Class
• | 1. Mathematical and Physical Sciences | [X] |
| 1 | Name: | Dr. Joanna Aizenberg | | Institution: | Harvard University | | Year Elected: | 2016 | | Class: | 1. Mathematical and Physical Sciences | | Subdivision: | 103. Engineering | | Residency: | Resident | | Living? : |
Living
| | Birth Date: | 1960 | | | | | Joanna Aizenberg pursues a broad range of research interests that include biomimetics, smart materials, wetting phenomena, bio-nano interfaces, self-assembly, crystal engineering, surface chemistry, structural color and biomineralization. She received the B.S. degree in Chemistry in 1981, the M.S. degree in Physical Chemistry in 1984 from Moscow State University, and the Ph.D. degree in Structural Biology from the Weizmann Institute of Science in 1996.
After spending nearly a decade at Bell Labs, Joanna joined Harvard University, where she is the Amy Smith Berylson Professor of Materials Science, Professor of Chemistry and Chemical Biology, Director of the Kavli Institute for Bionano Science and Technology and Platform Leader in the Wyss Institute for Biologically Inspired Engineering. The Aizenberg lab's research is aimed at understanding some of the basic principles of biological architectures and the economy with which biology solves complex problems in the design of multifunctional, adaptive materials. She then uses biological principles as guidance in developing new, bio-inspired synthetic routes and nanofabrication strategies that would lead to advanced materials and devices, with broad implications in fields ranging from architecture to energy efficiency to medicine.
Aizenberg is elected to the American Academy of Arts and Sciences, American Philosophical Society, American Association for the Advancement of Science; and she is a Fellow of American Physical Society and Materials Research Society. Dr. Aizenberg received numerous awards from the American Chemical Society and Materials Research Society, including Fred Kavli Distinguished Lectureship in Nanoscience, Ronald Breslow Award for the Achievement in Biomimetic Chemistry, Arthur K. Doolittle Award in Polymeric Materials, ACS Industrial Innovation Award, and was recognized with two R&D 100 Awards for best innovations in 2012 and 2013 for the invention of a novel class of omniphobic materials and watermark ink technologies. In 2015 she received Harvard’s most prestigious Ledlie Prize that is awarded for the most valuable contribution to science made by a Harvard scientist.
Joanna has served at the Board of Directors of the Materials Research Society and at the Board on Physics and Astronomy of the National Academies. She served on the Advisory Board of Langmuir and Chemistry of Materials, on Board of Reviewing Editors of Science Magazine, and is an Editorial Board Member of Advanced Materials. | |
2 | Name: | Dr. Frances H. Arnold | | Institution: | California Institute of Technology | | Year Elected: | 2018 | | Class: | 1. Mathematical and Physical Sciences | | Subdivision: | 103. Engineering | | Residency: | Resident | | Living? : |
Living
| | Birth Date: | 1956 | | | | | Linus Pauling Professor of Chemical Engineering, Bioengineering and Biochemistry at Caltech, Frances Arnold pioneered protein engineering by directed evolution, with applications in alternative energy, chemicals, and medicine. She uses evolution augmented with machine learning to circumvent our profound ignorance of how DNA encodes function and create new biological molecules. She has been recognized by induction into the US National Academies of Science, Medicine, and Engineering, the American Academy of Arts and Sciences, the National Inventors Hall of Fame, and the Pontifical Academy of Sciences.
Her awards include the Charles Stark Draper Prize of the National Academy of Engineering (2011), the US National Medal of Technology and Innovation (2011), the Millennium Technology Prize (2016), the National Academy of Sciences’ Sackler Prize in Convergence Research (2017), and the Franklin Institute's Bower Award and Prize for Achievement in Science (2019). Frances Arnold won the 2018 Nobel Prize in Chemistry for her work on directed evolution of enzymes. Arnold pioneered the 'directed evolution' technique, which is now used by hundreds of laboratories and companies to produce more useful enzymes.
