Fact-checked by Grok 2 weeks ago

Samuel C. C. Ting

Samuel C. C. Ting (born January 27, 1936) is a Chinese-American best known for his discovery of the J/ψ meson, a that provided key evidence for the of , for which he shared the 1976 with . He is also the principal investigator and founder of the Alpha Magnetic Spectrometer (AMS), a high-precision particle detector mounted on the (ISS) since 2011, which has collected over 257 billion events as of November 2025 to study , , and the origins of the through measurements of positrons, electrons, protons, and other particles. As the Thomas Dudley Cabot Professor of Physics at the (MIT), Ting has led international collaborations involving accelerators in the United States, , and space, advancing experimental and research. Born in , to Chinese parents Kuan Hai Ting, an engineering , and Tsun-Ying Wang, a psychology , both graduate students at the at the time, Ting spent much of his early childhood in —first in and —before moving to in 1949 amid political upheaval. He returned to the for higher education, earning a B.S.E. in both physics and mathematics in 1959 and a Ph.D. in physics in 1962 from the , where he worked under mentors including L.W. Jones and Martin Perl. Ting's early career included a Fellowship at from 1962 to 1965, followed by faculty positions at (1965–1971) and (starting in 1969), where he became the Thomas Dudley Cabot Professor in 1977. During this period, he led experiments at that culminated in the 1974 discovery of the J/ψ particle—a charmed quark-antiquark pair—using a proton beam on a target, confirming the existence of the charm quark and revolutionizing understanding of strong nuclear forces. This breakthrough, independently observed by Richter's team at SLAC, earned them the and the in 1976. In the 1990s, Ting shifted focus to space-based experiments, proposing the in 1995 as a detector to search for and primordial black holes using the and later the ISS. After a prototype flew on in 1998, the full AMS-02 instrument—a 16-nation, 600-scientist collaboration featuring the largest ever used in space—was installed on the ISS via Space Shuttle Endeavour's mission in May 2011. Over more than a decade of operation, AMS has delivered groundbreaking results, including precise flux measurements of positrons up to 1 TeV (published in Physical Review Letters in 2013 and updated through 2022), evidence of nuclei like antihelium, and constraints on models, with no predicted outcomes matching the observed anomalies in spectra. In April 2024, Ting presented findings from over 240 billion events at the American Physical Society's April Meeting; as of November 2025, analysis continues with over 257 billion events recorded. Ting's contributions extend to other discoveries, such as precise measurements of the electron's (less than 10⁻¹⁷ cm), alongside memberships in the (elected 1977) and numerous international academies. In 2023, he received the Bhabha Award for his AMS leadership, and in 2025, the International Center for Basic Science (ICBS) Basic Science Lifetime Award. His work continues to probe fundamental questions in cosmology and through ongoing AMS data analysis.

Early Life and Education

Family Background and Childhood

Samuel C. C. Ting was born on January 27, 1936, in , to graduate students Kuan Hai Ting, who studied , and Tsun-Ying Wang, who studied . As the first of three children, Ting acquired U.S. at birth, but his family returned to just two months later, driven by his parents' strong sense of patriotism amid the escalating . Ting's early childhood unfolded in wartime , where he lived as a from 1936 to 1945, frequently relocating to evade forces, including stays in and . Due to the chaos of air raids and instability, he received no formal schooling until age 12 and was primarily homeschooled by his mother, who emphasized and despite limited resources. His parents, both professors, shared stories of pioneering scientists like , James Clerk Maxwell, and , fostering Ting's curiosity about physics and self-directed learning in through available books. Raised partly by his maternal grandmother after his parents focused on their academic careers, Ting absorbed tales of his family's resilience, including his mother's determination to pursue education amid 's turbulent revolutions. In 1949, amid the and the Nationalist government's retreat, Ting's family fled to as part of the , settling there as (mainlanders). This displacement marked a period of adaptation in post-war , where resources remained scarce, but it allowed Ting to begin formal around age 13, starting in the and continuing through . His early exposure to scholarly discussions at his parents' universities and personal reading habits deepened his passion for , laying the groundwork for his later academic pursuits.

Academic Training

Ting moved to the in 1956 at the age of 20, enrolling at the in Ann Arbor to pursue in and . Despite his limited formal schooling prior to arrival—having completed only six years of high school in amid wartime disruptions and family relocations—he quickly adapted and demonstrated exceptional aptitude. His family's emphasis on education, influenced by his parents' academic pursuits, played a key role in motivating his determination to succeed in this new environment. At the , Ting completed his undergraduate studies remarkably efficiently, earning Bachelor of Science in Engineering (B.S.E.) degrees in both physics and in 1959. He continued seamlessly into graduate work, obtaining a (M.S.) in physics in 1960 before culminating his doctoral studies with a Ph.D. in physics in 1962. This accelerated timeline—spanning just six years for all degrees—reflected his intensive focus and the supportive academic resources available, contrasting sharply with the resource constraints he had faced earlier in life. Following his Ph.D., Ting undertook postdoctoral research as a Fellow at the in from 1962 to 1965. There, he collaborated with physicist Cocconi at the , gaining early exposure to cutting-edge high-energy through experiments on proton-proton collisions that probed fundamental properties of subatomic particles. This period at provided crucial influences and technical expertise in accelerator-based research, solidifying his foundation in experimental before transitioning to faculty positions.

