To Be Announced
On February 11, 2021, in New York, NY, the United States Postal Service® will issue the Chien-Shiung Wu stamp (Forever® priced at the First-Class Mail® rate) in one design, in a pressure-sensitive adhesive (PSA) pane of 20 stamps (Item 480200). This stamp will go on sale nationwide February 11, 2021, and must not be sold or canceled before the first-day-of-issue.
This new Forever stamp honors Dr. Chien-Shiung Wu (1912–1997), one of the most influential nuclear physicists of the 20th century. The stamp art features a detailed portrait of Wu wearing a black-and-white high-collared, traditional Chinese gown known as qipao. The illustration was first drawn in graphite, then rendered in egg tempera paint. The background was painted with the pigment lapis lazuli, a highly valued color historically used in artistic depictions of angels, nobility, and the Virgin Mary. Art director Ethel Kessler designed the stamp with original art by Kam Mak.
Availability to Post Offices: Item 480200, Chien-Shiung Wu (Forever Priced at the First-Class Mail Rate) Commemorative PSA Pane of 20 Stamps
Stamp Fulfillment Services will not make an automatic push distribution to Post Offices. Post Offices may begin ordering stamps before the first-day-of-issue through SFS Web at.
Special Dedication Postmarks
Only the following pictorial postmark is permitted for the Chien-Shiung Wu stamp. The word “Station” or the abbreviation “STA” is required somewhere in the design because it will be a temporary station. Use of any image other than the following special pictorial image is prohibited.
Guidelines for Finalizing the Chien-Shiung Wu Stamp Pictorial Postmark Art
To finalize the Chien-Shiung Wu stamp pictorial postmark art, insert the date, city, state, and ZIP Code™ of the physical location of your event adjacent to the stamp image. Overall dimensions of the pictorial postmark must not exceed 4 inches (horizontally) by 2 inches (vertically). Collectors prefer the dimensions 3-1/2 inches by 1 inch.
The Postal Service™ must make all special postmarks known to collectors through advance publicity in the Postal Bulletin. Therefore, all special dedication cancellations must be reported to Stamp Services 4 weeks before the event using PS Form 413, Pictorial Postmark Announcement/Report. To get a copy of the form, go to.
How to Order the First-Day-of-Issue Postmark
Customers have 120 days to obtain the first-day-of-issue postmark by mail. They may purchase new stamps at their local Post Office™ or at The Postal Store® website at. They must affix the stamps to envelopes of their choice, address the envelopes (to themselves or others), and place them in a larger envelope addressed to:
FDOI – Chien-Shiung Wu Stamp
USPS Stamp Fulfillment Services
8300 NE Underground Drive, Suite 300
Kansas City, MO 64144-9900
After applying the first-day-of-issue postmark, the Postal Service will return the envelopes through the mail. There is no charge for the postmark up to a quantity of 50. There is a 5-cent charge for each additional postmark over 50. All orders must be postmarked by June 11, 2021.
How to Order First-Day Covers
The Postal Service also offers first-day covers for new stamp issues and Postal Service stationery items postmarked with the official first-day-of-issue cancellation. Each item has an individual catalog number and is offered in the USA Philatelic catalog and online at. Customers may register to receive a free USA Philatelic catalog online at .
Locally produced items are not authorized. Only merchandise that has been approved and assigned an item number by Headquarters Retail Marketing may be produced and sold.
Technical details for the Chien-Shiung Wu stamp will appear in a future edition of the Postal Bulletin.
— Stamp Services, Marketing, 12-31-20
Chien-Shiung Wu (吳健雄; May 31, 1912 – February 16, 1997) was a Chinese-American experimental physicist who made significant contributions in the field of nuclear physics. Wu worked on the Manhattan Project, where she helped develop the process for separating uranium into uranium-235 and uranium-238 isotopes by gaseous diffusion. She is best known for conducting the Wu experiment, which proved that parity is not conserved. This discovery resulted in her colleagues Tsung-Dao Lee and Chen-Ning Yang winning the 1957 Nobel Prize in Physics, while Wu herself was awarded the inaugural Wolf Prize in Physics in 1978. Her expertise in experimental physics evoked comparisons to Marie Curie. Her nicknames include the “First Lady of Physics”, the “Chinese Madame Curie” and the “Queen of Nuclear Research”.
