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Isamu Akasaki

Isamu Akasaki (30 January 1929 – 1 April 2021) was a Japanese electrical engineer and physicist best known for his pioneering development of gallium nitride-based semiconductors, particularly the invention of efficient blue light-emitting diodes (LEDs) that revolutionized energy-efficient lighting worldwide.^[1]^[2] Born in Chiran, Kagoshima Prefecture, Japan, Akasaki earned a B.S. in electronics engineering from Kyoto University in 1952 and a Ph.D. in engineering from Nagoya University in 1964.^[1]^[3] He began his career as a research staff member at Kobe Kogyo Corporation (now Fujitsu Ltd.) from 1952 to 1959, focusing on electronic materials, before joining Nagoya University from 1959 to 1964 as a research associate and advancing to associate professor in the Department of Electronics.^[4]^[3] In 1964, Akasaki joined Matsushita Research Institute Tokyo (now Panasonic Corporation), where he served as head of the Basic Research Laboratory IV until 1974 and then as general manager of the Semiconductor Department until 1981, during which time he contributed to advancements in gallium arsenide and gallium phosphide LEDs, including the development of high-quality GaAs crystals in 1968 and GaP red LEDs in 1970.^[3] Returning to academia, he became a full professor at Nagoya University from 1981 to 1992, where he led research on metalorganic vapor phase epitaxy (MOVPE) techniques, achieving breakthroughs such as the low-temperature buffer layer for GaN growth in 1986 and the first p-type GaN doping in 1989, enabling the creation of a GaN p-n junction blue/UV LED that same year.^[4]^[3] In 1992, he joined Meijo University as a professor, later becoming university professor in 2010 and distinguished professor in 2015, while also serving as director of the Research Center for Nitride Semiconductor Core Technologies.^[4]^[5] Akasaki's collaborative work with students Hiroshi Amano and others resulted in the first practical blue LED in 1992 and a blue-violet laser diode in 1995, foundational to white LED technology that combines blue light with phosphors for energy-saving illumination up to 100 times more efficient than traditional bulbs.^[2]^[3] For these innovations, he shared the 2014 Nobel Prize in Physics with Amano and Shuji Nakamura, recognizing their role in enabling bright, long-lasting white light sources that have transformed global lighting and reduced energy consumption.^[6] Among his numerous honors, Akasaki received the 2009 Kyoto Prize in Advanced Technology, the 2011 IEEE Edison Medal, and the 2021 Queen Elizabeth Prize for Engineering, and he authored over 730 papers, edited 12 books, and held more than 200 patents related to nitrides.^[3]^[7] Akasaki passed away from pneumonia in Nagoya on 1 April 2021 at the age of 92.^[1]^[5]

Early Life and Education

Childhood and Family Background

Isamu Akasaki was born on January 30, 1929, in Chiran (now part of Minamikyushu City), Kagoshima Prefecture, Japan.^[1] He was the son of Suguo Akasaki, a Buddhist altar craftsman, and Sumi Akasaki, growing up in a modest family environment shaped by his father's traditional trade.^[8]^[9] Akasaki had an elder brother, Masanori Akasaki, who pursued a career as a plasma physicist and electronic engineering researcher, potentially influencing his early surroundings.^[8] Although born in the rural town of Chiran, Akasaki spent much of his childhood in Kagoshima City, where his family relocated during his early years, while making annual trips back to their ancestral hometown in Chiran's samurai district.^[10] His formative period unfolded amid Japan's pre-war and wartime challenges in the 1930s and 1940s, including the militarization of society and the devastation of World War II, as Kagoshima Prefecture endured heavy Allied bombings in 1945 that left much of the region in ruins.^[10] Post-war reconstruction efforts in southern Japan, coupled with the economic hardships of the era, characterized his modest rural-influenced upbringing, fostering resilience in a time of national recovery.^[9] Akasaki's early exposure to science came through local schools and family influences, where he developed a strong interest in natural phenomena during outings to Kagoshima Bay's rocky shores, collecting rocks and shells that captivated him with their shapes and colors.^[9] His father further nurtured this curiosity by providing him with ore specimens as a child, sparking a lifelong fascination with crystals and materials that would later define his scientific path.^[11] At Kagoshima's Seventh Higher School (a preparatory institution now affiliated with Kagoshima University), he engaged in self-study and classroom learning, particularly excelling in and developing a passion for mathematics, physics, and chemistry amid the post-war push for technological advancement in Japan.^[10] These wartime experiences of destruction and rebuilding, contrasted with the relative stability he later encountered, heightened his interest in physics and electronics as tools for innovation and recovery.^[10] This foundation led him to pursue higher education at Kyoto University, where he studied in the Faculty of Science.^[10]