Dr. Arnold chairs the Advisory Panel of the David and Lucile Packard Foundation Fellowships in Science and Engineering and is a Trustee of the Gordon Research Conferences. She co-founded Gevo, Inc. in 2005 to make fuels and chemicals from renewable resources and Provivi, Inc. in 2014 to develop non-toxic modes of agricultural pest control. | |
3 | Name: | Mr. Norman R. Augustine | | Institution: | Lockheed Martin Corporation | | Year Elected: | 1997 | | Class: | 1. Mathematical and Physical Sciences | | Subdivision: | 103. Engineering | | Residency: | Resident | | Living? : |
Living
| | Birth Date: | 1935 | | | | | Norman R. Augustine was raised in Colorado and attended Princeton University where he graduated with a BSE in Aeronautical Engineering, magna cum laude, and MSE and was elected to Phi Beta Kappa, Tau Beta Pi and Sigma Xi. In 1958, he joined the Douglas Aircraft Company in California where he held titles of Program Manager and Chief Engineer. Beginning in 1965, he served in the Pentagon in the Office of Secretary of Defense as an Assistant Director of Defense Research and Engineering. Joining the LTV Missiles and Space Company in 1970, he served as Vice President, Advanced Programs and Marketing. In 1973, he returned to government as Assistant Secretary of the Army and in 1975 as Under Secretary of the Army and later as Acting Secretary of the Army. Joining Martin Marietta Corporation in 1977, he served as Chairman and CEO from 1988 and 1987, respectively, until 1995, having previously been President and Chief Operating Officer. He served as President of Lockheed Martin Corporation upon the formation of that company in 1995, and became its Chief Executive Officer on January 1, 1996, and later Chairman. Retiring as an employee of Lockheed Martin in August 1997, he joined the faculty of the Princeton University School of Engineering and Applied Science where he served as Lecturer with the Rank of Professor until July 1999. In 2019 he and his wife endowed three Professorships in Princeton's School of Engineering with the goal of addressing global challenges and creating the next generation of scientific leaders. Mr. Augustine served as Chairman and Principal Officer of the American Red Cross for nine years and as Chairman of the National Academy of Engineering, the Association for the United States Army, the Aerospace Industry Association, and the Defense Science Board. He is a former President of the American Institute of Aeronautics and Astronautics and the Boy Scouts of America. He has been a member of the Board of Directors of ConocoPhillips, Black & Decker, Procter & Gamble and Lockheed Martin and a member of the Board of Trustees of Colonial Williamsburg, Johns Hopkins, Princeton University and the Massachusetts Institute of Technology. He is currently a Regent of the University System of Maryland. He is a 16-year member of the President's Council of Advisors on Science and Technology and serves on the Department of Homeland Security Advisory Board and was a member of the Hart/Rudman Commission on National Security. Mr. Augustine has been presented the National Medal of Technology by the President of the United States, has five times been awarded the Department of Defense's highest civilian decoration, the Distinguished Service Medal, and has received the Joint Chiefs of Staff Distinguished Public Service Award. He recently received the 2013 CRDF Global George Brown Award for International Scientific Cooperation. He is co-author of The Defense Revolution and Shakespeare in Charge and author of Augustine's Laws and Augustine's Travels. He holds twenty-three honorary degrees and was selected by Who's Who in America and the Library of Congress as one of the Fifty Great Americans on the occasion of Who's Who's fiftieth anniversary. He has traveled in over 100 countries and stood on both the North and South Poles. | |
4 | Name: | Dr. Manson Benedict | | Institution: | Massachusetts Institute of Technology | | Year Elected: | 1977 | | Class: | 1. Mathematical and Physical Sciences | | Subdivision: | 103. Engineering | | Residency: | Resident | | Living? : |
Deceased
| | Birth Date: | 1907 | | Death Date: | September 18, 2006 | | | |
5 | Name: | Dr. Dawn A. Bonnell | | Institution: | University of Pennsylvania | | Year Elected: | 2024 | | Class: | 1. Mathematical and Physical Sciences | | Subdivision: | 103. Engineering | | Residency: | Resident | | Living? : |
Living
| | Birth Date: | 1961 | | | | | Dr. Bonnell is the is the Henry Robinson Towne Professor of Engineering and Applied Science and the Senior Vice Provost for Research at the University of Pennsylvania. She received her B.A. and PhD from the University of Michigan and was a Fulbright scholar to the Max-Planck-Institute in Stuttgart, Germany.
