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Paul Ching Wu Chu (Chinese: 朱經武; born December 2, 1941) is a Taiwanese-American physicist specializing in superconductivity, magnetism, and dielectrics. He is a professor of physics and T.L.L. Temple Chair of Science in the Physics Department at the University of Houston College of Natural Sciences and Mathematics. He was the president of the Hong Kong University of Science and Technology from 2001 to 2009. In 1987, he was one of the first scientists to demonstrate high-temperature superconductivity.

Key Information

Early life and education

[edit]

Chu was born in Changsha, Hunan, Republic of China in 1941. Chu's family was from Taishan, Guangdong. Chu spent his childhood in Taiwan.[1][2]

In 1958, Chu graduated from Taichung Municipal Cingshuei Senior High School. He then earned a Bachelor of Science (B.S.) from National Cheng Kung University in 1962, a Master of Science (M.S.) from Fordham University in 1965, and his Ph.D. from the University of California, San Diego, in 1968.[3]

Career

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After two years of performing industrial research with Bell Laboratories at Murray Hill, New Jersey, Chu was appointed assistant professor of physics at Cleveland State University in 1970. He was subsequently promoted to associate professor and professor of physics in 1973 and 1975, respectively.

In 1979, Chu became a professor of physics at the University of Houston, an appointment he still holds. In 1987, he and Maw-Kuen Wu announced the historic discovery of superconductivity above 77 K in YBCO,[4] touching off a frenzy of scientific excitement exemplified by the Woodstock of physics, at which he was a featured presenter.[5] He was then appointed the director of the Texas Center for Superconductivity. Chu has served as the T.L.L. Temple Chair of Science at the same university since 1987. He also has served as a consultant and visiting staff member at Bell Laboratories, Los Alamos Scientific Laboratory, the Marshall Space Flight Center, Argonne National Laboratory and DuPont at various times.[6]

Chu has received numerous awards and honors for his outstanding work in superconductivity, including the National Medal of Science[7] and the Comstock Prize in Physics in 1988,[8] and the American Physical Society's International Prize for New Materials. He was an invited contributor to the White House National Millennium Time Capsule at the National Archives in 2000 and was selected the Best Researcher in the U.S. by U.S. News & World Report in 1990.

In 1989, Chu was elected a Fellow of the American Academy of Arts and Sciences.[9] He is a member of the National Academy of Sciences, Chinese Academy of Sciences (foreign member), Academia Sinica, Russian Academy of Engineering (RAE) and the Third World Academy of Sciences. His research activities extend beyond superconductivity to magnetism and dielectrics. [citation needed]

On November 17, 2014, an IEEE Milestone in Electrical Engineering and Computing plaque was presented to University of Houston for Chu and his team's 1987 discovery of high temperature superconductors.[10][11]

On September 1, 2001, Chu succeeded Professor Chia-Wei Woo as the president of The Hong Kong University of Science and Technology. Chu's tenure as university president ended officially on 1 September 2009.

On November 5, 2011, Chu was appointed as the founding President of the Taiwan Comprehensive University System (TCUS).[12]

Personal life

[edit]

He is married to May Chu, the daughter of Shiing-Shen Chern.[13]

Awards and honors

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  • Honorary Doctor of Science (Sc.D.) degree from Whittier College. (1991)[14]
  • 2014 IEEE Council on Superconductivity Max Swerdlow Award for Sustained Service to the Applied Superconductivity Community.[15]

Lectures

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  • 1991 – High temperature superconductivity: four years later Lecture sponsored by the Dept. of Electrical and Computer engineering, University of California, San Diego. Electrical and Computer Engineering Distinguished Lecture Series. Digital object made available by UC San Diego Library.

