrons ...
  60. [60]
    Belated recognition: Lise Meitner's role in the discovery of fission
    Recognition of LiseMeitner's contributions remedies a significant historical omission, and places the discovery itself in its proper scientific context.Missing: arguments | Show results with:arguments<|control11|><|separator|>
  61. [61]
    Why is there no Nobel physics prize for nuclear fission?
    Oct 2, 2023 · In the case of Meitner, some scholars suggest that Siegbahn's animosity prevented her from winning. As a leading Swedish physicist, he would ...
  62. [62]
    Lise Meitner in Sweden 1938–1960: Exile from physics
    Aug 1, 1994 · Lise Meitner fled Germany for Sweden in 1938. Her professional difficulties in Stockholm coupled with her exclusion from the discovery of ...
  63. [63]
    Elise (Lise) Meitner - skbl.se
    Mar 8, 2018 · ... Lise Meitner could leave Manne Siegbahn's institute. She became an advisor on the project to build Sweden's first subterranean reactor and ...
  64. [64]
    https://www.iaea.org/newscenter/news/pioneering-nuclear-science-discovery-nuclear-fission
  65. [65]
    A renaming proposal: “The Auger–Meitner effect” - Physics Today
    Sep 1, 2019 · According to Meitner's 1922 description, “a primary (nuclear) β-ray transforms itself in the nucleus into a γ-ray. The γ-ray either goes through ...
  66. [66]
    Belated recognition: Lise Meitner's role in the discovery of fission
    Aug 10, 2025 · In fact, however,Meitner was essential to the discovery at every phase: she brought the uranium investigation to Berlin, led the Berlin group ...Missing: reassessments | Show results with:reassessments
  67. [67]
    Lise Meitner and Fission: Fallout from the Discovery - Sime - 1991
    Of her pioneering work in nuclear physics, little is said; she is remembered primarily for nuclear fission, a discovery in which she did not share. Especially ...Missing: reassessments | Show results with:reassessments
  68. [68]
    Overlooked for the Nobel: Lise Meitner - Physics World
    Oct 5, 2020 · Disciplinary bias and a stew of other prejudices helped deny the physicist Lise Meitner a share of the 1944 Nobel Prize for Chemistry.Missing: debates | Show results with:debates
  69. [69]
    Lise Meitner and the Discovery of Nuclear Fission - jstor
    Scientific publications show that the in- vestigation that led to the discovery of fission was intensely interdisciplinary. Questions from nuclear physics ...