Dr. Bonnell is recognized for advances in atomic imaging and local electronic structure of complex surfaces, obtaining the first scanning probe images of atoms on oxide surfaces, a result that generated a new field of research. She has advanced probes of local properties, interfaces in electronic and plasmonic hybrid nanostructures, and ferroelectric nanolithography. She has served as President AVS: Science and Technology Society and vice President of the American Ceramic Society. She has authored or coauthored over 250 publications and edited or coedited seven books.
Dr. Bonnell received the Sosman Award from the American Ceramic Society, the AVS Nanotechnology Award, the Staudinger/Durrer Medal from ETH Zurich, and several distinguished lectureships. She is a fellow of the Materials Research Society, Honorary Fellow of the AVS, Distinguished Life Fellow of the ACerS, and a member of the National Academy of Engineering. | |
6 | Name: | Dr. William F. Brinkman | | Institution: | United States Department of Energy | | Year Elected: | 2002 | | Class: | 1. Mathematical and Physical Sciences | | Subdivision: | 103. Engineering | | Residency: | Resident | | Living? : |
Living
| | Birth Date: | 1938 | | | | | William F. Brinkman received a Ph.D. in physics at the University of Missouri in 1965. He joined Bell Laboratories in 1966 after spending one year as an NSF Postdoctoral Fellow at Oxford University. In 1972, he became head of the Infrared Physics and Electronics Research Department, and in 1974 he became the director of the Chemical Physics Research Laboratory. He held the position of director of the Physical Research Laboratory from 1981 until moving to Sandia in 1984. He returned to Bell Laboratories in 1987 to become executive director of the Physics Research Division. In 1993 he became Physical Sciences Research Vice President, and in January 2000 became Vice President, Research. He retired from this position in September 2001. He then served as president of the American Physical Society and senior research associate in the Department of Physics at Princeton University until June 2009 when he was confirmed by the U.S. Senate as Director of the Office of Science in the United States Department of Energy. Overseeing the nation's research programs in fusion energy sciences and nuclear and high-energy physics, the Office is the country's single largest supporter of basic research in the physical sciences. He retired from the position in 2013.
William Brinkman's personal research covered materials classes of great engineering significance such as metals, semiconductors, superconductors and liquid crystals. He contributed significantly in the understanding of correlated electron motion, electron-hole liquid formation, exotic superfluid states and defects in liquid crystals. His technical leadership for the development of Wavelength Division Multiplexing (WDM) for high capacity communications systems and optical fiber fabrication has revolutionized long distance transmission. He has chaired many committees shaping the national policy for technology development and science. A contribution of singular importance is the 8 volume 1986 NRC "Brinkman Report" on the status of physics.