See also

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References

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Additional sources

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[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Paul Ching Wu Chu

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Paul Ching-Wu Chu (born December 2, 1941) is a Chinese-American physicist specializing in superconductivity, magnetism, and dielectrics, best known for leading the team that discovered superconductivity at 93 K in the YBa₂Cu₃O₇ compound in 1987, marking a breakthrough in high-temperature superconductivity operable with liquid nitrogen.[1][2] Born in Changsha, Hunan Province, China, Chu's family relocated to Taiwan in 1949 amid political upheaval; he earned his Bachelor of Science in physics from National Cheng Kung University in 1962, a Master of Science in physics from Fordham University in 1965, and a Ph.D. in physics from the University of California, San Diego, in 1968.[3][4] After conducting research at Bell Laboratories from 1968 to 1970 and serving as a professor at Cleveland State University until 1979, Chu joined the University of Houston in 1979, where he became Professor of Physics and T.L.L. Temple Chair of Science in 1987, while founding and directing the Texas Center for Superconductivity (TcSUH).[2][5] From 2001 to 2009, he also served as president of the Hong Kong University of Science and Technology.[6] Chu's research advanced the field by demonstrating stable superconductivity above the boiling point of liquid nitrogen (77 K), enabling practical applications without helium cooling; his 1987 discovery built on earlier cuprate work and spurred global efforts in materials science, while later achievements included superconductivity up to 164 K in mercury-based compounds under pressure in 1994. He continues to lead research at the Texas Center for Superconductivity, with recent work (as of 2025) advancing ambient-pressure high-temperature superconductors.[2][7] For these contributions, he received the National Medal of Science in 1988, the John Fritz Medal in 2001, and numerous other honors, including election to the National Academy of Sciences and the American Academy of Arts and Sciences.[6][2]

Early Life and Education

Early Life

Paul Ching Wu Chu was born on December 2, 1941, in Changsha, Hunan Province, Republic of China.[3] His early years coincided with the escalating Chinese Civil War between the Nationalist and Communist forces, which profoundly shaped his family's circumstances. In 1949, as the Nationalists retreated following their defeat on the mainland, Chu's family relocated to Taiwan to escape the political upheaval and establishment of the People's Republic of China.[8] This move, common among many Nationalist sympathizers, marked the beginning of Chu's adaptation to life on the island, where he navigated the challenges of postwar resettlement in a resource-scarce environment. In Taiwan, Chu's childhood fostered a budding curiosity in science, influenced by the era's emphasis on self-reliance and innovation amid limited resources. As a young boy in the early 1950s, he developed a fascination with electronics, spending time rebuilding crystal radio sets as a hobby.[4] He was particularly drawn to electric and magnetic phenomena, once constructing a radio from scratch, which highlighted his innate tinkering spirit.[9] These formative experiences, encouraged by the cultural value placed on academic excellence in math and science during Taiwan's developmental phase, sparked his lifelong pursuit of physics.

Education

Paul Ching Wu Chu earned his Bachelor of Science degree in physics from National Cheng Kung University in Tainan, Taiwan, in 1962.[10] After graduating, Chu served one year in the Nationalist Chinese Air Force before pursuing graduate studies in the United States.[11] He then obtained a Master of Science degree in physics from Fordham University in New York in 1965.[10] Chu completed his Doctor of Philosophy in physics at the University of California, San Diego, in 1968, where his doctoral research under advisor Bernd T. Matthias focused on low-temperature physics, specifically high-pressure effects on the superconductivity of transition metals and alloys.[10][12]

Professional Career

Early Positions

Following his PhD in physics from the University of California, San Diego in 1968, Paul Ching Wu Chu joined Bell Telephone Laboratories in Murray Hill, New Jersey, as a Member of the Technical Staff from 1968 to 1970. There, he engaged in industrial research focused on solid-state physics, including studies related to magnetism.[3][5] In 1970, Chu transitioned to academia, accepting an appointment as assistant professor of physics at Cleveland State University in Ohio, where he remained until 1979.[3] He was promoted to associate professor in 1973 and achieved the rank of full professor by 1975.[13] During this period, Chu established a research program in superconductivity, magnetism, and dielectrics, assembling a dynamic team of researchers at an institution with constrained funding and facilities.[5] His efforts included key collaborations, such as serving as a Resident Research Associate at Argonne National Laboratory in 1972 and as a Visiting Staff Member at Los Alamos Scientific Laboratory from 1975 to 1980, which supported experimental work on material properties under extreme conditions.[3] In 1977, Chu was appointed chair of the physics department at Cleveland State University, a role he held until 1979, during which he further developed the department's capabilities in condensed matter physics amid ongoing resource limitations.[13] His publications from this era addressed topics such as dielectric responses in solids and magnetic behaviors, laying foundational insights for later advancements, though detailed records of specific outputs remain limited in accessible archives.[3]