Professional Career

Early Research Positions

Following his Ph.D. in physics from the in 1962, where his thesis focused on experiments, Samuel C. C. Ting began his postdoctoral career as a Fellow at from 1962 to 1965. There, he collaborated with Giuseppe Cocconi at the , conducting experiments on high-energy proton-proton collisions to study particle interactions and scattering processes. These efforts honed Ting's expertise in high-energy beams and precision scattering measurements, contributing to early validations of (QED) in hadron environments. In 1965, Ting returned to the United States as an instructor and was promoted to assistant professor at Columbia University, where he held the position from spring 1965 to 1967. At Columbia, he led the development of advanced detectors for electron-positron pair production studies, including a key collaboration with Leon M. Lederman on an experiment at Brookhaven National Laboratory that successfully observed the first antideuteron—a bound state of an antiproton and antineutron—in proton-beryllium collisions. This work utilized innovative magnetic spectrometers and scintillation counters to achieve high-resolution identification of rare antimatter events, establishing Ting's reputation for detector design in electron-positron collider applications. Additionally, Ting's group repeated a QED test at DESY in Germany, confirming the validity of QED processes in γ + anything → e⁺ + e⁻ + anything reactions and quantifying contributions from the ρ vector meson. By 1967, Ting joined as an associate professor, where he expanded his research to , leading teams on large-scale collision experiments using the Alternating Gradient (AGS). These early efforts focused on precision measurements of particle lifetimes and interaction cross-sections, such as pair production yields in proton-nucleus collisions, which provided critical data on electromagnetic processes at high energies. Through international collaborations, including with European and U.S. accelerator teams, Ting refined experimental techniques for detecting short-lived particles, laying the groundwork for his later breakthroughs in . He was promoted to full professor at in 1969.

MIT Professorship and Leadership

In 1977, Samuel C. C. Ting was appointed the first Thomas Dudley Cabot Professor of Physics at the (MIT), a position he has held since, recognizing his contributions to experimental . Ting has provided significant leadership within MIT's Laboratory for Nuclear Science (LNS), particularly as leader of the Electromagnetic Interactions Group, where he has directed efforts in experiments emphasizing international collaborations. The AMS project, coordinated through LNS under his oversight, exemplifies this focus, involving physicists from multiple nations working on high-energy cosmic ray detection. In 1995, Ting proposed and founded the Alpha Magnetic Spectrometer (AMS) experiment, serving as its and coordinating a collaboration of approximately 600 scientists from over 60 institutions across 16 countries. Through this role, he has directed groups at , managing the integration of contributions from Europe, Asia, and the . Ting's administrative contributions include securing sustained funding for , a space-based experiment initially supported by and the Department of Energy, with ongoing operations extended through international partnerships beyond 2025. In June 2025, an upgrade to enhance sensitivity to passed qualification tests, ensuring continued viability on the . His efforts have ensured the project's viability on the , fostering interdisciplinary oversight and resource allocation for large-scale research.

Scientific Discoveries and Projects

J/ψ Particle Discovery

In 1974, Samuel C. C. Ting led the MIT- (MIT-BNL) collaboration in an experiment at the Alternating Gradient Synchrotron (AGS) at (BNL) to search for new heavy particles through high-energy proton interactions. The setup involved directing a beam of protons at 28.3 GeV onto a target, utilizing a large-aperture superconducting spectrometer designed to detect electron-positron (e⁺e⁻) pairs with high precision and efficiency under intense beam conditions. This detector, developed over preceding years, incorporated lead-glass counters and proportional chambers to identify and measure the of dileptons produced in the collisions. On November 10-11, 1974, the team observed a narrow in the e⁺e⁻ spectrum, corresponding to a new particle they named the "J" particle, with a of approximately 3.1 GeV/c² and a width less than 5 MeV. This detection arose from the reaction p + Be → e⁺ + e⁻ + X, where the excess yield of pairs at this mass indicated a short-lived decaying electromagnetically into leptons. The result was published promptly in , confirming the particle's existence with very high statistical significance, based on ~17 observed events over an estimated background of ~0.35. The J particle's properties aligned with theoretical predictions for a state, specifically a of a and its antiquark (c\bar{c}), resolving longstanding puzzles in the by providing direct evidence for the fourth flavor proposed by , John Iliopoulos, and Luciano Maiani in 1970. Independently, led the SLAC-LBL collaboration at the electron-positron collider at Stanford Linear Accelerator Center, observing the same resonance (named ψ) in e⁺e⁻ annihilation events around the same time, leading to the unified identification as the J/ψ meson and their shared 1976 .