He is a member of the National Academy of Sciences, the American Academy of Arts & Sciences, and the American Physical Society. He was elected a member of the American Philosophical Society in 2002. | |
7 | Name: | Dr. George F. Carrier | | Institution: | Harvard University | | Year Elected: | 1976 | | Class: | 1. Mathematical and Physical Sciences | | Subdivision: | 103. Engineering | | Residency: | Resident | | Living? : |
Deceased
| | Birth Date: | 1918 | | Death Date: | March 8, 2002 | | | |
8 | Name: | Dr. Alfred Y. Cho | | Institution: | Bell Laboratories, Lucent Technologies | | Year Elected: | 1996 | | Class: | 1. Mathematical and Physical Sciences | | Subdivision: | 103. Engineering | | Residency: | Resident | | Living? : |
Living
| | Birth Date: | 1937 | | | | | Alfred Y. Cho was born July 10, 1937 in Beijing, China. He retired as the Semiconductor Research Vice President, Bell Laboratories, Lucent Technologies in 2001. He received his B.S., M.S., and Ph.D. in electrical engineering from the University of Illinois in 1960, 1961, and 1968, respectively. In 1961, prior to obtaining his Ph.D. degree, he worked at Ion Physics Corporation, Burlington, Massachusetts, a subsidiary of High Voltage Engineering Corporation, where he studied charged micron-sized solid particles in high electric fields. In 1962, he joined TRW-Space Technology Laboratories, Redondo Beach, California, and engaged in research in high current density ion beams. He returned to the University of Illinois in 1965 and received a Ph.D. degree in electrical engineering in 1968. Upon his graduation in 1968, he joined Bell Laboratories, Murray Hill, New Jersey as a Member of Technical Staff and was promoted to Department Head in 1984. He was named Director of the Materials Processing Research Laboratory in 1987 and Semiconductor Research Vice President in 1990. He is now an Adjunct Semiconductor Research Vice President, Bell Labs, Lucent Technologies, and an Adjunct Professor at the University of Illinois. He has made seminal contributions to materials science and physical electronics through his pioneering development of the molecular beam epitaxy (MBE) crystal growth process. He demonstrated that MBE could be used to prepare epitaxial films one atomic layer at a time, with exceptional control at atomic dimensions and further showed that these films could be the basis of devices with never before realized electrical and optical properties. His work has bridged many disciplines ranging from fundamental quantum physics, through epitaxial crystal growth, to device fabrication and testing. The capabilities of MBE have allowed new fields of materials research to develop. The ability to precisely make quantum wells has had a far-reaching impact, ranging from classroom physics to revolutions in electronic and optical devices for the consumer electronics, computer and communications industries MBE is broadly used today for advanced multilayer crystal growth and has led to radically new devices including high-speed transistors, microwave devices, laser diodes and detectors. Most of the semiconductor lasers used in today's compact disc players and CD-ROM'S are manufactured using MBE-grown material. Presently, MBE is used to produce the Hall sensors used as disk drive speed controllers for computers and VCRs. High electron mobility transistors (HEMTs) which are utilized as high speed circuit components and in high frequency, low noise, direct broadcast satellite and wireless communications are manufactured by MBE. This impact of MBE on fundamental science has been as dramatic as its impact on semiconductor technology. A significant ongoing contribution of MBE is the experimental generation of low dimensional systems. The discovery of an entirely new state of electrons, the fractional quantized Hall effect, was made possible as a result of MBE crystal quality. More recently (1994) he and coworkers demonstrated a fundamentally new type of laser which is a unipolar intersubband semiconductor laser called the quantum cascade (QC) laser. Dr. Cho has authored over 590 papers in surface physics, crystal growth, and device physics and performance. He holds 75 patents on crystal growth and semiconductor devices related to MBE. He is a recipient of the Electronics Division Award of the Electrochemical Society (1977), the American Physical Society International Prize for New Materials (1982), the IEEE Morris N. Liebmann Award (1982), the GaAs Symposium Award - Ford (1986), the Heinrich Welker Medal - Siemens (1986), the Solid State Science and Technology Medal of the Electrochemical Society (1987), the World Materials