University of Houston Tenure

In 1979, Paul Ching Wu Chu joined the University of Houston as a professor of physics, marking the beginning of his long-term academic career there.[2] His appointment followed positions at other institutions, providing a foundation for his subsequent leadership at UH. Over the years, he advanced to hold the T. L. L. Temple Chair of Science in 1987, a prestigious endowed position that recognized his growing influence in the field.[2][14] A pivotal achievement during his tenure was the founding of the Texas Center for Superconductivity (TcSUH) in 1987, established with funding from the Texas Legislature in response to breakthroughs in high-temperature superconductivity.[15] As founding director from 1987 to 2001, Chu transformed TcSUH into a multidisciplinary research hub at the University of Houston, encompassing over 200 faculty, postdoctoral fellows, and students focused on superconductivity and advanced materials.[14][16] The center facilitated collaborative investigations into superconducting materials, fostering innovations in energy and related technologies.[17] Chu's mentorship at UH extended to numerous students and collaborators, particularly in early experiments on yttrium barium copper oxide (YBCO) superconductors. Notable mentees included M. K. Wu, a former student who contributed to initial YBCO findings, as well as lab members like Ru-Ling Meng, Pei-Hung Hor, Li Gao, Zhi-Jung Huang, Jeff Bechtold, Daniel Campbell, and Y. Q. Wang, who formed the core team for the 1987 discovery.[18][19] Through TcSUH, he guided generations of researchers, emphasizing hands-on training in materials synthesis and characterization.[20] Administratively, Chu took on key roles within the physics department and related units at UH through the 2000s, including directing the Magnetic Information Research Laboratory from 1984 to 1988 and leading TcSUH until 2001.[14] These positions involved overseeing research programs, securing funding, and integrating superconductivity studies into the department's curriculum and facilities.[14] His efforts strengthened UH's profile as a center for condensed matter physics.[2]

Administrative Leadership

Paul Ching Wu Chu's administrative experience at the University of Houston, where he served in various leadership positions such as directing research laboratories, provided a foundation for his subsequent high-level roles in academia.[2] In January 2001, Chu was appointed the second president of The Hong Kong University of Science and Technology (HKUST), a position he held until August 2009. During his tenure, he prioritized research expansion by establishing the Institute for Advanced Study in 2006, modeled after Princeton University's, to promote interdisciplinary and international collaborations among leading scholars.[21] He also oversaw faculty growth, recruiting senior academics from the United States and Taiwan to strengthen global ties, and advocated for policies to commercialize scientific research in Hong Kong, emphasizing the need for supportive measures to translate innovations into practical applications.[22][21] These efforts contributed to elevating HKUST's global standing, with the university achieving a ranking of 35th worldwide in the Times Higher Education Supplement by 2009.[21] In 2012, Chu was appointed Honorary Chancellor of the Taiwan Comprehensive University System (TCUS), an alliance of four leading research universities—National Cheng Kung University, National Chung Hsing University, National Sun Yat-sen University, and National Tsing Hua University—formed in 2011 to optimize resources and enhance higher education.[2][23] In this role, he served on the Consultation Committee since 2009, advising on development plans to build world-class institutions through integrated research, teaching, and international cooperation, while supporting policy reforms for regional balance and resource sharing among member institutions up to 2025.[2][23] His involvement helped foster cross-strait academic ties by leveraging his expertise to promote collaborations between Taiwanese universities and international partners, including those in Hong Kong and the mainland.[21] Throughout these administrative positions, Chu maintained a balance with his ongoing research responsibilities at the University of Houston (UH) and the Texas Center for Superconductivity at UH (TcSUH), where he continued as professor, T.L.L. Temple Chair of Science, founding director, and chief scientist, ensuring his scientific work remained active alongside leadership duties.[2]