Academic Training

Isamu Akasaki enrolled at Kyoto University's Faculty of Science in 1949, following a highly competitive entrance examination, and pursued studies in the Department of Chemistry amid Japan's post-war recovery period.^[10] The wartime aftermath had delayed his entry into higher education by approximately two years, reflecting broader disruptions to academic timelines in the late 1940s, though the Kyoto campus itself remained largely intact and fostered a resilient student environment.^[10] His undergraduate curriculum centered on chemistry, with an emphasis on physical chemistry principles, laboratory-based self-study, and independent problem-solving rather than rote instruction.^[10] Akasaki graduated with a Bachelor of Science degree from the Department of Chemistry in March 1952.^[4] Following graduation, he entered industry rather than immediately pursuing advanced studies, joining Kobe Kogyo Corporation (now part of Fujitsu) as a researcher, which created a twelve-year gap before his doctoral work.^[3] In 1959, Akasaki transitioned to Nagoya University as a research associate in the School of Engineering, where he began graduate studies focused on semiconductor materials.^[12] Under this arrangement, he conducted research on vapor-phase epitaxial growth techniques, earning his Doctor of Engineering degree in electronics in March 1964.^[4] His doctoral thesis, titled "Vapor Phase Epitaxial Growth of Ge," explored thermodynamic aspects of impurity doping in germanium crystals, marking his initial foray into semiconductor fabrication.^[8] This graduate experience provided foundational exposure to solid-state physics and early experimentation with compound semiconductor processes, shaping his later innovations in materials science.^[8]

Professional Career

Early Positions in Industry and Academia

Upon graduating from Kyoto University in 1952, Isamu Akasaki joined Kobe Kogyo Corporation (now Fujitsu Ltd.) as a research staff member, where he contributed to the development of electronic materials during Japan's post-war electronics industry expansion.^[3] His early work focused on manufacturing processes for fluorescent screens in cathode-ray tubes and β-ray scintillators, marking his initial exposure to luminescence phenomena in vacuum tube technologies.^[3] This period from 1952 to 1959 allowed Akasaki to build practical skills in materials synthesis amid the rapid growth of semiconductor-related applications in consumer electronics.^[4] In 1959, Akasaki transitioned to Nagoya University as a research associate in the Department of Electronics, advancing to assistant professor and then associate professor by 1964 while pursuing his Doctor of Engineering degree, which he completed that year.^[4] During this time, he conducted hands-on laboratory experiments on vapor-phase epitaxial (VPE) growth of germanium, pioneering thermodynamic analyses of impurity doping processes to enhance crystal quality.^[3] These efforts represented his first publications on compound semiconductor materials in the early 1960s, laying foundational knowledge in epitaxial techniques essential for optoelectronic devices.^[3] Akasaki served as head of the Basic Research Laboratory IV at Matsushita Research Institute Tokyo, Inc. (now part of Panasonic Corporation) from 1964 to 1974 and as general manager of the Semiconductor Research Department from 1974 to 1981.^[4] In this role, he led teams on applied projects in optoelectronic materials, emphasizing compound semiconductors such as GaAs, GaP, AlN, and early explorations of GaN.^[3] Key achievements included developing high-quality GaAs crystals via VPE in 1968, achieving the world's highest electron mobility at the time, and creating the brightest GaP-based red light-emitting diode in 1970.^[3] Additionally, in 1967, he initiated VPE growth of AlN to study its optical properties, and by 1974, he grew GaN single crystals using molecular beam epitaxy, demonstrating his growing expertise in advanced deposition methods that foreshadowed later adaptations like metal-organic vapor phase epitaxy (MOVPE).^[3]