Alpha Magnetic Spectrometer Development

In 1994, Samuel Ting proposed the Alpha Magnetic Spectrometer (AMS) to as a detector to search for and by measuring cosmic rays from aboard the . The project aimed to extend experiments beyond Earth's atmosphere, leveraging space-based observations to detect rare cosmic phenomena that ground-based detectors could not access. Ting, as from , coordinated the initial design to meet NASA's stringent safety and performance requirements for missions. The AMS project evolved from its original shuttle-based configuration to the enhanced version intended for long-term deployment on the (ISS). A precursor flight, , launched successfully on Discovery's mission in June 1998, validating key technologies and gathering initial data over 10 days. Following this demonstration, and the Department of Energy approved the full development for ISS integration in , enabling multi-year observations with greater precision and data volume. Under Ting's leadership at , an collaboration of over 600 scientists from 16 nations constructed the instrument, incorporating advanced engineering to ensure reliability in space. The AMS-02 detector is a 7.5-ton module measuring approximately 5 meters by 4 meters by 3 meters, featuring a cryogenic producing a 0.14 field to bend charged particle trajectories. Its core components include a silicon tracker for precise measurement, a time-of-flight for determination, a ring imaging for particle identification, and an electromagnetic to assess energy and distinguish electrons from hadrons. These elements, supported by over 300,000 electronic channels and 650 onboard processors, enable high-resolution detection of cosmic rays across a wide energy range. AMS-02 launched on May 16, 2011, aboard Space Shuttle Endeavour's STS-134 mission and was installed on the ISS's Zenith module, where it began operations shortly thereafter. The detector faces significant operational challenges in the space environment, including exposure to high levels of cosmic and solar radiation that can degrade components over time, necessitating robust shielding and redundant systems. Data acquisition generates an internal rate of 7 gigabits per second from up to 2,000 cosmic ray events per second, which onboard processing reduces to a transmittable 2 megabits per second via the ISS's communication links—equivalent to roughly 20 gigabytes per day after compression. As of November 2025, AMS-02 has collected over 250 billion cosmic ray events during more than 14 years of operation on the ISS.

Broader Research Contributions

Particle Physics Experiments

Samuel C. C. Ting made significant contributions to the development of high-precision detectors for experiments at terrestrial accelerators, emphasizing technologies that enabled detailed studies of particle interactions. In the late and early , Ting led the design and construction of advanced spectrometers at facilities like in and in the United States. These included large double-arm spectrometers equipped with superconducting magnets, which provided magnetic fields for precise momentum measurements, and multiwire proportional chambers featuring thousands of gold-plated wires for high-resolution tracking. Such detectors achieved mass resolutions as fine as ±5 MeV and large acceptance angles, allowing for the identification of electrons, , and hadrons with rejection rates exceeding 10^8 against background particles. These innovations were applied across multiple accelerators, including DESY's electron-positron storage rings and Brookhaven's proton synchrotrons, facilitating experiments on high-energy interactions and decays to probe at distances around 10^{-14} cm. A key aspect of Ting's work involved technology, which he pioneered for particle detectors in the 1970s. At , Ting's group constructed a 4π superconducting magnet detector capable of handling intense fluxes up to 10^{11} per second, integrated with Cherenkov counters and lead-glass shower counters for particle identification. This setup minimized systematic errors in measuring electromagnetic processes, such as electron-positron in multi-GeV photon collisions. The superconducting solenoids provided uniform magnetic fields essential for tracking charged particles, influencing subsequent detector designs by demonstrating the feasibility of cryogenically cooled magnets in high-radiation environments. Ting's emphasis on precision extended to identification systems, incorporating drift chambers and scintillators to distinguish muons from hadronic backgrounds with efficiencies over 99%. These components were crucial for experiments requiring clean samples, as seen in his group's work at Brookhaven using focused proton beams with intensities up to 10^{12} protons per second. Ting's experiments on weak interactions focused on terrestrial accelerator-based probes of electroweak unification, particularly through electron-positron annihilation processes. As spokesperson for the L3 collaboration at CERN's Large Electron-Positron (LEP) collider from 1982 to 2003, he oversaw measurements that tested the Glashow-Weinberg-Salam model by analyzing Z boson decays. The L3 detector, under Ting's leadership, featured a massive superconducting solenoid producing a 0.5 Tesla field, surrounding a central tracker, a high-resolution bismuth germanate (BGO) electromagnetic calorimeter, and muon chambers with iron absorbers for precise muon identification. These allowed for energy resolutions of approximately 1.4% at 45 GeV for electrons and photons, enabling detailed studies of lepton asymmetries. One notable result was the precision measurement of the forward-backward asymmetry in muon production, which confirmed the parity-violating nature of weak neutral currents predicted by the model, with values consistent with sin²θ_W ≈ 0.232 at the Z pole. Such findings provided empirical validation of the electroweak unification, constraining the number of neutrino species to three and verifying the standard model's predictions for weak interaction couplings. Ting's influence on and detector design stemmed from his advocacy for superconducting technologies and international collaborations. His early adoption of superconducting magnets at in the 1970s predated their widespread use and informed the engineering choices for LEP's experiments, where L3's 12,000-ton detector exemplified scalable cryogenic systems for large-scale facilities. By leading a 16-nation effort for L3, Ting contributed to optimizing LEP's operational parameters, such as energies up to 209 GeV, to maximize electroweak . His work on focusing and techniques at Brookhaven—achieving spot sizes of 3 × 6 mm² without collimators—also influenced designs by highlighting the benefits of high-intensity, low-emittance s for experiments. These advancements not only enhanced the capabilities of LEP but also set precedents for future s, emphasizing modular, high- detectors integrated with advanced magnets.