Research Contributions

High-Temperature Superconductivity

Prior to 1987, superconductivity— the phenomenon of zero electrical resistance and expulsion of magnetic fields in certain materials— was confined to extremely low temperatures near absolute zero, necessitating cooling with costly liquid helium at 4.2 K. The highest critical temperature (Tc) for conventional superconductors, such as niobium-tin alloys, hovered around 18 K, while the record for any material stood at approximately 23 K for niobium-germanium, severely restricting practical applications due to the cryogenic challenges. This landscape shifted dramatically in 1986 when J. Georg Bednorz and K. Alex Müller reported superconductivity at 35 K in lanthanum-barium-copper oxide, igniting intense global research; Chu's group at the University of Houston subsequently enhanced Tc to 52 K in a similar compound under high pressure, setting the stage for further breakthroughs.[18] In February 1987, Paul C. W. Chu, leading a team at the University of Houston in collaboration with M. K. Wu's group at the University of Alabama in Huntsville, discovered superconductivity at 93 K in yttrium barium copper oxide (YBCO), with the orthorhombic phase YBa₂Cu₃O₇₋δ marking the first material to superconduct above the 77 K boiling point of affordable liquid nitrogen. This achievement was detailed in a landmark paper co-authored by Chu, Wu, P. H. Hor, R. L. Meng, and others, published in Physical Review Letters, where resistive and magnetic measurements confirmed a sharp, reproducible transition between 80 and 93 K at ambient pressure.[1][18] The YBCO compound represented a pivotal shift to copper-oxide-based (cuprate) materials, building on precursors like Chu's high-pressure experiments on lanthanum-based systems during his earlier career.[18] The experimental synthesis of YBCO involved a solid-state reaction: stoichiometric mixtures of yttrium oxide (Y₂O₃), barium carbonate (BaCO₃), and copper oxide (CuO) in a 1:4:6 molar ratio were ground, calcined at around 900°C to form the precursor, then pelletized and sintered at 950°C in air for several hours, followed by slow cooling and oxygenation at 400–500°C to achieve the optimal oxygen content (δ ≈ 0.1–0.2) essential for the superconducting phase.[1][18] This ambient-pressure method contrasted with prior high-pressure techniques used by Chu's team, enabling scalable production without specialized equipment and confirming the material's stability through zero-field cooling magnetization and four-probe resistivity tests.[1] The discovery of YBCO superconductivity immediately transformed the field, enabling liquid-nitrogen-based experiments and applications in power transmission, magnets, and sensors, while inspiring thousands of follow-up studies on cuprates. In 2014, the IEEE designated the work as a Milestone in Electrical Engineering, recognizing it as "the first superconductor above the boiling point of liquid nitrogen" and highlighting its role in advancing energy and medical technologies.