Congress Award of ASM International (1988), the Gaede-Langmuir Award of the American Vacuum Society (1988), the Industrial Research Institute Achievement Award of the Industrial Research Institute, Inc. (1988), the New Jersey Governor's Thomas Alva Edison Science Award (1990), the International Crystal Growth Award of the American Association for Crystal Growth (1990), the Asian American Corporate Achievement Award (1992), the AT&T Bell Labs Fellow Award (1992), the National Medal of Science, presented by President Clinton (1993), the Newcomb Cleveland Prize of the American Association for the Advancement of Science (1993-94), the IEEE Medal of Honor (1994), the Materials Research Society Von Hippel Award (1994), The Elliott Cresson Medal of the Franklin Institute (1995), the Computer and Communications Prize of the C & C Foundation, Japan (1995), the New Jersey Inventors Hall of Fame (1997), Honorary Doctor of Engineering, University of Illinois at Urbana-Champaign (1999), the Willis E. Lamb Medal for Laser Physics (2000), the University of Illinois Alumni Achievement Award (2000), the IEEE Third Millennium Medal (2000), the NASA Group Achievement Award (2000), Honorary Doctor of Science Degree, City University of Hong Kong (2000) and the Honorary Doctor of Science, Hong Kong Baptist University (2001), and the 2005 National Medal of Technology, announced and presented by President Bush in 2007. He is a Fellow of the Institute of Electrical and Electronics Engineering, the American Physical Society, and the American Academy of Arts & Sciences. He is a member of the U. S. National Academy of Engineering (1985), the National Academy of Sciences (1985), the Third World Academia of Sciences (1987), the Academia Sinica (1990), the Chinese Academy of Sciences (1996), and the American Philosophical Society (1996). He is married to Mona Willoughby; they have four children, Derek, Deidre, Brynna, and Wendy. His outside interests include painting, calligraphy, photography, table tennis, and most recently, learning how to play golf. | |
9 | Name: | Dr. John Cocke | | Institution: | IBM | | Year Elected: | 1995 | | Class: | 1. Mathematical and Physical Sciences | | Subdivision: | 103. Engineering | | Residency: | Resident | | Living? : |
Deceased
| | Birth Date: | 1925 | | Death Date: | July 16, 2002 | | | |
10 | Name: | Dr. Monica Olvera de la Cruz | | Institution: | Northwestern University | | Year Elected: | 2020 | | Class: | 1. Mathematical and Physical Sciences | | Subdivision: | 103. Engineering | | Residency: | resident | | Living? : |
Living
| | Birth Date: | 1959 | | | | | Monica Olvera de la Cruz is the Lawyer Taylor Professor of Materials Science and Engineering; Professor of Chemistry; Professor of Chemical and Biological Engineering; Professor of Physics and Astronomy; director of the Center for Computation and Theory of Soft Materials; and deputy-director of the Center for Bio-Inspired Energy Science. Monica Olvera de la Cruz obtained her B.A. in physics from the UNAM, Mexico, in 1981, and her Ph.D. in physics from Cambridge University, UK, in 1985. She was a guest scientist (1985-86) in the National Institute of Standards and Technology, Gaithersburg, MD. She joined Northwestern University in 1986, where she is the Lawyer Taylor Professor of Materials Science & Engineering, Professor of Chemistry, Chemical & Biological Engineering and Physics and Astronomy. From 2006-2013 she directed the Materials Research Center at Northwestern. From 1995-97 she was a staff scientist in the Commissariat a l’Energie Atomique, Saclay, France, where she also held visiting scientist positions in 1993 and in 2003. She has developed theoretical models to determine the thermodynamics, statistics and dynamics of macromolecules in complex environments including multicomponent solutions of heterogeneous synthetic and biological molecules, and molecular electrolytes. She was elected a member of the American Philosophical Society in 2020. | |
11 | Name: | Dr. Edward E. David | | Institution: | EED, Inc. | | Year Elected: | 1979 | | Class: | 1. Mathematical and Physical Sciences | | Subdivision: | 103. Engineering | | Residency: | Resident | | Living? : |
Deceased