Professorship and Institutional Leadership

In 1981, Isamu Akasaki was appointed professor in the Department of Electronics at Nagoya University, where he led a research group focused on semiconductor materials, including oversight of laboratory operations and supervision of graduate students in optoelectronics and related fields.^[4]^[13] During his tenure until 1992, he mentored doctoral candidates and fostered a lab environment emphasizing persistent basic research on challenging materials like gallium nitride, often securing competitive grants from Japan's Science and Technology Agency (JST) and Ministry of Education, Culture, Sports, Science and Technology (MEXT) to support high-risk projects despite initial skepticism in the academic funding landscape.^[4]^[14] Akasaki's most notable mentorship was of Hiroshi Amano, who joined his Nagoya University lab as an undergraduate in 1982 and completed his PhD under Akasaki's guidance in 1989, crediting him not only for scientific direction but also for instilling a culture of resilience and ethical conduct in research amid repeated experimental failures.^[15]^[14] This approach, rooted in Akasaki's prior industry experience at Matsushita Electric, enabled the lab to navigate Japan's grant-based funding system, where professors like Akasaki played pivotal roles in proposal writing and resource allocation for graduate training.^[4]^[3] Following his departure from Nagoya University in 1992, Akasaki was named professor emeritus there and joined Meijo University as a professor in the Graduate School of Science and Technology in 1992, holding the position until his death in 2021 while maintaining active involvement in both institutions.^[4]^[13] In 2004, he was appointed university professor at Nagoya University, and in 2010 at Meijo University, roles that amplified his institutional leadership in advancing semiconductor education and interdisciplinary collaboration.^[4]^[16] Akasaki contributed to institution-building by serving as a research fellow at the Nagoya University Akasaki Research Center, established in 2001 to drive innovation in semiconductor devices, and was instrumental in the development of the Akasaki Institute at Nagoya University, completed in 2006 and funded by royalties from his patents.^[4]^[17] The institute focuses on next-generation optoelectronics research, including nitride semiconductors, while prioritizing student training through hands-on programs and collaborative projects to cultivate future leaders in the field.^[18]^[19] From 2011, he also directed the Research Center for Nitride Semiconductor Core Technologies at Meijo University, further solidifying his legacy in guiding institutional efforts toward practical applications of advanced materials.^[4]^[13]

Research Contributions

Advances in Gallium Nitride Technology

Gallium nitride (GaN) is a wide-bandgap semiconductor with a bandgap energy of 3.4 eV, making it promising for optoelectronic applications in the blue and ultraviolet spectra.^[20] However, early efforts to grow high-quality GaN crystals faced significant challenges, primarily due to the 16% lattice mismatch between GaN and commonly used sapphire substrates, which induced high defect densities, cracking, and poor crystallinity.^[21]^[20] These issues persisted despite attempts using various epitaxial techniques, as the thermal and lattice mismatches led to polycrystalline films with dislocation densities exceeding 10^{10} cm^{-2}.^[21] A major breakthrough occurred in 1985 when Isamu Akasaki and Hiroshi Amano successfully grew high-quality single-crystal GaN using metalorganic vapor phase epitaxy (MOVPE) with a low-temperature buffer layer.^[20]^[21] The process involved depositing a thin aluminum nitride (AlN) buffer layer, approximately 20–50 nm thick, on a sapphire substrate at a low temperature of around 500°C to promote nucleation and minimize initial mismatch stresses.^[20] This was followed by heating to approximately 1000°C and growing the GaN layer using trimethylgallium (TMGa) and ammonia (NH₃) as precursor gases, resulting in significantly reduced defect densities—over two orders of magnitude lower than prior methods—and atomically flat surfaces.^[21] The AlN buffer acted as an effective intermediary, providing oriented nucleation sites and accommodating the lattice mismatch to enable coherent epitaxial growth.^[21] Further advances came in 1989 with the achievement of p-type doping in GaN, also by Akasaki and Amano, which addressed another key barrier to device fabrication.^[20] They doped the GaN with magnesium (Mg) during MOVPE growth, but initial attempts yielded semi-insulating material due to hydrogen passivation, where hydrogen atoms bound to Mg acceptors, neutralizing their electrical activity.^[21] To overcome this, they applied low-energy electron beam irradiation (LEEBI) at around 10 kV, which desorbed the passivating hydrogen and activated the Mg acceptors, yielding hole concentrations of approximately 10^{17} cm^{-3} and confirming p-type conduction via Hall effect measurements.^[22] This technique enabled controlled conductivity in GaN, marking a pivotal step in nitride semiconductor development.^[21]