Cosmic Ray and Antimatter Investigations

The Alpha Magnetic Spectrometer (AMS-02), under the leadership of Samuel C. C. Ting, has provided pivotal measurements of positrons and electrons, revealing an excess of positrons in primary cosmic rays. In 2013, AMS-02 reported the positron fraction—the ratio of positron to the combined positron and electron —in the energy range from 0.5 to 350 GeV, based on over 10 million events, showing a steady increase with energy and an excess above 10 GeV that rises to about 250 GeV. This excess, isotropic within 3% and not attributable to a single nearby source, has been interpreted by subsequent analyses as potentially originating from wind nebulae, which accelerate electrons and positrons to high energies through astrophysical processes. These findings challenged standard cosmic ray propagation models and opened avenues for probing nearby astrophysical accelerators. AMS-02's investigations into extended to precise measurements of fluxes and light nuclei, shedding light on the scarcity of in the . The 2016 analysis of the -to-proton flux ratio, derived from 1.9 million events in the rigidity range of 1 to 400 GV, showed no significant excess beyond expectations from secondary production in interactions of s with interstellar gas, indicating the absence of large-scale domains such as galaxies. Concurrently, measurements of proton and fluxes highlighted anomalies in their spectral indices; the proton flux from 1 GV to 1.8 TV, based on 300 million events, and the flux from 1.9 GV to 3 TV, from 50 million events, revealed a harder spectrum compared to protons, with the proton-to- ratio decreasing at rigidities above 200 GV, suggesting contributions from a distinct population of sources or modified propagation effects. As of November 2025, AMS-02 has collected over 257 billion events since its 2011 deployment on the , spanning more than 14 years of operation and covering a full plus additional years. These results have yielded updated insights into solar influences and subtle spectral features. A 2025 analysis over the first 11-year measured and fluxes in the rigidity range from 1 to 41.9 GV using 1.1 million events, uncovering fine time structures and charge-sign dependent modulations in the solar particle environment that reveal new dynamics in transport near . The extended survey also identified potential anomalies in high-energy spectra, including hints of annihilation signals in and excesses, though astrophysical explanations remain viable and require further discrimination. These observations, analyzed through advanced modeling of solar modulation, enhance our understanding of local behavior. The collective AMS-02 data on cosmic rays and antimatter carry profound implications for cosmology, particularly the matter-antimatter asymmetry arising from the Big Bang. The negligible antiproton fluxes, consistent across measurements, affirm a universe dominated by matter with no evidence for primordial antimatter regions, aligning with the observed baryon asymmetry parameter η ≈ 6 × 10^{-10} and supporting mechanisms like CP violation in the early universe. By quantifying fluxes of 10 billion to hundreds of billions of cosmic rays, these studies delineate the universe's composition, constraining dark matter models while emphasizing astrophysical origins for observed anomalies, and underscoring the need for continued high-precision space-based detection to resolve open questions in particle astrophysics.

Awards and Honors

Nobel Prize and Early Recognitions

In 1976, Samuel C. C. Ting was awarded the , shared equally with , for their independent discoveries of the J/ψ particle—a new heavy that provided experimental confirmation of the existence of the charm quark, a key component of the of . The Royal Swedish Academy of Sciences announced the prize on October 15, 1976, recognizing the profound impact of this breakthrough on understanding the strong nuclear force and subatomic structure. The Nobel ceremony took place on December 10, 1976, in , where Ting delivered his banquet speech in , the first such address in a non-European language at the event, underscoring his . In the speech, he emphasized the essential role of international collaboration, crediting the contributions of young scientists from diverse nations who worked on the experiment at . Prior to receiving the , Ting was honored with the in 1975 by the U.S. Department of Energy for his pioneering experimental techniques in , which extended the validation of and advanced high-energy collision studies. This accolade highlighted his early innovations in detector technology and , pivotal to the J/ψ .

Recent and Lifetime Achievements

Samuel C. C. Ting's career-spanning impact in and research has been recognized through numerous prestigious memberships in leading scientific academies. He was elected to the in 1977, affirming his early contributions to experimental physics. In 1994, he became a foreign member of the , highlighting his influence on international collaborations in high-energy physics. Ting has received more than 20 honorary degrees from distinguished institutions worldwide, reflecting his enduring legacy in advancing fundamental science. Notable among these is the honoris causa from the in 1978, his , in recognition of his groundbreaking experimental work. Other examples include honorary doctorates from in 1990 and the Hong Kong University of Science and Technology in 2005. His leadership in the Alpha Magnetic Spectrometer (AMS) project on the earned him the Public Service Medal in 2001, honoring his role in developing this landmark instrument for and detection. Building on this, Ting received 's Award for Compelling Results in Physical Sciences in 2017 for the AMS's precise measurements of positrons and electrons, which provided key insights into and cosmic phenomena. In 2023, he received the Homi Bhabha Medal and Prize from the International Union of Pure and (IUPAP) for his vision and of the experiment. In 2025, Ting was awarded the Basic Lifetime Achievement Award by the International Congress of Basic , celebrating his discovery of the J/ψ particle and lifelong in the experiment, which have profoundly shaped our understanding of the universe's fundamental structure. These honors build upon his foundational 1976 , underscoring a lifetime of transformative contributions to .