| | Birth Date: | 1925 | | Death Date: | February 13, 2017 | | | | | Edward E. David was the president of EED, Inc, advisors to industry, government and universities, and consults on research and development, strategic planning and management, intellectual property, technology transfer, enhancing corporate research programs and developing corporate-academic research partnerships for the Washington Advisory Group. He received his doctorate in electrical engineering from the Massachusetts Institute of Technology in 1950 and spent the first two decades of his research career at Bell Telephone Laboratories, ascending to the position of executive director. From 1970-73 Dr. David served as science advisor to the President of the United States and director of the White House Office of Science and Technology Policy. He was also president of Exxon Research and Engineering Company from 1977-86, leading the corporation's research operations in projects both domestically and abroad. Dr. David was on the boards of several businesses and on technical advisory boards nationally and abroad. In 2009 he was awarded the Exceptional Public Service Medal for his outstanding leadership, dedication, and commitment to NASA as a member of the NASA Advisory Council. He was a retired U.S. Representative to the NATO Science Committee as well as a member of the National Academy of Engineering, the National Academy of Sciences, and the American Academy of Arts & Sciences. He was elected a member of the American Philosophical Society in 2017. Edward E. David, Jr., died February 13, 2017, at age 92, at his home in Bedminster, New Jersey. | |
12 | Name: | Dr. Robert H. Dennard | | Institution: | IBM Thomas J. Watson Research Center | | Year Elected: | 1997 | | Class: | 1. Mathematical and Physical Sciences | | Subdivision: | 103. Engineering | | Residency: | Resident | | Living? : |
Deceased
| | Birth Date: | 1932 | | Death Date: | April 23, 2024 | | | | | Robert H. Dennard is a Fellow of the Institute of Electrical and Electronics Engineers (IEEE), a member of the National Academy of Engineering, and a member of the American Philosophical Society. He received the IEEE Cledo Brunetti Award in 1982. In 1988 he was awarded the National Medal of Technology by President Reagan for his invention of the one-transistor dynamic RAM cell. He received the IRI Achievement Award from the Industrial Research Institute in 1989 and the Harvey Prize from Technion, Haifa, Israel, in 1990. Dr. Dennard was inducted into the National Inventors Hall of Fame in Akron, Ohio in 1997. In 2001 he received the Aachener and Munchener Prize for Technology and also was awarded the IEEE Edison Medal. He received the Vladimir Karapetoff Award from Eta Kappa Nu in 2002 and the Lemelson-MIT Lifetime Achievement Award in 2005. Dr. Dennard received NEC’s C&C Prize in 2006 and the Benjamin Franklin Medal in Electrical Engineering in 2007. In 2013, he was awarded the Kyoto Prize in Electronics. In January 2017 he was awarded the National Academy of Sciences' Award for the Industrial Application of Science. Dr. Dennard and his wife Jane Bridges live in Croton-on-Hudson, NY. They are active participants in Scottish Country Dancing and choral singing. | |
13 | Name: | Dr. Mildred S. Dresselhaus | | Institution: | Massachusetts Institute of Technology | | Year Elected: | 1995 | | Class: | 1. Mathematical and Physical Sciences | | Subdivision: | 103. Engineering | | Residency: | Resident | | Living? : |
Deceased
| | Birth Date: | 1930 | | Death Date: | February 20, 2017 | | | | | Mildred Dresselhaus was born in Brooklyn, New York and grew up in a poor section of the Bronx. She attended the New York City public schools through junior high school. She then went to Hunter College High School in New York City and continued her education at Hunter College. She was a Fulbright Fellow at the Cavendish Laboratory, Cambridge University from 1951-52. Next, she earned her master's degree at Radcliffe in 1953 and continued on to get a Ph.D. at the University of Chicago in 1958. Her thesis was on "The Microwave Surface Impedance of a Superconductor in a Magnetic Field." At the University of Chicago she came into contact with Enrico Fermi, one of the great physicists of the 20th century. The "survival" tactics that helped propel her to success were honed in her earliest years; raised in poverty, she learned as a child to protect herself against daily intimidation in a tough New York neighborhood. Dr. Dresselhaus started college planning to go into elementary school teaching. When she was a sophomore at Hunter College, she met Rosalyn Yalow, who taught her physics and later became a Nobel Laureate in medicine (1977). It was in part due to her interactions with Rosalyn Yalow that Dr. Dresselhaus recognized her potential as a physicist and developed higher goals for herself. Also coming from a disadvantaged background, Yalow encouraged the young undergraduate to press ahead despite detractors, taught her to recognize and seize opportunity, and followed her career as it unfolded with "advice and love". Mildred Dresselhaus moved to Cornell University to complete her NSF sponsored Post-Doctoral fellowship where she continued her studies on superconductivity. After her post-doctorate days were over, she and her husband moved to the Boston area where they both got jobs at the Massachusetts Institute of Technology's Lincoln Laboratory in Lexington, Massachusetts. Both worked at Lincoln Labs for the next 7 years. At the Lincoln Laboratory, she switched from research on superconductivity to magneto-optics and carried out a series of experiments that led to a fundamental understanding of the electronic structure of semimetals, especially graphite. With four young children, she was invited in 1967 by Louis Smullin, head of the Electrical Engineering Department, to come to MIT and be a visiting professor for a year. She was so enthusiastic about teaching undergraduates and graduate students, and about working with graduate students on research projects, that she was in 1968 appointed as a tenured full professor. She remained on the MIT faculty throughout her career, pursuing an intense research and teaching career in the area of electronic materials. A leader in promoting opportunities for women in science and engineering, Dr. Dresselhaus received a Carnegie Foundation grant in 1973 to encourage women's study of traditionally male dominated fields, such as physics. In 1973, she was appointed to The Abby Rockefeller Mauze chair, an Institute-wide chair, endowed in support of the scholarship of women in science and engineering. She greatly enjoyed her career in science. As Dr. Dresselhaus says about working with MIT students, "I like to be challenged. I welcome the hard questions and having to come up with good explanations on the spot. That's an experience I really enjoy." She has over her career graduated over 60 Ph.D. students and has given many invited lectures worldwide on her research work. Her later research interests were on little tiny things, which go under the name of nanostructures, carbon nanotubes, bismuth nanowires and low dimensional thermoelectricity. Awards received include the Karl T. Compton Medal for Leadership in Physics from the American Institute of Physics (2001); the Medal of Achievement in Carbon Science and Technology from the American Carbon Society (2001); honorary membership in the Ioffe Institute of the Russian Academy of Sciences (2000); the National Materials Advancement Award of the Federation of Materials Societies (2000); 19 honorary doctorate degrees; the Nicholson Medal of the American Physical Society (2000); the Weizmann Institute's Millennial Lifetime Achievement Award (2000); UNESCO's Award for Women in Science (2007); the University of Chicago's Alumni Medal (2008); the Presidential Enrico Fermi Award (2012); the Kavli Prize from the Norwegian Academy of Science and Letters (2012), the Presidential Medal of Freedom, and the IEEE Medal of Honor (2015). She is a member of the National Academy of Sciences and the National Academy of Engineering. She was elected a member of the American Philosophical Society in 1995. Mildred Dresselhaus died February 20, 2017, in Cambridge, Massachusetts at the age of 86. | |
14 | Name: | Mr. Roger L. Easton | | Institution: | Naval Research Laboratory & KERNCO & New Hampshire Electric Cooperative | | Year Elected: | 1998 | | Class: | 1. Mathematical and Physical Sciences | | Subdivision: | 103. Engineering | | Residency: | Resident | | Living? : |
Deceased
| | Birth Date: | 1921 | | Death Date: | May 8, 2014 | | | | | Roger Easton was born in a small village in northern Vermont to a town doctor and his school teacher wife. He and his older brothers and one younger sister went to local schools where they had very good teachers. He followed his older brother to Middlebury College where he was graduated during World War II. He went to work at the Naval Research Laboratory in 1943 with his initial work being on blind landing system for aircraft. In 1945 he was married to the former Barbara Coulter of Flint, Michigan. They had five children, three girls and two boys and five grandchildren. Two of the girls died in adulthood of two different cancers. When the development of rockets became important, he joined the Rocket Sonde branch and participated in the proposal that put NRL in the satellite launching business. He designed the Vanguard I satellite, now the oldest in space. Following the launch of the Russian Sputnik, he conceived the U.S. Navy Space Surveillance System, an electronic fence extending across the southern U.S. and detecting all satellites that crossed it. Later he added