Chien-Shiung Wu was born in the town of Liuhe in Taicang, Jiangsu province, China, on 31 May 1912, the second of three children of Wu Zhong-Yi (吳仲裔) and Fan Fu-Hua. The family custom was that children of this generation had Chien as the first character (generation name) of their forename, followed by the characters in the phrase Ying-Shiung-Hao-Jie, which means “heroes and outstanding figures”. Accordingly, she had an older brother, Chien-Ying, and a younger brother, Chien-Hao. Wu and her father were extremely close, and he encouraged her interests passionately, creating an environment where she was surrounded by books, magazines, and newspapers.
Wu received her elementary school education at Ming De School, a school for girls founded by her father. She left her hometown in 1923 at the age of 11 to go to the Suzhou Women’s Normal School No. 2. This was a boarding school with classes for teacher training as well as for regular high school. Admission to teacher training was more competitive, as it did not charge for tuition or board and guaranteed a job on graduation. Although her family could have afforded to pay, Wu chose the more competitive option and was ranked ninth among around 10,000 applicants.
In 1929, Wu graduated at the top of her class and was admitted to National Central University in Nanjing. According to government regulations of the time, teacher-training college students wanting to move on to universities needed to serve as schoolteachers for one year. In Wu’s case, this was only nominally enforced. She went to teach at a public school in Shanghai, the president of which was the philosopher Hu Shih, whose class she took.
From 1930 to 1934, Wu studied at National Central University (later renamed Nanjing University and reinstated in Taiwan), first in mathematics, but later transferring to physics. She became involved in student politics. Relations between China and Japan were tense at this time, and students were urging the government to take a stronger line with Japan. Wu was elected as one of the student leaders by her colleagues because they felt that since she was one of the top students at the university, her involvement would be forgiven, or at least overlooked, by the authorities. That being the case, she was careful not to neglect her studies. She led protests that included a sit-in at the Presidential Palace in Nanjing, where the students were met by Chiang Kai-shek.
For two years after graduation, she did graduate-level study in physics and worked as an assistant at Zhejiang University. She became a researcher at the Institute of Physics of the Academia Sinica. Her supervisor was Gu Jing-Wei, who had earned her PhD abroad at University of Michigan and encouraged Wu to do the same. Wu was accepted by University of Michigan, and her uncle, Wu Zhou-Zhi, provided the necessary funds. She embarked for the United States with a female friend, Dong Ruo-Fen (董若芬), a chemist from Taicang, on the SS President Hoover in August 1936. Her parents and uncle saw her off. She would never see her parents again.
The two women arrived in San Francisco, where Wu’s plans for graduate study changed after visiting the University of California, Berkeley. She met physicist Luke Chia-Liu Yuan, a grandson of Yuan Shikai (the first President of the Republic of China and self-proclaimed Emperor of China). Yuan showed her the Radiation Laboratory, where the director was Ernest O. Lawrence, who would soon win the Nobel Prize for Physics in 1939 for his invention of the cyclotron particle accelerator.
Wu heard that at Michigan women were not even allowed to use the front entrance, and decided that she would prefer to study at Berkeley. Yuan took her to see Raymond T. Birge, the head of the physics department, and he offered Wu a place in the graduate school despite the fact that the academic year had already commenced. Wu then abandoned her plans to study at Michigan and enrolled at Berkeley. Her Berkeley classmates included Robert R. Wilson and George Volkoff; her friends included Ursula Schaefer, a history student who chose to remain in the United States rather than return to Nazi Germany, and Margaret Lewis, an American post-doctoral student. Wu applied for a scholarship at the end of her first year, but there was prejudice against Asian students, and Wu and Yuan were instead offered a readership with a lower stipend. Yuan then applied for, and secured, a scholarship at Caltech.
Wu made rapid progress in her education and her research. Although Lawrence was officially her supervisor, she also worked closely with Emilio Segrè. Her thesis had two separate parts. The first was on bremsstrahlung, the electromagnetic radiation produced by the deceleration of a charged particle when deflected by another charged particle, typically an electron by an atomic nucleus. She investigated this using beta-emitting phosphorus-32, a radioactive isotope easily produced in the cyclotron that Lawrence and his brother John H. Lawrence were evaluating for use in cancer treatment and as a radioactive tracer. This marked Wu’s first work with beta decay, a subject on which she would become an authority. The second part of the thesis was about the production of radioactive isotopes of xenon produced by the nuclear fission of uranium with the 37-inch and 60-inch cyclotrons at the Radiation Laboratory.
Wu completed her PhD in June 1940, and was elected to Phi Beta Kappa, the US academic honor society. In spite of Lawrence and Segrè’s recommendations, she could not secure a faculty position at a university, so she remained at the Radiation Laboratory as a post-doctoral fellow.