Personal Life

Family and Relationships

Samuel C. C. Ting's family placed a strong emphasis on , influenced by his parents' academic backgrounds as graduate students at the —his father in engineering and his mother in psychology—both of whom prioritized scholarly pursuits despite their own challenging upbringings in . This value shaped Ting's upbringing after the family relocated from to in 1949 amid political turmoil, and later supported his return to the in 1956 to attend the , where his parents provided initial financial assistance for the move. Ting's first marriage was to Kay Louise Kuhne, an architect, in 1960, with whom he had two daughters, Jeanne and Amy; the marriage ended in divorce. In 1985, he married Dr. Susan Carol Marks, an educator, and they had one son, Christopher, born in 1986. Throughout Ting's career transitions, including stints at in from 1963 to 1965 and subsequent positions at and , his family provided essential support by relocating with him and maintaining a focus on academic achievement, reflecting the enduring family commitment to .

Interests and Philanthropy

Beyond his groundbreaking work in , Samuel C. C. Ting has dedicated significant efforts to and the mentorship of young scientists, particularly in . Through the Alpha Magnetic Spectrometer (AMS) experiment on the , which he leads, Ting has trained numerous Chinese physicists, many of whom have risen to leadership roles in their fields back home. This international collaboration has fostered technical expertise and experimental skills among emerging researchers, emphasizing hands-on involvement in large-scale projects. Ting's commitment to education extends to initiating the Shandong Institute of Advanced Technology (SDIAT) in , , proposed by him in 2019 to advance research in high-energy physics, , and detection. As a key figure in its establishment, the institute serves as a hub for training and innovation, aligning with his vision of building scientific capacity in developing regions. He has also delivered numerous lectures to young scientists in since the early 2000s, including talks at in 2009, the University of Science and Technology of in 2016, in 2019, and the Greater Bay Area Science Forum in in 2023, where he shared insights on research and experimental methodologies. In speeches and interviews, Ting has advocated strongly for enhanced scientific cooperation, particularly between the and , arguing that joint projects like and potential future colliders in would accelerate discoveries and the next generation of physicists. He has highlighted how such partnerships have already benefited by shifting global talent and resources toward collaborative efforts, countering declines in U.S. high-energy physics funding. Ting often advises young researchers to pursue their deepest passions relentlessly, drawing from his own journey despite initial family reservations about a scientific career.

Publications

Key Solo and Lead-Authored Works

Samuel C. C. Ting's Ph.D. thesis work, completed at the in 1962, focused on high-energy pion-proton experiments conducted using the Alternating Gradient at . This research culminated in a lead-authored detailing diffraction measurements at beam momenta of 3, 4, and 5 GeV/c, providing early insights into dynamics at intermediate energies. The study demonstrated the applicability of optical theorem approximations to pion-proton interactions and contributed foundational data for understanding cross-sections. Ting's most seminal lead-authored work came in 1974, when he headed the experimental team at Brookhaven that observed a narrow in electron-positron pairs from proton-beryllium collisions, announcing the discovery of the J particle (later identified as the J/ψ meson). The paper, titled "Experimental Observation of a Heavy Particle J," reported a particle with approximately 3.1 GeV/c² and negligible width, observed in the p + Be → e⁺ + e⁻ + anything, with a production cross-section indicating a new heavy state. This breakthrough, involving 20 co-authors under Ting's leadership, provided direct evidence for quarks and earned him the 1976 . The experiment's design emphasized high-precision electron identification using a novel lead-glass array, achieving a of about 3.7% at 3 GeV. Ting's leadership in space-based particle detection is exemplified by his proposal for the Alpha Magnetic Spectrometer (AMS), detailed in the 2002 Physics Reports article "The Alpha Magnetic Spectrometer (AMS) on the International Space Station" (Alcaraz et al.), where Ting as principal investigator contributed to outlining the detector's design and scientific objectives for antimatter and dark matter searches aboard the International Space Station. The description covered AMS's superconducting magnet, silicon tracker, and time-of-flight system, projecting sensitivity to cosmic-ray positrons up to 300 GeV and antiprotons to 10 TeV. This collaborative proposal paper emphasized the instrument's 0.14 m² sr acceptance and redundancy for long-duration operation, paving the way for AMS's 2011 deployment. Collaborative AMS data analyses have since built on this framework to report precise cosmic-ray spectra.