Invention of Blue LEDs and Lasers

In 1989, Isamu Akasaki and Hiroshi Amano demonstrated the world's first GaN p-n junction blue/UV light-emitting diode (LED) using a structure grown on a sapphire substrate via metalorganic chemical vapor deposition (MOCVD).^[22]^[23] This device, activated through magnesium doping and low-energy electron beam irradiation (LEEBI) to achieve p-type conduction, emitted weak blue light under forward bias at low currents (<20 mA), marking a groundbreaking achievement that proved GaN's viability for optoelectronic devices through the first demonstration of injection electroluminescence from a wide-bandgap nitride semiconductor. Building on their earlier 1985 development of high-quality GaN crystal growth using a low-temperature aluminum nitride buffer layer, this p-n junction enabled hole-electron recombination for visible emission.^[23] Throughout the early 1990s, Akasaki and Amano's team advanced the LED design by incorporating double-heterostructure (DH) configurations with AlGaN cladding layers to confine carriers and light, significantly boosting brightness and efficiency.^[20] By introducing indium gallium nitride (InGaN) quantum wells (QWs) with well widths under 3 nm in the active region, they further enhanced radiative recombination rates, achieving an EQE of 1.5% by 1992, which represented a substantial improvement over the 1989 device's performance.^[20] These InGaN/GaN QW structures addressed key limitations in carrier confinement and reduced non-radiative losses, paving the way for brighter blue LEDs suitable for practical applications. Parallel efforts in the 1990s extended to blue laser diodes, where Akasaki, Amano, and collaborators—including interactions with Shuji Nakamura's independent work at Nichia Corporation—focused on achieving stimulated emission.^[2] Akasaki's group realized pulsed laser operation from a single InGaN QW diode at 376 nm in 1996, while Nakamura demonstrated room-temperature continuous-wave (CW) operation of a violet laser diode at 405 nm the same year, enabling high-density optical storage like Blu-ray discs.^[20] The DH design with InGaN QWs proved critical for both groups, providing optical gain and low threshold currents around 60 mA (4 kA/cm²) for CW mode, overcoming challenges in mirror reflectivity and thermal management inherent to nitride materials.^[24] Subsequent refinements tackled efficiency droop—a reduction in quantum efficiency at high currents due to carrier overflow and Auger recombination—through optimized QW compositions and semipolar GaN substrates to minimize polarization fields.^[20] Commercialization faced barriers like scaling high-quality epitaxial growth and cost-effective fabrication, but partnerships such as with Toyoda Gosei enabled market-ready blue LEDs by the mid-1990s, with EQEs exceeding 36% achieved in research by 2002.^[20] This work culminated in the 2014 Nobel Prize in Physics, shared with Nakamura, recognizing the invention's role in enabling white LEDs by coating blue emitters with yellow phosphors to produce broad-spectrum light twice as efficient as fluorescent lamps.^[2]

