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Sumio Iijima

Sumio Iijima (born May 2, 1939) is a Japanese physicist and inventor best known for discovering carbon nanotubes in 1991, cylindrical nanostructures composed of rolled-up graphene sheets that represent a fourth allotrope of carbon and have exceptional mechanical, electrical, and thermal properties.^[1]^[2] His breakthrough, achieved using high-resolution transmission electron microscopy at NEC Corporation's Fundamental Research Laboratories, revealed multi-walled carbon nanotubes formed as byproducts in fullerene synthesis via arc discharge evaporation.^[3]^[4] Iijima's early career focused on advancing electron microscopy techniques to visualize atomic structures. After earning a bachelor's degree from the University of Electro-Communications in Tokyo in 1963 and a PhD in solid-state physics from Tohoku University in 1968, he conducted postdoctoral research at Tohoku before joining Arizona State University from 1970 to 1982, where he specialized in high-resolution imaging of carbon materials.^[1]^[2] Returning to Japan in 1982, he worked on ultrafine particles at the Research Development Corporation until 1987, then joined NEC, where his expertise in electron microscopy led to the nanotube discovery.^[3] In 1993, he co-demonstrated the synthesis of single-walled carbon nanotubes using metal catalysts in arc discharge, further expanding their potential applications.^[3] Later, as University Professor at Meijo University since 1999, Senior Research Fellow at NEC Corporation, and former director (2001–2015) of the Nanotube Research Center at AIST in Tsukuba, he developed scalable production methods like Super-Growth for industrial uses in electronics, energy storage, and biomedicine.^[1]^[4]^[5] Iijima's work has profoundly influenced materials science, enabling innovations in conductive films, batteries, and sensors while establishing the foundations of modern nanotechnology.^[4] His contributions earned numerous accolades, including the Nishina Memorial Award in 1985, the Agilent Technologies Europhysics Prize in 2001, the Japan Academy Prize in 2002, the Balzan Prize for Nanoscience in 2007, and the King Faisal International Prize for Science in 2025.^[1]^[3]

Early Life and Education

Birth and Early Years

Sumio Iijima was born on May 2, 1939, in Koshigaya, Saitama Prefecture, Japan.^[6]^[7] His early years unfolded in a rural setting that would later influence his scientific curiosity, as the area was then far from the urban sprawl of nearby Tokyo.^[8] Growing up in the countryside during the immediate postwar period, Iijima spent much of his childhood engaged in hands-on exploration of the natural world, chasing butterflies, catching snakes, and raising rabbits and pigeons.^[6] This environment fostered an early sense of wonder and discovery through direct observation, which he later described as foundational to his approach to science.^[9] At his local rural school, where classes were large and resources modest, a dedicated science teacher played a pivotal role in igniting his interest in the subject, encouraging him to pursue deeper inquiries despite initial academic challenges.^[6] These formative experiences in rural Japan motivated Iijima to seek formal education in physics, leading him to move to Tokyo for higher studies.^[6]

Academic Training

Sumio Iijima earned his Bachelor's degree in Engineering from the University of Electro-Communications in Tokyo in 1963.^[3] He continued his studies at Tohoku University in Sendai, obtaining a Master's degree in chemistry in 1965.^[8] In 1968, Iijima completed his Ph.D. in solid-state physics at Tohoku University, with a dissertation titled "Print-Out Effects in AgBr Crystals," which examined crystal defects using electron microscopy techniques.^[4] During his graduate work at Tohoku University's Research Institute for Scientific Measurements, Iijima developed foundational expertise in transmission electron microscopy through hands-on research on material structures, including collaborative studies on the effects of electron irradiation on silver bromide crystals published in 1966.^[10] This early laboratory experience emphasized high-resolution imaging methods essential for analyzing atomic-scale defects in solids.^[11]