Magnetism and Dielectrics

Paul Ching Wu Chu's research extended into the magnetic properties of oxide materials, particularly exploring ferromagnetic and antiferromagnetic behaviors in complex systems such as manganites. His investigations focused on the interplay between magnetic ordering and structural properties under extreme conditions like high pressure and low temperatures, revealing novel phases in these materials. For instance, in orthorhombic HoMnO₃, an antiferromagnetic oxide, Chu and collaborators observed a field-induced re-entrant phase transition, where an applied magnetic field suppressed the ferroelectric order and induced a coupling between ferroelectric and magnetic states, demonstrating strong magnetoelectric interactions.[24] This work highlighted how external fields could manipulate competing orders in multiferroic oxides, providing insights into the fundamental mechanisms governing antiferromagnetism in perovskite structures. Building on these magnetic studies, Chu examined dielectric anomalies associated with magnetic phase transitions in similar oxides. In perovskite HoMnO₃ and YMnO₃, his team identified ferroelectricity induced by magnetic ordering, specifically at the lock-in transitions to E-type antiferromagnetic structures or incommensurate phases, where dielectric measurements revealed sharp anomalies coinciding with magnetic changes.[25] These findings underscored the coupled nature of magnetism and dielectrics in rare-earth manganites, with the dielectric response enhancing near antiferromagnetic transitions, offering a pathway to understand multiferroic behaviors without relying on traditional ferroelectric mechanisms. Chu's contributions to dielectrics also included explorations of high-permittivity materials suitable for electronics, leveraging nanotechnology to engineer enhanced properties. He co-invented a method to generate negative dielectric constants in aggregates of surface-treated oxide nanoparticles under a DC bias field, allowing tunable permittivity and frequency-dependent negative values, which has potential applications in electromagnetic wave devices like antennas and waveguides.[26] This nanoscale approach integrated magnetic and dielectric functionalities, using oxide nanostructures to achieve unprecedented control over dielectric responses. These efforts, conducted at the Texas Center for Superconductivity at the University of Houston (TcSUH) as a platform for advanced materials synthesis, resulted in numerous publications beyond superconductivity, contributing to Chu's over 460 total papers on solid-state physics topics including magnetism and dielectrics.[2] His work emphasized conceptual advancements in coupled phenomena, prioritizing high-impact oxide systems from the 1990s through the 2010s.

Recent Developments

In 2025, Paul Ching Wu Chu collaborated with Liangzi Deng at the University of Houston's Texas Center for Superconductivity to stabilize superconducting materials at ambient pressure, employing mini-diamond anvil cells and a novel pressure-quench protocol. This approach successfully preserved the high-pressure superconducting phase of bismuth antimony telluride (Bi0.5Sb1.5Te3) under normal conditions, demonstrating zero electrical resistance at temperatures up to 8 K without ongoing compression.[27][28] Building on his foundational yttrium barium copper oxide (YBCO) work from the 1980s, Chu's recent experiments have targeted higher transition temperatures to bridge the gap toward room-temperature superconductivity. In February 2025, Chu co-authored a publication detailing these pressure-stabilized superconductors, emphasizing their adaptability for practical applications through enhanced critical temperatures and structural integrity post-quenching.[29] In May 2025, Chu presented at an IEEE event on the "odyssey of high-Tc search," reflecting on the field's evolution and honoring predecessors like Harold Weinstock for their contributions to cryogenic advancements. These ongoing efforts underscore implications for energy transmission, where ambient superconductors could enable efficient, lossless power grids, and for quantum computing, offering stable materials for scalable qubit arrays.[30][7]

Awards and Honors

Scientific Prizes

Paul Ching Wu Chu received the National Medal of Science in 1988 from the President of the United States, recognizing his pioneering contributions to high-temperature superconductivity, which enabled stable superconducting states at temperatures significantly higher than previously achieved, around 93 K in yttrium barium copper oxide (YBCO) materials.[31] This award, the nation's highest honor for scientific achievement, honors individuals for outstanding advancements in the physical, biological, mathematical, or engineering sciences that have profoundly influenced their fields. The medal was presented by President Ronald Reagan during a White House ceremony on July 15, 1988, highlighting Chu's role in advancing the practical potential of superconductivity for applications in energy transmission and computing.[6] In the same year, Chu shared the Comstock Prize in Physics from the National Academy of Sciences with Maw-Kuen Wu for their groundbreaking discovery of superconductivity in YBCO and related copper oxide compounds, marking a major leap in elevating the critical temperature above the boiling point of liquid nitrogen.[32] Established in 1910 through a bequest from Henry T. Comstock, the prize is awarded approximately every five years to North American residents for innovative discoveries or investigations in electricity, magnetism, or light, and includes a $20,000 monetary award. The 1988 recognition underscored the transformative impact of their work on solid-state physics, directly tying to the experimental verification of high-temperature superconductivity that spurred global research efforts. The ceremony occurred at the National Academy of Sciences' annual meeting, affirming the discovery's role in challenging theoretical limits of superconductivity. Chu was also awarded the International Prize for New Materials by the American Physical Society in 1988 for his breakthroughs in developing high-temperature superconducting materials that revolutionized condensed matter physics.[2] This prize, funded by IBM and later evolving into the James C. McGroddy Prize, celebrates exceptional research leading to novel materials with significant technological promise, emphasizing innovations in synthesis and properties characterization. The award highlighted Chu's contributions to pressure-enhanced superconductivity in oxide perovskites, presented during the APS March Meeting, and reflected the rapid validation of these materials through crystallographic and magnetic studies that confirmed zero-resistance states at elevated temperatures.