Collaborative and Review Articles

Samuel C. C. Ting has co-authored hundreds of scientific publications, with a significant portion arising from large-scale international collaborations, including the L3 experiment at CERN's Large Electron-Positron Collider (LEP) and the experiment on the (ISS). These efforts underscore his role in coordinating multidisciplinary teams from over 16 nations, focusing on high-energy and detection. An early exemplar of Ting's collaborative research is the 1974 announcement of the J/ψ particle discovery by his team at , involving dozens of physicists and marking the confirmation of the . In the 1990s, as spokesperson for the L3 collaboration at , Ting oversaw numerous co-authored papers on production and decays, such as measurements of splitting into charmed quarks in hadronic Z decays, which provided key tests of (QCD) predictions for heavy quark fragmentation. These studies, based on LEP data, quantified the probability of -to-charm transitions with high precision, contributing to the understanding of charm processes. A pivotal collaborative achievement came in 2013 with the AMS experiment's publication in Physical Review Letters, "Precision Measurement of the Positron Fraction in Primary Cosmic Rays of 0.5–350 GeV," co-authored by over 100 members of the AMS collaboration under Ting's leadership as . This paper reported the first high-statistics measurement of the fraction in up to 350 GeV, revealing an excess of positrons at energies above 10 GeV that deviates from standard astrophysical models and hints at potential new physics, such as annihilation. The analysis utilized 6.8 billion events collected during the first 18 months of AMS operations on the ISS, demonstrating the detector's unprecedented precision in distinguishing positrons from electrons. In 2025, the collaboration, again with Ting as spokesperson, published "Antiprotons and Elementary Particles over a " in , presenting an 11-year survey of fluxes based on 1.1 million events in the rigidity range of 1.00 to 41.9 GV. This work detailed variations in antiparticle fluxes correlated with solar activity, identifying anomalies in antiproton-to-proton ratios near that suggest influences from solar particle events and interplanetary propagation effects, providing new constraints on origin and acceleration mechanisms. The measurements, spanning from May 2011 to December 2022, highlight the experiment's ability to resolve solar modulation impacts on spectra. Ting has also co-authored influential review articles synthesizing collaborative findings. In the 2002 Physics Reports, the AMS collaboration's comprehensive overview, "The Alpha Magnetic Spectrometer () on the International Space Station," detailed the experiment's instrumentation, calibration, and early results on cosmic ray antimatter components, including positron and antiproton fluxes, while discussing implications for dark matter searches and astrophysical models. This 75-page synthesis, drawing on data from billions of cosmic ray events, serves as a foundational reference for antimatter studies in space-based .