Professional Career

Early Positions

Following his doctoral studies, Sumio Iijima joined Arizona State University in Tempe, Arizona, as a research associate in the Department of Physics from 1970 to 1977, where he advanced high-resolution transmission electron microscopy (HRTEM) techniques for direct atomic imaging in crystalline materials.^[5] He was promoted to senior research associate at the Center for Solid State Science from 1977 to 1982, continuing his work under Professor John M. Cowley to refine these methods for visualizing atomic structures.^[5] During this period at ASU, Iijima invented a key HRTEM technique that enabled the imaging of atomic-scale defects in crystals, marking a significant milestone in materials characterization.^[3] In 1979, Iijima took a visiting senior scientist fellowship at the Department of Metallurgy and Materials Science, University of Cambridge, England, where he collaborated on defect analysis in carbon-based materials using electron microscopy.^[12] This short-term role, lasting several months, built on his ASU expertise and focused on graphite structures and imperfections.^[3] Iijima returned to Japan in 1982, joining the Research Development Corporation of Japan (now part of the Japan Science and Technology Agency) as group leader for the ERATO Program in Nagoya, a position he held until 1987.^[5] There, he led applied microscopy projects on ultra-fine particles, applying his HRTEM skills to investigate nanoscale material properties.^[3] These foundational techniques from his early positions later informed his imaging of nanostructures.^[12]

Career at NEC

In 1987, Sumio Iijima joined NEC Corporation as a senior principal researcher at the Fundamental Research Laboratories in Tsukuba, Japan, where he focused on advanced materials research.^[5] He advanced to the position of senior research fellow, a role he continues to hold, overseeing and contributing to projects on nanomaterials throughout his tenure.^[5]^[1] During his time at NEC, Iijima led research teams investigating nanomaterials, including the development of electron microscopy techniques that facilitated key discoveries such as carbon nanotubes in 1991.^[1]^[13] From the laboratories, he directed efforts to explore the properties and potential applications of these structures, establishing NEC as a pioneer in nanotechnology.^[7] His leadership extended to administrative responsibilities, notably as director of the NEC-AIST Nanotube Research Center from 2001 to 2015, where he coordinated interdisciplinary teams on nanotube synthesis and characterization.^[14] In this capacity and beyond, Iijima has maintained advisory roles, guiding NEC's strategic initiatives in nanomaterials up to the present.^[5] Iijima's work at NEC has emphasized collaborations with global partners to advance the commercialization of nanotube-based technologies.^[13] For instance, NEC partnered with institutions like the Japan Science and Technology Agency (JST) and the National Institute of Advanced Industrial Science and Technology (AIST) to develop high-purity carbon nanotube manufacturing processes and prototypes, such as faster transistors in 2003 and infrared sensors in 2023 aimed for market entry by 2026.^[13] These efforts have involved international cooperation, including joint projects with entities like Meijo Nano Carbon, to translate research into practical applications in electronics and sensing.^[13]

Academic Roles

In 1999, Sumio Iijima was appointed as Professor in the Department of Materials Science and Engineering at Meijo University in Nagoya, Japan, advancing to University Professor in 2010, a position he continues to hold.^[5]^[7] In this capacity, he has mentored graduate students specializing in nanotechnology, guiding research on advanced materials through hands-on supervision and collaboration on experimental projects.^[15] His teaching at Meijo integrates practical insights from electron microscopy and nanomaterial synthesis, fostering interdisciplinary approaches in the graduate curriculum.^[3] Since 2007, Iijima has served as Distinguished Invited University Professor at Nagoya University, where he has played a key role in establishing nanoscience programs and promoting cutting-edge research in carbon-based nanomaterials.^[5]^[15] This affiliation allows him to bridge academic training with industrial applications, contributing to the university's initiatives in nanotechnology education and the supervision of advanced student theses.^[16] In 2015, Iijima was named Honorary AIST Fellow at the National Institute of Advanced Industrial Science and Technology (AIST), where he advises on materials science initiatives, particularly those involving nanoscale structures and their practical implementations.^[5]^[4] Complementing his formal roles, Iijima has delivered guest lectures worldwide on electron microscopy applications and supervised theses exploring its techniques in nanomaterial characterization, enhancing global academic discourse in the field.^[3]^[7]