Wu and Yuan were married at the home of Robert Millikan, Yuan’s academic supervisor and the President of Caltech, on May 30, 1942. Neither the bride’s nor the groom’s families were able to attend due to the outbreak of the Pacific War. Wu and Yuan moved to the East Coast of the United States, where Wu became a faculty member at Smith College, a private women’s college in Northampton, Massachusetts, while Yuan worked on radar for RCA. She found the job frustrating, as her duties involved teaching only, and there was no opportunity for research. She appealed to Lawrence, who wrote letters of recommendation to a number of universities. Smith responded by making Wu an associate professor and increasing her salary. She accepted a job from Princeton University in New Jersey as an instructor for naval officers.
In March 1944, Wu joined the Manhattan Project’s Substitute Alloy Materials (SAM) Laboratories at Columbia University. She lived in a dormitory there, returning to Princeton on the weekends. The role of the SAM Laboratories, headed by Harold Urey, was to support the Manhattan Project’s gaseous diffusion (K-25) program for uranium enrichment. Wu worked alongside James Rainwater in a group led by William W. Havens, Jr., whose task was to develop radiation detector instrumentation.
In September 1944, Wu was contacted by the Manhattan District Engineer, Colonel Kenneth Nichols. The newly commissioned B Reactor at the Hanford Site had run into an unexpected problem, starting up and shutting down at regular intervals. John Archibald Wheeler suspected that a fission product, xenon-135, with a half-life of 9.4 hours, was the culprit, and might be a neutron poison. Segrè then remembered the work that Wu had done at Berkeley on the radioactive isotopes of xenon. The paper on the subject was still unpublished, but Wu and Nichols went to her dorm room and collected the typewritten draft prepared for the Physical Review. Xenon-135 was indeed the culprit; it turned out to have an unexpectedly large neutron absorption cross-section.
After the end of the war in August 1945, Wu accepted an offer of a position as an associate research professor at Columbia. Communication with China was restored, and Wu received a letter from her family, but plans to visit China were disrupted by the Chinese Civil War, and the birth in 1947 of a son, Vincent Yuan (袁緯承), who would grow up to become a physicist like his parents. In 1949, Yuan joined the Brookhaven National Laboratory, and the family moved to Long Island. After the communists came to power in China that year, Wu’s father wrote urging her not to return. Since her passport had been issued by the Kuomintang government, she found it difficult to travel abroad. This eventually led to her decision to become a US citizen in 1954. She would remain at Columbia for the rest of her career. She became an associate professor in 1952, a full professor in 1958, and the Michael I. Pupin Professor of Physics in 1973. Her students called her the Dragon Lady, after the character of that name in the comic strip Terry and the Pirates.
In her post-war research, Wu continued to investigate beta decay. Enrico Fermi had published his theory of beta decay in 1934, but an experiment by Luis Walter Alvarez had produced results at variance with the theory. Wu set out to repeat the experiment and verify the result. She suspected that the problem was that a thick and uneven film of copper sulfate (CuSO4) was being used as a copper-64 beta ray source, which was causing the emitted electrons to lose energy. To get around this, she adapted an older form of spectrometer, a solenoidal spectrometer. She added detergent to the copper sulfate to produce a thin, even film. She then demonstrated that the discrepancies observed were the result of experimental error; her results were consistent with Fermi’s theory.
At Columbia, Wu knew the Chinese-born theoretical physicist Tsung-Dao Lee personally. In the mid-1950s, Lee and another Chinese theoretical physicist, Chen Ning Yang, grew to question a hypothetical law of elementary particle physics, the “law of conservation of parity”. One example highlighting the problem was the puzzle of the theta and tau particles, two apparently differently charged, strange mesons. They were so similar that they would ordinarily be considered to be the same particle; but different decay modes resulting in two different parity states were observed, suggesting that Θ+ and τ+ were different particles, if parity is conserved:
Θ+ → π+ + π0
τ+ → π+ + π+ + π−
Lee and Yang’s research into existing experimental results convinced them that parity was conserved for electromagnetic interactions and for the strong interaction. For this reason, scientists had expected that it would also be true for the weak interaction, but it had not been tested, and Lee and Yang’s theoretical studies showed that it might not hold true for the weak interaction. Lee and Yang worked out a pencil-and-paper design of an experiment for testing conservation of parity in the laboratory. Because of her expertise in choosing and then working out the hardware manufacture, set-up, and laboratory procedures, Wu then informed Lee that she could carry out the experiment.