References

  1. [1]
    Samuel C.C. Ting – Biographical - NobelPrize.org
    I was born on 27 January 1936 in Ann Arbor, Michigan, the first of three children of Kuan Hai Ting, a professor of engineering, and Tsun-Ying Wang, a professor ...
  2. [2]
    Samuel C.C. Ting - MIT Physics
    Proposed, constructed and leads the Alpha Magnetic Spectrometer (AMS) ... Professor Ting poses in front of the Space Shuttle Endeavor before it launches with AMS-.
  3. [3]
    Samuel C. C. Ting | The Alpha Magnetic Spectrometer Experiment
    Samuel Ting was born in Ann Arbor, Michigan. Shortly after, his parents, who were both graduate students at the University of Michigan, took him to China.
  4. [4]
    Samuel C. C. Ting – NAS - National Academy of Sciences
    I am the founder and Principal Investigator of the Alpha Magnetic Spectrometer (AMS) deployed on the International Space Station in 2011. AMS is a multi-purpose ...
  5. [5]
    2024 APS April Meeting - Event - Latest Results from the Alpha ...
    Apr 4, 2024 · Presenter: Samuel C Ting (MIT). Author: Samuel C Ting (MIT). In twelve years on the International Space Station, AMS has collected more than ...Missing: CC | Show results with:CC
  6. [6]
    Samuel Ting awarded Bhabha Award for AMS work - MIT Physics
    Aug 2, 2023 · Proposed and developed by Ting, AMS is a unique precision magnetic spectrometer in space. Since its launch in May 2011, AMS has furthered our ...<|control11|><|separator|>
  7. [7]
    Samuel C.C. Ting - InfiniteMIT
    TING: I was born in the University of Michigan hospital, where both my parents were graduate students. My father studied civil engineering. My mother studied ...
  8. [8]
    The Chinese Experience . Samuel C.C. Ting Eyewitness - PBS
    SAMUEL TING: I was born in Michigan and then returned to China a few months after I was born. My parents were rather patriotic types. At that time, the war ...Missing: occupation | Show results with:occupation
  9. [9]
    Q&A with Samuel Ting - Michigan Engineering News
    Feb 28, 2018 · Samuel C.C. Ting received the Nobel Prize in 1976, with Burton Richter, for discovering the subatomic J/ψ particle.Missing: biography | Show results with:biography
  10. [10]
    Research Profile - Samuel Ting | Lindau Mediatheque
    His father, Kuan-hai Ting, was professor of engineering, and his mother, Tsun-Ying Wang, was a professor of psychology. After having spent his youth in China, ...Missing: childhood | Show results with:childhood
  11. [11]
    [PDF] Samuel C. C. Ting - Nobel Lecture
    In the last decade, with the construction of giant electron accelerators, with the development of sophisticated detectors for distinguishing electrons from.Missing: PhD thesis topic
  12. [12]
    Michigan Great Samuel C. C. Ting: Nobel Laureate physicist has ...
    May 24, 1999 · 27, 1936. Ting's parents, scholars in their own right, were both graduate students at the University in early 1936. The couple planned to return ...Missing: background | Show results with:background
  13. [13]
    Physicists Produce Antimatter Particles In a Complex Form ...
    ... , and Samuel Ting, 29, instructor in physics, from Taiwan. They are engaged in research at Columbia and at Brookhaven National Laboratory, Upton, L. I..
  14. [14]
    Columbia Physicists Discover First Anti – Deuteron Particle ...
    Columbia Physicists Discover First Anti - Deuteron Particle. By Joseph Wihnyk. Leon M. Lederman and Samuel C. Ting, two Columbia physicists, have discovered ...
  15. [15]
    Ting, S. C. C. (Samuel Chao-chung), 1936-
    His research efforts are devoted to the physics of electron or muon pairs, investigating quantum electrodynamics, production and decay of photon-like particles, ...
  16. [16]
    MIT, Massachusetts Institute of Technology - AMS-02
    The Electromagnetic Interactions Group (EMI) of the Laboratory for Nuclear Science at MIT is led by Nobel Laureate Professor Samuel Ting.<|control11|><|separator|>
  17. [17]
    LNS: Lab for Nuclear Science - MIT Offices & Services Directory
    Group Leader, Samuel Ting · 26-306A, 617-253-8326. Administrative Assistant 2, Christine Titus · 26-147, 617-253-8326. Hadronic Physics Group. Group Leader ...
  18. [18]
    [PDF] 400 km) above the Earth, the Alpha Magnetic Spectrometer (AMS ...
    States) under the leadership of Nobel Laureate Samuel Ting of M.I.T. The ... AMS project is coordinated by the Laboratory for Nuclear Science at MIT under the.
  19. [19]
    Long-Awaited Cosmic-Ray Detector May Be Shelved
    Apr 3, 2007 · When Samuel Ting, the Nobel Prize-winning particle physicist, proposed back in 1995 to use the International Space Station to plumb the ...Missing: principal | Show results with:principal
  20. [20]
    [PDF] The Alpha Magnetic Spectrometer Experiment (AMS) - INFN – Pisa
    16 Countries, 56 Institutes, 500 Physicists. ~ 95% of AMS is constructed in Europe and Asia. Page 4. Italian National participation in AMS-02 y97637_1ba.ppt.<|control11|><|separator|>
  21. [21]
    Alpha Magnetic Spectrometer (AMS): How It Works - NASA
    Apr 2, 2013 · Led by Principle Investigator and Spokesperson Samuel Ting of the Massachusetts Institute of Technology, the AMS team includes some 600 ...
  22. [22]
    [PDF] “AMS Days at CERN” and Latest Results from the AMS Experiment ...
    Apr 15, 2015 · Samuel Ting of MIT and CERN. ... The AMS project is coordinated by the Laboratory for Nuclear Science at MIT under the leadership of Professor R.
  23. [23]
    Samuel C.C. Ting – Nobel Lecture - NobelPrize.org
    Nobel Lecture, December 11, 1976. The Discovery of the J Particle: A Personal Recollection. Read the Nobel Lecture Pdf 1.55 MB.
  24. [24]
    Experimental Observation of a Heavy Particle | Phys. Rev. Lett.
    We report the observation of a heavy particle J, with mass m = 3 . 1 GeV and width approximately zero. The observation was made from the reaction p + B e → e + ...
  25. [25]
    Ting to direct space-station experiment | MIT News
    Sep 27, 1995 · NASA and the Department of Energy (DOE) signed an agreement September 20 to conduct the experiment and have the research team led by Dr. Ting, ...
  26. [26]
    Alpha Magnetic Spectrometer - NASA
    The AMS is a high profile space-based particle physics experiment that is led by Nobel laureate Samuel Ting of the Massachusetts Institute of Technology (MIT).
  27. [27]
    ISS: AMS (Alpha Magnetic Spectrometer) - eoPortal
    Jun 7, 2012 · - Such criticism barely registers with the mission's leader, particle physicist Samuel Ting. The 79-year-old Nobel laureate has made a career of ...<|control11|><|separator|>