Research Contributions

Electron Microscopy Techniques

Sumio Iijima made pioneering contributions to high-resolution transmission electron microscopy (HRTEM) during the 1970s, particularly while working at Arizona State University, where he focused on imaging atomic arrangements in crystalline materials. His early work demonstrated the capability of HRTEM to directly visualize crystal lattices at the atomic scale, as exemplified by his 1971 study on the titanium-niobium oxide system, which resolved lattice fringes corresponding to interatomic distances.^[17] This approach laid foundational techniques for structural analysis, emphasizing phase contrast imaging under controlled defocus conditions to enhance visibility of atomic columns.^[18] A key innovation in Iijima's research was the development of methods to visualize lattice defects and dislocations in crystals, enabling detailed examination of structural imperfections that influence material properties. In 1973, he published direct observations of defects in hydrogen niobate (H-Nb₂O₅) using HRTEM, revealing dislocations and stacking faults through lattice fringe discontinuities at resolutions approaching 0.3 nm. Building on this, his collaborative work that same year explored high-resolution imaging of defects and disorder in various crystals, providing protocols for interpreting image contrast from dislocations and establishing HRTEM as a standard tool for defect characterization.^[3] These techniques prioritized thin specimen preparation and minimal beam exposure to preserve defect integrity during observation. Iijima's advancements extended to achieving sub-angstrom resolution in HRTEM, a milestone that pushed the limits of electron optics for atomic-scale imaging. In a 1979 collaboration, he analyzed contrast transfer functions and information limits, theoretically enabling resolutions below 0.2 nm by optimizing lens aberrations and electron coherence, which influenced subsequent microscope designs worldwide. His methods, published in journals such as Ultramicroscopy, including a 1981 paper on observing atomic steps on silicon surfaces, standardized imaging protocols and inspired global adoption in materials science.^[19] For instance, the use of high-brightness electron sources like field-emission guns in these setups reduced beam-induced damage, allowing clearer imaging of sensitive crystalline samples without significant structural alteration.^[3] These HRTEM innovations provided essential tools for later applications, such as briefly imaging nanostructures like fullerenes, by offering unprecedented atomic-level detail.^[18]

Fullerene Imaging

In 1987, Sumio Iijima utilized high-resolution transmission electron microscopy (HRTEM) to capture the first images of isolated C60 molecules in carbon soots, revealing spherical carbon clusters approximately 0.7 nm in diameter with icosahedral symmetry consistent with the predicted soccer-ball structure composed of 12 pentagons and 20 hexagons.^[20] These images provided direct visual confirmation of the truncated icosahedral cage geometry proposed for buckminsterfullerene, demonstrating its stability as a closed-shell carbon molecule under electron beam conditions.^[20] Iijima's 1987 communication in the Journal of Physical Chemistry detailed the fullerene cage structures observed in soots produced by arc evaporation, emphasizing their closed polyhedral forms and inherent stability due to the even distribution of pentagonal defects that induce positive curvature without unpaired pi electrons.^[20] This work highlighted how such cage architectures prevent reactive edge sites, contributing to the robustness of fullerenes compared to open graphitic fragments.^[20] Extending his microscopy techniques, Iijima analyzed higher fullerenes like C70 and C84 in thin films and soots during the early 1990s, employing electron diffraction to determine their geometric properties. In a 1992 study, he and collaborator H. Kuroshima examined C70 thin films grown on alkali halide substrates via organic molecular beam epitaxy, revealing an expanded lattice constant of approximately 1.44 nm perpendicular to the stacking plane, indicative of the elongated rugby-ball shape with D5h symmetry and 12 pentagons amid 25 hexagons.^[21] Iijima's HRTEM investigations of carbon soots also contributed to elucidating fullerene formation mechanisms by visualizing atomic-scale defects, such as pentagon-heptagon pairs and Stone-Wales rotations, in nascent cage structures during arc-discharge synthesis.^[22] These observations illustrated how local curvature defects facilitate the closure of graphitic sheets into stable fullerenes, providing insights into the growth pathways from planar graphene fragments to three-dimensional polyhedra under high-temperature conditions.^[22]