Recognition and Awards

Major Scientific Honors

Isamu Akasaki received the Nobel Prize in Physics in 2014, shared with Hiroshi Amano and Shuji Nakamura, "for the invention of efficient blue light-emitting diodes which has enabled bright and energy-saving white light sources." The award, which included a prize amount of SEK 8 million to be shared equally among the laureates, was presented at a ceremony in Stockholm on December 10, 2014, with the selection committee highlighting the transformative impact of blue LEDs on energy-efficient lighting and their role in enabling affordable, long-lasting illumination worldwide. This honor underscored Akasaki's foundational work on gallium nitride (GaN) semiconductors, which overcame longstanding challenges in producing high-quality crystals necessary for blue light emission. In 2009, Akasaki was awarded the Kyoto Prize in Advanced Technology by the Inamori Foundation, recognizing his pioneering contributions to GaN-based optoelectronics, including the development of high-quality GaN crystals and their application in blue light-emitting devices. The prize, valued at 100 million Japanese yen and including a diploma and medal, was conferred during a ceremony in Kyoto on November 10, 2009, with the foundation emphasizing how Akasaki's innovations laid the groundwork for practical blue LEDs and lasers, revolutionizing solid-state lighting and optical technologies. Akasaki earned the IEEE Edison Medal in 2011 from the Institute of Electrical and Electronics Engineers (IEEE), awarded for his pioneering contributions to the invention of blue light-emitting diodes (LEDs) and lasers. Presented at the IEEE Honors Ceremony in New York on June 7, 2011, this medal, one of the highest honors in electrical engineering, highlighted Akasaki's leadership in advancing GaN-based semiconductor technology, which enabled energy-efficient blue LEDs and their integration into broader optoelectronic applications, as noted by the IEEE awards committee for its profound engineering impact.

National and International Distinctions

In 1997, Akasaki was awarded the Medal with Purple Ribbon by the Japanese government, recognizing his significant contributions to academic and artistic developments in semiconductor technology.^[13] This honor, one of Japan's highest for scholarly achievements, underscored his pioneering role in advancing gallium nitride-based devices, which bolstered Japan's leadership in materials science innovation.^[25] In 2004, Akasaki was designated a Person of Cultural Merits by the Japanese government, acknowledging his outstanding contributions to the promotion of culture and scholarship through advancements in semiconductor technology.^[4] Akasaki received the Asahi Prize in 2001 from the Asahi Shimbun, honoring his outstanding accomplishments in the field of academics, particularly for breakthroughs in blue light-emitting diodes that transformed energy-efficient lighting technologies.^[4] In 2002, he was further distinguished with the Order of the Rising Sun, Gold Rays with Neck Ribbon, a national decoration acknowledging his sustained impact on Japan's technological progress in optoelectronics.^[8] The pinnacle of his national recognition came in 2011 when Akasaki was conferred the Order of Culture by Emperor Akihito at the Imperial Palace, the highest cultural honor in Japan, for his lifetime contributions to semiconductor technology and its role in national innovation.^[4] This award highlighted how his research on gallium nitride semiconductors supported Japan's strategic advancements in energy-saving technologies and global competitiveness in electronics.^[26] On the international stage, Akasaki shared the 2015 Charles Stark Draper Prize for Engineering from the U.S. National Academy of Engineering with Shuji Nakamura, Nick Holonyak Jr., M. George Craford, and Russell Dupuis, for the invention, development, and commercialization of gallium nitride-based blue light-emitting diodes. The $500,000 prize recognized the societal benefits of LED technology in energy-efficient lighting.^[27] Akasaki's work also earned the 2021 Queen Elizabeth Prize for Engineering, shared with Shuji Nakamura, Nick Holonyak Jr., M. George Craford, and Russell Dupuis, for the invention and development of LED lighting that revolutionized sustainable illumination worldwide.^[28] The prize, worth £1 million, was presented in a ceremony emphasizing the environmental impact of their innovations, with the award accepted on Akasaki's behalf by representatives from Meijo University.^[29] These distinctions complemented his earlier scientific honors, such as the Nobel Prize, by focusing on the engineering and policy implications of his contributions to global energy efficiency.^[30]