Wu chose to do this by taking a sample of radioactive cobalt-60 and cooling it to cryogenic temperatures with liquid gases. Cobalt-60 is an isotope that decays by beta particle emission, and Wu was also an expert on beta decay. The extremely low temperatures were needed to reduce the amount of thermal vibration of the cobalt atoms to almost zero. Also, Wu needed to apply a constant and uniform magnetic field across the sample of cobalt-60 in order to cause the spin axes of the atomic nuclei to line up in the same direction. For this cryogenic work, she needed the facilities of the National Bureau of Standards and its expertise in working with liquid gases, and traveled to its headquarters in Maryland with her equipment to carry out the experiments.
Lee and Yang’s theoretical calculations predicted that the beta particles from the cobalt-60 atoms would be emitted asymmetrically and the hypothetical “law of conservation of parity” was invalid. Wu’s experiment showed that this is indeed the case: parity is not conserved under the weak nuclear interactions. Θ+ and τ+ are indeed the same particle, which is today known as a kaon, K+. This result was soon confirmed by her colleagues at Columbia University in different experiments, and as soon as all of these results were published — in two different research papers in the same issue of the same physics journal — the results were also confirmed at many other laboratories and in many different experiments.
The discovery of parity violation was a major contribution to particle physics and the development of the Standard Model. In recognition of their theoretical work, Lee and Yang were awarded the Nobel Prize for Physics in 1957. Wu’s role in the discovery was not publicly honored until 1978, when she was awarded the inaugural Wolf Prize.
In 1963, Wu experimentally demonstrated a universal form of Fermi’s beta decay model, confirming the Conserved Vector Current hypothesis of Richard Feynman and Murray Gell-Mann on the road to the Standard Model. Her demonstration that parity was not conserved brought other assumptions that physicists had made about the weak interaction into question. If parity is not conserved in weak force interaction, what about charge conjugation? This was an effect that held true for electromagnetism, gravity and the strong interaction, so it had been assumed that it would hold for the weak interaction too. Wu conducted a series of experiments on double beta decay in a salt mine under Lake Erie that proved that charge conjugation was not conserved either.
Another important experiment carried out by Wu was the first experimental confirmation of quantum results relevant to a pair of entangled photons as applicable to the Einstein-Podolsky-Rosen (EPR) paradox. Wu’s results confirmed Maurice Pryce and John Clive Ward’s calculations on the correlation of the quantum polarizations of two photons propagating in opposite directions. Wu later conducted research into the molecular changes in the deformation of hemoglobins that cause sickle-cell disease. She also did research on magnetism and the Mössbauer effect during the 1960s. She wrote a textbook with Steven Moszkowski, Beta Decay, which was published in 1966 and became a standard reference on the subject.
Wu’s older brother died in 1958, her father in 1959, and her mother in 1962. The United States State Department had imposed severe restrictions on travel to Communist countries by its citizens, so she was not permitted to visit mainland China to attend their funerals. She saw her uncle, Wu Zhou-Zhi, and younger brother, Wu Chien-Hao, on a trip to Hong Kong in 1965. After the 1972 Nixon visit to China, relations between the two countries improved, and she visited China again in 1973. By this time her uncle and brother had perished in the Cultural Revolution and the tombs of her parents had been destroyed. She was greeted by Zhou Enlai, who personally apologized for the destruction of the tombs. After this, she returned to China several times.
In later life, Wu became more outspoken. She protested the imprisonment in Taiwan of relatives of physicist Kerson Huang in 1959 and of the journalist Lei Chen in 1960. In 1964, she spoke out against gender discrimination at a symposium at the Massachusetts Institute of Technology. “I wonder,” she asked her audience, “whether the tiny atoms and nuclei, or the mathematical symbols, or the DNA molecules have any preference for either masculine or feminine treatment.” When men referred to her as Professor Yuan, she immediately corrected them and told them that she was Professor Wu. In 1975, Robert Serber, the new chairman of the Physics Department at Columbia University, adjusted her pay to make it equal to that of her male counterparts. She also protested the crackdown in China that followed the Tiananmen Square massacre of 1989. In the year 1978, she was awarded the first Wolf Prize in Physics, which has, as one of its criteria, being thought deserving to receive a Nobel Prize without receiving one. She retired in 1981 and became a professor emerita.
Wu died on February 16, 1997, in New York City at the age of 84 after suffering a stroke. An ambulance rushed her to St. Luke’s–Roosevelt Hospital Center, but she was pronounced dead on arrival. She was survived by her husband and son. In accordance with her wishes, her ashes were buried in the courtyard of the Ming De School that her father had founded and she had attended as a girl.