Carbon Nanotube Discovery

During experiments on fullerene synthesis using arc-discharge evaporation of graphite electrodes, Sumio Iijima discovered multi-walled carbon nanotubes (MWNTs) in 1991 as needle-like structures forming in the carbonaceous deposits on the negative electrode.^[23] These MWNTs consisted of coaxial tubes of graphitic carbon sheets, with the carbon atoms arranged in hexagons that wound helically around the central axis.^[23] Iijima's observations, made via high-resolution transmission electron microscopy, revealed that the tubes had outer diameters ranging from a few to several tens of nanometers and could contain 2 to 50 concentric layers, with the helical pitch varying between individual tubes.^[23] Iijima detailed these findings in a seminal paper published in Nature in October 1991, emphasizing the seamless, rolled-up graphene structure and its potential as an intermediate form between fullerenes and graphite fibers.^[23] The helical geometry, confirmed through electron diffraction patterns, suggested a growth mechanism involving the curling of graphitic sheets during the high-temperature arc process.^[23] This discovery immediately expanded the scope of carbon-based nanomaterials, bridging molecular and macroscopic scales. In follow-up work in 1993, Iijima and Toshinari Ichihashi at NEC reported the production of single-walled carbon nanotubes (SWNTs) with diameters of approximately 1 nm, synthesized in the gas phase of a modified carbon-arc discharge using iron catalyst.^[24] Independently and simultaneously, Donald S. Bethune and colleagues at IBM described similar SWNTs (~1.2 nm diameter) grown via cobalt-catalyzed arc evaporation, with both groups publishing back-to-back in Nature.^[25] Electron microscopy and diffraction analyses in these studies confirmed the single-layer helical arrangement of hexagons, distinguishing SWNTs from the multi-layered variants.^[24] Early characterization using transmission electron microscopy provided initial insights into the nanotubes' properties, revealing their rigid, defect-free graphitic structure that implied superior mechanical strength with high elastic modulus, tunable electrical conductivity (metallic or semiconducting based on helicity), and excellent thermal conductance.^[26] These structural observations laid the foundation for subsequent experimental verifications of ballistic electron transport and exceptional tensile strength in isolated nanotubes.^[26] The discoveries generated immediate scientific excitement, prompting global research into controlled synthesis and property optimization within months.^[26]

Recognition

Scientific Honors and Memberships

Sumio Iijima was elected as a Foreign Associate of the National Academy of Sciences (USA) in 2007, recognizing his contributions to nanoscience.^[27] He became a Member of the Japan Academy on December 13, 2010, in the Section II (Materials Science) subsection.^[28] In 2009, Iijima was elected as a Foreign Member of the Norwegian Academy of Science and Letters.^[15] He was also elected as a Foreign Member of the Chinese Academy of Sciences in 2011.^[15] Iijima has received honorary memberships in several crystallography and microscopy societies for his pioneering work in high-resolution electron microscopy, which underpinned his later nanotube discoveries. These include Honorary Member of the Crystallographic Society of Japan in 2002 and Honorary Member of the Japanese Society of Microscopy in 2004.^[15] He was elected Fellow of the American Physical Society in 2000.^[15]

Major Awards

Sumio Iijima received the Bertram Eugene Warren Diffraction Physics Award from the American Crystallographic Association in 1976 for his innovations in electron microscopy techniques that advanced the understanding of atomic structures.^[5] In 1985, he was awarded the Nishina Memorial Award by the Nishina Memorial Foundation for his significant contributions to solid-state physics, particularly his studies on structural instabilities in materials.^[1] Iijima earned the Asahi Prize from the Asahi Shimbun Cultural Foundation in 1996 in recognition of his discovery of carbon nanotubes and its implications for materials science.^[29] He shared the Agilent Technologies Europhysics Prize from the European Physical Society in 2001 with Cees Dekker, Thomas W. Ebbesen, and Paul L. McEuen for their pioneering work on the properties and applications of carbon nanotubes.^[30] In 2002, Iijima was honored with the Japan Academy Prize and Imperial Award from the Japan Academy for the development of high-resolution electron microscopy and the discovery of carbon nanotubes.^[31] He also received the Benjamin Franklin Medal in Physics from the Franklin Institute that year for his discovery and elucidation of the atomic structure and helical nature of carbon nanotubes.^[32] In 2007, Iijima received the Balzan Prize for Nanoscience from the International Balzan Prize Foundation for his discovery of carbon nanotubes, particularly single-wall carbon nanotubes and their mechanical and electronic properties.^[33] He was also awarded the Gregori Aminoff Prize in Crystallography from the Royal Swedish Academy of Sciences for his fundamental contributions to the development of methods in electron microscopy and their applications.^[15] The Prince of Asturias Award for Technical and Scientific Research, shared with Shuji Nakamura, Robert Langer, George M. Whitesides, and Tobin Marks, was bestowed upon him in 2008 by the Princess of Asturias Foundation for groundbreaking advancements in nanoscience and bioengineering.^[34] Iijima shared the inaugural Kavli Prize in Nanoscience from the Norwegian Academy of Science and Letters in 2008 with Louis E. Brus for their transformative discoveries of zero- and one-dimensional nanostructures, including fullerenes and carbon nanotubes, which laid the foundation for modern nanoscience.^[35] In 2015, he received the European Inventor Award in the non-European countries category from the European Patent Office, shared with Akira Koshio and Masako Yudasaka, for their invention of carbon nanotube aggregates enabling targeted drug delivery in medical applications.^[36] Most recently, in 2025, Iijima was awarded the King Faisal International Prize in Science (Physics) by the King Faisal Foundation for establishing the field of carbon nanotubes through his pioneering discovery and subsequent research.^[37]