Later Life and Legacy

Personal Life

Isamu Akasaki was married to Ryoko Akasaki, with whom he shared a life in Nagoya, Japan, beginning in the 1960s as his career took root there.^[31]^[10] The couple had two daughters.^[9] Their partnership emphasized mutual support, with Akasaki expressing gratitude for the encouragement from his family amid his demanding research pursuits.^[32] Akasaki's personal interests reflected a thoughtful and reflective disposition, including a longstanding appreciation for classical music and extensive reading, habits he cultivated during his student days and likely carried into adulthood.^[10] Rooted in his Kagoshima origins—where he grew up exploring the natural landscapes of southern Japan—he favored a simple, unpretentious lifestyle that contrasted with the acclaim of his scientific achievements.^[9]^[10] He approached work-life balance with intense dedication, famously summarizing his philosophy as "no pain, no gain," while viewing his mentorship of students as an extension of familial bonds, often prioritizing their growth over personal publicity.^[32]^[33] Akasaki shunned the spotlight, maintaining a low profile that allowed his wife to stand by his side during rare public moments, such as the 2014 Nobel banquet.^[34]^[31]

Death and Posthumous Impact

Isamu Akasaki died on April 1, 2021, at the age of 92 in a hospital in Nagoya, Japan, from pneumonia.^[34]^[9] His family held a private funeral service, while public tributes poured in from academic institutions and scientific organizations. Meijo University, where Akasaki had served as a distinguished professor, issued an official statement mourning his loss and highlighting his contributions to semiconductor technology.^[5] Nagoya University, his longtime affiliate, also expressed condolences, emphasizing his role in advancing nitride semiconductor research.^[11] The Japanese government acknowledged his passing through official channels, recognizing his national impact on science and innovation.^[14] Akasaki's invention of the blue LED has had a profound posthumous impact, enabling the global proliferation of energy-efficient solid-state lighting that has transformed everyday illumination and display technologies. Switching all cities to LED lighting could save approximately 1.4 billion tonnes of CO2 cumulatively by 2030 through substantial energy savings compared to traditional incandescent bulbs.^[35] His breakthroughs influenced international standards for solid-state lighting, promoting efficient, mercury-free alternatives that support sustainable development goals.^[28] Furthermore, Akasaki's perseverance in overcoming scientific challenges has inspired generations of young researchers in Asia and beyond to pursue innovations in optoelectronics.^[36] In 2021, Akasaki was awarded the Queen Elizabeth Prize for Engineering, shared with collaborators, for the creation and development of efficient blue light-emitting diodes that underpin modern LED technology.^[37] The Akasaki Research Center at Nagoya University continues his legacy through ongoing projects in gallium nitride-based devices, including explorations into quantum applications such as high-efficiency optoelectronic components for emerging technologies.^[38]