Institutional Recognitions

In recognition of his leadership in engineering and science, Paul Ching Wu Chu was awarded the John Fritz Medal in 2001 by the American Association of Engineering Societies, one of the highest honors in the engineering profession for outstanding achievement in pure or applied science or notable public service.[33][2] Chu was elected a Fellow of the American Academy of Arts and Sciences in 1989, acknowledging his contributions to scholarship and societal leadership in the physical sciences.[34] Chu was elected to the National Academy of Sciences in 1989, recognizing his outstanding contributions to physics.[3] During his presidency at the Hong Kong University of Science and Technology from 2001 to 2009, Chu received the Honorary Fellowship from the Hong Kong Institution of Engineers in 2009 for his distinguished service to the engineering profession and the community.[35] He was also honored with the K. T. Li Professor Chair Award from National Cheng Kung University in Taiwan in 2009, recognizing his exemplary leadership in higher education and scientific advancement.[2] In 2014, the Institute of Electrical and Electronics Engineers (IEEE) dedicated a Milestone plaque at the University of Houston to commemorate the 1987 discovery of high-temperature superconductivity at the Texas Center for Superconductivity (TcSUH), which Chu founded and directed, highlighting the institutional impact of his administrative vision in advancing materials science research.[36][37] Chu's leadership extended to Taiwan, where he served as the founding president of the Taiwan Comprehensive University System in 2011 and was appointed honorary chancellor in 2012, roles that underscored his ongoing influence in consolidating and elevating higher education institutions across the region.

Later Life and Legacy

Personal Life

Paul Ching Wu Chu is married to May Chu, a physicist and the daughter of the renowned mathematician Shiing-Shen Chern.[38] The couple shares a mutual interest in scientific pursuits, reflecting their respective backgrounds in physics and mathematics.[39] Chu and his wife have divided their family life between the United States, Hong Kong, and Taiwan, maintaining residences that align with his professional transitions while preserving strong cultural connections to his roots. During his presidency at the Hong Kong University of Science and Technology from 2001 to 2009, the couple resided in Hong Kong, immersing themselves in the region's dynamic cultural environment. Following his return to the United States in 2009, they have primarily lived in Houston, Texas, where May Chu is based.[40][5]

Influence and Ongoing Work

Paul Ching Wu Chu has mentored numerous PhD students throughout his career, many of whom have gone on to make significant contributions to superconductivity research, including notable figures like Maw-Kuen Wu, who collaborated on early high-temperature superconductor discoveries under Chu's guidance.[18] His mentorship emphasizes experimental solid-state physics, fostering advancements in the field through hands-on training in high-pressure and low-temperature techniques.[41] Chu has also established scholarships to support emerging physicists, such as the Paul and May Chu Undergraduate Research Awards at the Hong Kong University of Science and Technology (HKUST), which he endowed with his wife to recognize excellence in physics research among undergraduates.[42] Similarly, the Paul Ching Wu Chu Scholarship at HKUST rewards outstanding academic performance in physics, providing financial support up to tuition fees plus $50,000 to eligible continuing undergraduate students.[43] His broader influence extends to global superconductivity research, where his pioneering work on high-temperature superconductors has shaped international efforts, as evidenced by over 48,000 citations to his publications and the widespread adoption of his methods in labs worldwide.[44] Additionally, Chu's leadership roles, including his presidency at HKUST from 2001 to 2009, have facilitated US-China academic exchanges by bridging scientific communities across the two nations, promoting collaborative programs and student mobility.[45] As of 2025, Chu continues to serve as Founding Director and Chief Scientist of the Texas Center for Superconductivity at the University of Houston (TcSUH), directing ongoing projects focused on discovering novel superconductors, elevating critical temperatures through new paradigms, and exploring topological states in superconducting materials for practical applications.[41] He remains active in public outreach, delivering lectures such as his 2025 presentation "In Search of High Tc" at the IEEE Council on Superconductivity event.[30] These efforts underscore his enduring commitment to advancing the field beyond his earlier breakthroughs.