References

[1]
Sumio Iijima - Engineering and Technology History Wiki
Feb 29, 2016 · In 1991 he discovered carbon nanotubes, which are tube-shaped materials whose diameter measures on the nanometer scale. Carbon nanotubes are now ...
[2]
Sumio Iijima - Physics Today
May 2, 2017 · Born on 2 May 1939, Sumio Iijima is a Japanese physicist who discovered carbon nanotubes. After earning his PhD in solid-state physics at ...
[3]
ECS Lecture | Sumio Iijima - The Electrochemical Society
May 19, 2008 · In 1991, Prof. Iijima discovered carbon nanotubes and elucidated that carbon nanotubes are composed of concentric graphene tubes and have the ...Missing: biography | Show results with:biography<|control11|><|separator|>
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Professor Sumio Iijima - King Faisal Prize
In 1991 he discovered carbon nanotubes, pioneering nanoscience and nanotechnology in the world. The first paper reporting carbon nanotubes currently has 58,000 ...
[5]
Online Extra: Q&A with NEC's Sumio Iijima - Bloomberg
Jul 7, 2002 · The scientist, who could become the next Japanese to receive a Nobel prize, recently took time to talk about his life work with BusinessWeek ...
[6]
Sumio Iijima: Bio-bibliography - International Balzan Prize Foundation
Sumio Iijima, born in Saitama, Japan, on 2 May 1939, is a Japanese citizen. At present, he is Professor at Meijo University in Nagoya, Director of the Research ...Missing: family background early life
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Sumio Iijima: Inventor of Carbon Nanotubes and Pioneer of Modern ...
Oct 6, 2021 · Sumio Iijima is a Japanese physicist and inventor who was the first to clearly describe the formation of carbon nanotubes and imagine their potential.Missing: biography | Show results with:biography
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[PDF] Interview
Interview with Professor Sumio Iijima. He discovered carbon nanotubes in ... It should start from very early childhood. I grew up in the countryside ...Missing: family | Show results with:family
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Electronmicroscopic Observations of the Effect of Electron Irradiation ...
Electronmicroscopic Observations of the Effect of Electron Irradiation and Print-Out Effect on AgBr Crystal. Sumio Iijima and Tadatoshi Hibi. Copyright (c) 1966 ...
[10]
[PDF] List of papers by Sumio Iijima (since 1966) - NEC
List of papers by Sumio Iijima (since 1966). [1966]. 1) “Electronmicroscopic observation of the effect of electron irradiation and print-out effect on AgBr ...Missing: Tohoku | Show results with:Tohoku
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Sumio Iijima: Our Researchers - NEC Corporation
Sep 24, 2025 · University Professor, Meijo University · Senior Research Fellow, NEC Corporation · Honorary AIST Fellow, National Institute of Advanced Industrial ...Missing: Koshigaya | Show results with:Koshigaya
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Sumio Iijima - The Franklin Institute
Iijima revealed the first electron micrograph showing atoms in a crystal. Iijima also worked as a visiting scholar at Cambridge University in 1979, where he ...Missing: mentors | Show results with:mentors
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Carbon Nanotube: Featured Technologies | NEC
Sep 1, 2017 · Here, Dr. Iijima looks back on his history as a researcher, and talks about the future of carbon nanotubes.
[14]
[PDF] Dr. Sumio Iijima(飯島澄男)
Biography: Sumio Iijima is a Professor in Meijo University & Director, NEC AIST/Nanotube Research. Center at Nagoya University. Hi is often cited as ...
[15]
[PDF] Dr. Sumio Iijima's Research Accomplishments & Biography
Sumio Iijima's Research Accomplishments & Biography last update September 1, 2022. Biography. Name: Sumio Iijima. Date of Birth: May 2, 1939. Contact: Meijo ...Missing: family | Show results with:family<|control11|><|separator|>