References

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Isamu Akasaki – Facts - NobelPrize.org
Isamu Akasaki. © Nobel Prize Outreach. Photo: A. Mahmoud. Isamu Akasaki Nobel Prize in Physics 2014. Born: 30 January 1929, Chiran, Japan. Died: 1 ...
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Isamu Akasaki,, Japanese citizen. Born 1929 in Chiran, Japan. Ph.D. 1964 from Nagoya University, Japan. Professor at Meijo University, Nagoya, and ...
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Autobiography of Isamu Akasaki Aug.,2014 - 名城大学
He also edited 12 books. He has been awarded 117 Japanese and 104 foreign patents related to nitrides.
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Isamu Akasaki – Biographical - NobelPrize.org
Research Associate, Assistant Professor and Associate Professor, Department of Electronics, Nagoya University.
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[Obituary] Professor, Dr. Isamu Akasaki Passes Away - 名城大学
Apr 2, 2021 · This is to inform you that Professor Isamu Akasaki passed away from pneumonia on 1st April,2021 at a hospital in Nagoya.
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The Nobel Prize in Physics 2014 was awarded jointly to Isamu Akasaki, Hiroshi Amano and Shuji Nakamura for the invention of efficient blue light-emitting ...
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ISAMU AKASAKI | Memorial Tributes: Volume 25
He was born January 30, 1929, to Suguo and Sumi Akasaki; his father was a Buddhist altar craftsman. His elder brother, Masanori Akasaki, became a plasma ...Missing: Kagoshima | Show results with:Kagoshima
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Profile. Born in Kagoshima Prefecture in 1929, Dr Isamu Akasaki graduated from the Department of Chemistry, Faculty of Science, Kyoto University, in 1952.Missing: occupation | Show results with:occupation
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Nov 1, 2021 · When he was a child, his father gave him ore specimens that started his strong interest in crystals. He graduated from the Faculty of Science at ...Missing: occupation family background
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Oct 7, 2014 · Distinguished Professor Isamu Akasaki became a Research Associate in the Nagoya University School of Engineering in 1959 and, after serving ...
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1929: Born in Chiran, Kagoshima, Japan ; 1952: B. Sc., Kyoto University ; 1964: D. Eng., Nagoya University ; 1952: Kobe Kogyo Corporation (currently Fujitsu Ltd.).Missing: family background
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I was born in Hamamatsu, Shizuoka Prefecture, Japan, on September 11, 1960, to my father Tatsuji and mother Yoshiko, and I grew up with younger brother Takashi.<|separator|>
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Oct 7, 2014 · In 1992 he was appointed as a Professor in the Meijo University School of Science and Engineering, and in December 2004 became a Distinguished ...
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In 1964 he received his doctorate of engineering degree from Nagoya University—the title of his thesis was “Vapor phase epitaxial growth of Ge”—and moved to ...Missing: training | Show results with:training
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Akasaki Isamu | Biography, Nobel Prize, & Facts - Britannica
Oct 8, 2025 · Akasaki Isamu ; Born: January 30, 1929, Chiran, Japan ; Died: April 1, 2021, Nagoya (aged 92) ; Awards And Honors: Nobel Prize (2014).
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The Akasaki Institute was built to commemorate the research achievements of Distinguished Professor Isamu Akasaki, promote original and cutting-edge scientific ...Missing: Future 2017 founding
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[PDF] Isamu Akasaki - Nobel Lecture: Fascinated Journeys into Blue Light
INTRODUCTION. “In the beginning there was light,” emphasizes how closely light is tied to our lives. Light is indispensable for mankind and for many other ...
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In 1989, Akasaki and Amano achieved a major breakthrough when ... 4 Gbps direct modulation of 450 nm GaN laser for high-speed visible light communication.
[23]
Isamu Akasaki – Nobel Lecture - NobelPrize.org
Isamu Akasaki delivered his Nobel Lecture on 8 December 2014, at Aula Magna, Stockholm University. He was introduced by Professor Per Delsing.
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Sep 3, 2012 · The continuous wave laser irradiation at room temperature could be achieved successfully by reducing the threshold current to 60 mA (4 kA/cm2).
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Japanese Nobel laureate Isamu Akasaki, inventor of blue LED, dies
Apr 2, 2021 · Akasaki, born in Kagoshima Prefecture in Japan's southwest, graduated from Kyoto University in 1952 before working at Matsushita Electric ...Missing: family background
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He graduated in electrical engineering at the University of Kyoto in 1952. After working for the electronics company Kobe Kogyo Corporation (now Fujitsu), he ...Missing: training education degrees<|control11|><|separator|>
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Profs. Isamu Akasaki and Nick Holonyak Jr. honored for development of LED lighting. For Immediate Release. Pennington, NJ – The Electrochemical Society (ECS) is ...
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Isamu Akasaki receiving his Nobel Prize from His Majesty King Carl XVI Gustaf of Sweden at the Stockholm Concert Hall, 10 December 2014.<|control11|><|separator|>
[31]
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Apr 6, 2021 · Isamu Akasaki, 92, Dies; Nobel Winner Lit Up the World With LEDs ... A physicist, he shared the prize with two others for their breakthrough in ...
[34]
Cities' road to 2050: Lighting the way to sustainable growth
Oct 12, 2023 · If all cities flipped the switch to LED lighting, the world could save around 1.4bn tonnes of CO2 by 2030. [5]. Signify believes that ...
[35]
Isamu Akasaki in memoriam | Nature Photonics
Jul 29, 2021 · Isamu Akasaki, a long-standing professor at Meijo University in Nagoya, Japan, passed away on the morning of 1 April 2021.
[36]
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[37]
Akasaki Research Center
Contact us. 直線上に配置. Akasaki Research Center (ARC) Nagoya University Graduate School of Engineering. 直線上に配置.