References

  1. Superconductivity at 93 K in a new mixed-phase Y-Ba-Cu-O ...
  2. Paul CW Chu - Faculty Profile
  3. Chu, Ching-wu, 1941- - Niels Bohr Library & Archives
  4. Paul (Ching-Wu) Chu
  5. https://usa.chinadaily.com.cn/a/201406/13/WS5a2faab4a3108bc8c6728410.html
  6. The Inventive Mr. Chu - Texas Monthly
  7. Houston scientist Dr. Paul Chu upends the physics world - Chron
  8. [PDF] 講座大師朱經武 (Paul Ching-Wu Chu)簡介
  9. Chu, Selvamanickam Honored at Superconductivity Conference
  10. Paul Ching-Wu Chu | Encyclopedia.com
  11. Paul Ching-Wu Chu, PhD - Auroramri
  12. [PDF] PAUL C. W. CHU - Texas Center for Superconductivity
  13. Texas Center for Superconductivity Announces New Leadership
  14. Welcome to the Texas Center for Superconductivity at University of ...
  15. About The Texas Center For Superconductivity
  16. First-Hand:Discovery of Superconductivity at 93 K in YBCO
  17. TEAM REPORTS BREAKTHROUGH IN CONDUCTIVITY OF ...
  18. Physics Students Takes First in Superconductivity Symposium
  19. [PDF] The Road to Academic Excellence - HKU - Faculty of Education
  20. HKUST head leaving a valuable legacy - China Daily
  21. TCUS
  22. https://journals.aps.org/prl/abstract/10.1103/PhysRevLett.92.087204
  23. Ferroelectricity in perovskite and | Phys. Rev. B
  24. Generation and applications of negative dielectric constant materials
  25. UH Physicists Hit Major Milestone in Advancing Superconductor ...
  26. Creation, stabilization, and study at ambient pressure of ... - arXiv
  27. Bringing pressure-induced superconductivity back to ambient pressure
  28. In Search of High Tc | IEEE CSC
  29. Superconducting material stabilized at everyday pressure ... - NSF
  30. Paul (Ching-Wu) Chu | NSF - National Science Foundation
  31. Comstock Prize in Physics, US National Academy of Sciences, 2004
  32. John Fritz Medal Award - Society for Mining, Metallurgy & Exploration
  33. Ching-Wu Paul Chu | American Academy of Arts and Sciences
  34. Prof Paul CW Chu received the honour of the HKIE Honorary Fellow
  35. University of Houston Receives IEEE Milestone in Electrical ...
  36. High-Temperature Superconductivity - IEEE CSC
  37. Shiing-shen Chern - Biography - University of St Andrews
  38. UH Today - FAMED MATHEMATICIAN S.S. CHERN, EMERITUS ...
  39. Shiing-Shen Chern, 93, Innovator in New Geometry, Dies
  40. Dr. Ching Wu Chu - Houston - Texas Center for Superconductivity
  41. Thanks a million - South China Morning Post
  42. Paul Ching Wu Chu Scholarship for Continuing UG Students
  43. ‪Ching-Wu Chu‬ - ‪Google Scholar‬
  44. [PDF] Chinese American Scientists and U.S.-China Scientific Relations
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