[16]
Distinguished Invited University Professor Sumio Iijima
Sumio Iijima. Education. 1963 University of Electro-communications , Tokyo ... Tohoku University , Sendai , Majoring in Physics; Ph.D. Appointments. 1968 ...Missing: PhD advisor
[17]
High‐Resolution Electron Microscopy of Crystal Lattice of Titanium ...
Dec 1, 1971 · High‐Resolution Electron Microscopy of Crystal Lattice of Titanium‐Niobium Oxide Available. Sumio Iijima.Missing: transmission | Show results with:transmission
[18]
Sumio Iijima – NAS - National Academy of Sciences
I have developed the high-resolution transmission electron microscopy (HRTEM) method in the early 1979s, which laid the foundation of the current HRTEM.
[19]
Observation of atomic steps of (111) surface of a silicon crystal using ...
Using an ordinary transmission electron microscopy technique, atomic steps on the (111) surfaces of silicon single crystal have been observed.
[20]
The 60-carbon cluster has been revealed - ACS Publications
Sumio Iijima. Helical microtubules of graphitic carbon. Nature 1991, 354 (6348) , 56-58. https://doi.org/10.1038/354056a0. Leif Goodwin. Structure and ...
[21]
https://doi.org/10.1557/PROC-247-321
[22]
High resolution electron microscopy studies in carbon soots
A descriptive study using high resolution electron microscopy of fullerene-related carbon structures found in carbon soots is presented. ... S. Iijima.
[23]
Helical microtubules of graphitic carbon - Nature
Nov 7, 1991 · Electron microscopy reveals that each needle comprises coaxial tubes of graphitic sheets, ranging in number from 2 up to about 50. On each tube ...
[24]
Single-shell carbon nanotubes of 1-nm diameter - Nature
**Summary of Iijima and Ichihashi's 1993 Paper on Single-Shell Carbon Nanotubes:**
[25]
Cobalt-catalysed growth of carbon nanotubes with single-atomic-layer walls - Nature
### Summary of Bethune et al.'s 1993 Paper on Single-Walled Carbon Nanotubes
[26]
Carbon nanotubes: From macromolecules to nanotechnology - PNAS
Dec 7, 1999 · The discovery of nanotubes happened in 1991 when Dr. Sumio Iijima of NEC corporation found these tiny needles on electrodes used to prepare ...
[27]
Sumio Iijima to present Departments of Chemistry and Biochemistry ...
After earning his PhD degree from Tohoku University, he worked with Prof. J. M. Cowley at Arizona State University where he developed high-resolution ...Missing: training | Show results with:training
[28]
Personal Information - IIJIMA Sumio | The Japan Academy
"High resolution electron microscopy of crystal lattice of titanium-niobium oxide", S. Iijima, J. Appl. Phys., 42, 5891-5893 (1971). "Direct observation of ...
[29]
THE ASAHI PRIZE (English version) | 朝日新聞社の会社案内
The Asahi Prize was established in 1929 to honor individuals and groups ... Sumio Iijima Fujihiro Araki. [ Fiscal 1995]. Shuntaro Tanikawa The late Iri ...
[30]
https://members.eps.org/members/group_content_view.asp?group=85187&id=554142
[31]
Materials win medals - Physics World
Jan 30, 2002 · The 2002 Benjamin Franklin Medal in Physics has been awarded to Sumio Iijima of the NEC Corporation in Japan for his discovery of the atomic ...
[32]
Sumio Iijima, Shuji Nakamura, Robert Langer, George M ...
Whitesides and Tobin Marks. Prince of Asturias Award for Technical & Scientific Research 2008. These scientists are Sumio Iijima, from Japan, and Shuji Nakamura ...
[33]
Kavli Prize Laureate Sumio Iijima
Sumio Iijima studied at the University of Electro-Communications in Tokyo and completed his PhD in physics at Tohoku University in Sendai before moving to ...Missing: family background farmer life
[34]
Japanese research team wins European Inventor Award 2015 for a ...
Jun 11, 2015 · ... Sumio Iijima, Akira Koshio, and Masako Yudasaka at the Japanese firm NEC received the European Inventor Award 2015 in the category “Non ...
[35]
Professor Sumio Iijima – King Faisal Prize
### Summary of Professor Sumio Iijima