  28. [28]
    About AMS-02 - Alpha Magnetic Spectrometer - NASA
    May 16, 2011 · Magnetic Field Intensity. 0.14 T. Weight. 7.5 t. Size. 5x4x3 m. The Alpha Magnetic Spectrometer (AMS) is a state-of-the-art particle physics ...Missing: ton | Show results with:ton
  29. [29]
    The Electronics | The Alpha Magnetic Spectrometer Experiment
    The 300,000 channels produce 3.7 Mbit of data for each event. Events are collected at up to 2 kHz resulting in a data rate of 7 Gbit/s. This is processed by ...Missing: GB/ | Show results with:GB/
  30. [30]
    Operations of the thermal control system for Alpha Magnetic ...
    Dec 11, 2014 · The dimensions of AMS is about 3m×3m×3m, with weight of about 7 tons. On a spacecraft, the ram side faces to the velocity vector, the wake ...<|control11|><|separator|>
  31. [31]
    [PDF] Results from the L3 Experiment at LEP - CERN-PPE/93-31
    Feb 22, 1993 · The L3 detector shown in figure 2.1 is designed to study ete collisions up to 200 GeV with emphasis on high resolution energy measurements of ...
  32. [32]
    https://www.sciencedirect.com/science/article/abs/pii/S0168900214009309
  33. [33]
    https://cds.cern.ch/record/246903/files/ppe-93-031.pdf
  34. [34]
    https://doi.org/10.1103/PhysRevLett.110.141102
  35. [35]
    https://doi.org/10.1103/PhysRevLett.117.091103
  36. [36]
    Press release: The 1976 Nobel Prize in Physics - NobelPrize.org
    The Royal Swedish Academy of Sciences has decided to award the 1976 Nobel Prize for physics to be shared equally between Professor Burton Richter, Stanford ...Missing: charm | Show results with:charm
  37. [37]
    Samuel C.C. Ting – Facts - NobelPrize.org
    Samuel Ting and Burton Richter, independently of each other, discovered a new heavy particle, known as J/psi, proving experimentally the existence of a fourth ...Missing: announcement | Show results with:announcement
  38. [38]
    Samuel C.C. Ting – Banquet speech - NobelPrize.org
    Samuel CC Ting's speech at the Nobel Banquet, December 10, 1976 (Translation) Your Majesties, Your Royal Highnesses, Ladies and Gentlemen, Professor Burton ...
  39. [39]
    LAWRENCE Samuel C. Ting, 1975 | U.S. DOE Office of Science (SC)
    Samuel C. Ting, 1975, Physics: For powerful new experimental techniques that have extended the range of validity quantum electrodynamics.
  40. [40]
    Samuel C.C. Ting, '59, MS'60, PhD'63, HSCD'78
    TING, '59, MS'60, PhD'63, SCD'78, was born in Ann Arbor while his parents were visiting from China. When he moved to the U.S. to attend U-M at age 20, Ting ...Missing: 1977 Oxford 2010
  41. [41]
    Ting Receives 2025 Basic Science Lifetime Award - MIT Physics
    Apr 15, 2025 · Prof. Samuel CC Ting is among six globally acclaimed scientists who will receive a 2025 Basic Science Lifetime Award at July's 2025 International Congress of ...
  42. [42]
    Samuel Chao Chung Ting | Encyclopedia.com
    His parents, Kuan Hai Ting, an engineering professor, and Tsun-Ying Wang, a psychology professor, were graduate students at the University of Michigan; while ...Missing: background | Show results with:background
  43. [43]
    Samuel Chao Chung Ting - The New York Times
    Oct 19, 1976 · He spent his childhood in mainland China and his teen‐age years on Taiwan where his father is a professor at the National Taiwan University.
  44. [44]
    The Only Thing Important Is Physics
    Aug 17, 2023 · Ting's L3 experiment immediately after my graduation from college. It was the first research I ever conducted, and he has been my mentor ...
  45. [45]
    About SDIAT - Shandong Institute of Advanced Technology
    Shandong Institute of Advanced Technology Introduction. Beginning as a proposal initiated by Nobel Laureate Prof. Samuel C.C. Ting, SDIAT officially started ...
  46. [46]
    Nobel Prize Winner Prof. Samuel C.C. Ting visited SEU
    Samuel C.C. Ting's current visit includes giving a comprehensive introduction on the latest developments of AMS research. interviewing some students ...
  47. [47]
    Welcome - University of Science and Technology of China
    On March 5th, 2016, Nobel Laureate physicist Samuel C. C. Ting (Chinese name: DING Zhaozhong) visited USTC and gave an interesting talk about "The Latest ...Missing: speech | Show results with:speech
  48. [48]
    Prof. Samuel C.C. Ting Bestowed Honorary Dean of Institute for ...
    Jul 4, 2019 · Prof. Samuel C.C. Ting Bestowed Honorary Dean of Institute for Advanced Technology, SDU. Updated: July 4, 2019.
  49. [49]
    Nobel Prize Winner Samuel Ting Discusses Global Cooperation in ...
    May 24, 2023 · Samuel Ting is a world renowned Chinese-American physicist, who received the Nobel Prize for physics in 1976. He was in Guangzhou City, ...Missing: speech December<|separator|>
  50. [50]
    Pion-Proton Elastic Diffraction Scattering at 3, 4, and 5 GeV/c
    Pion-Proton Elastic Diffraction Scattering at 3, 4, and 5 GeV/c · C. C. Ting, L. W. Jones, and M. L. Perl · Phys. Rev. Lett. 9, 468 – Published 1 December 1962.Missing: Samuel PhD electron
  51. [51]
    Samuel C C Ting's research works | Massachusetts Institute of ...
    The latest DAMPE results are presented alongside published works of CREAM [15], PAMELA [16], NUCLEON [17], CALET [18] and AMS-02 [19] experiments. [15] ...
  52. [52]
    [PDF] Measurement of the Probability of Gluon Splitting into Charmed ...
    Nov 2, 1997 · Charmed Quarks in Hadronic Z Decays. The L3 Collaboration. Abstract. We have measured the probability, ng→c¯c, of a gluon splitting into a charm ...
  53. [53]
    Precision Measurement of the Positron Fraction in Primary Cosmic ...
    Apr 3, 2013 · The positron fraction, that is, the ratio of the positron flux to the combined flux of positrons and electrons, is presented in this Letter in ...
  54. [54]
    AMS experiment measures antimatter excess in space - CERN
    Apr 3, 2013 · The results, presented by AMS spokesperson Professor Samuel Ting in a seminar at CERN [see video], are to be published in the journal Physical ...Missing: scattering | Show results with:scattering
  55. [55]
    Antiprotons and Elementary Particles over a Solar Cycle
    Feb 3, 2025 · Over 2.0 × 10 11 cosmic-ray events have been recorded in the first 11 years of AMS operations. In the rigidity range from 1.00 to 41.9 GV, we ...
  56. [56]
    Most detailed survey of particles around the sun reveals new mysteries
    Feb 3, 2025 · An 11-year-long survey of the particles and antiparticles near our sun is unlocking our solar system's history – and raising new mysteries about the particles ...Missing: 02 | Show results with:02