another fence parallel to the first one. With the two fences we were able to obtain near instantaneous orbital elements on all space objects crossing both fences. The second fence was a continuous wave radar type with timing signals sent by the transmitter and detected over the horizon and by reflection. With this fence it was possible to locate the satellites very accurately. However, the fence had one problem: that cesium-beam clocks had to be carried between the transmitter and the receiver in order to synchronize them. From this operation came the idea of having a satellite carry the clock and, since both the transmitter and the receiver would be visible simultaneously, the clock would not need to be a very stable device - a crystal oscillator would do. A few weeks later the idea appeared that this might be the basis of a navigation device with a great virtue of being capable of measuring range and of being passive so the user need not interrogate the satellite and hence the system would not be overloaded. Following these thoughts a simplified version was demonstrated to personnel from the Naval Air Systems Command. A work order followed and two satellites were used for the time transfer between England, Australia, New Zealand and the U.S. These satellites used crystal oscillators as their timing sources. The next satellite used a rubidium clock designed by E. Jechart of Germany. Two of them were modified at NRL for use in space, the first ones so used. The next satellite, called either TIMATIONS 4 or NDS 2 (for Navigations Development Satellite) was launched on June 23, 1977 into a 12 hour orbit with cesium beam clocks and almost all of the characteristics of the GPS satellites. With this satellite we were able to measure the change in frequency due to gravitation very well and very close to that predicted by Einstein's general theory of gravitation. In 1980 Roger and Mrs. Easton retired to Canaan, New Hampshire where he started a career in public service. In 1982, he was elected in the first of two terms to the New Hampshire General Court and he later ran, unsuccessfully, for Governor. He served three terms as director of the New Hampshire Electric Cooperative, and he has served on the Planning Board for the Town of Canaan. Awards he has received include the following: The Navy Distinguished Civilian Service Award; The Institute of Navigation Thurlow Award; and the Sigma Xi Applied Science Award. Two awards are named for him - one for Space Surveillance and one for Space Navigation. In 1996 Roger Easton was inducted into the GPS Hall of Fame and in 2010 he was inducted into the National Inventors Hall of Fame. In 1997 he was awarded the Magellanic Premium Award of the American Philosophical Society and, in 1998, he was elected to the Society. | |
15 | Name: | Dr. Harold E. Edgerton | | Institution: | Massachusetts Institute of Technology | | Year Elected: | 1972 | | Class: | 1. Mathematical and Physical Sciences | | Subdivision: | 103. Engineering | | Residency: | Resident | | Living? : |
Deceased
| | Birth Date: | 1903 | | Death Date: | 1/4/90 | | | |
16 | Name: | Dr. Hiroshi Inose | | Institution: | National Institute of Informatics | | Year Elected: | 1979 | | Class: | 1. Mathematical and Physical Sciences | | Subdivision: | 103. Engineering | | Residency: | International | | Living? : |
Deceased
| | Birth Date: | 1927 | | Death Date: | October 11, 2000 | | | |
17 | Name: | Dr. Irwin Mark Jacobs | | Institution: | Qualcomm Inc.; Salk Institute for Biological Studies | | Year Elected: | 2013 | | Class: | 1. Mathematical and Physical Sciences | | Subdivision: | 103. Engineering | | Residency: | Resident | | Living? : |
Living
| | Birth Date: | 1933 | | | | | Irwin Mark Jacobs is Founding Chairman and CEO Emeritus of Qualcomm, a company he co-founded in 1985. As CEO through 2005 and Chairman through 2009, he led the growth from startup to Fortune 500 Company, now with over 28,000 employees worldwide. Qualcomm pioneered the development and commercialization of CDMA wireless technology, the basis for all third-generation cellular networks which now provide voice and broadband Internet access for over 1.6 billion customers. Qualcomm is the world’s largest semiconductor supplier for wireless products and a leader in introducing fourth-generation technology. For 15 consecutive years, QUALCOMM has been named to Fortune’s list of The 100 Best Companies To Work For.
Dr. Jacobs previously served as co-founder, CEO and chairman of LINKABIT Corporation, leading the development of Very Small Aperture Earth Terminals (VSATs) and the VideoCipher® satellite-to-home TV system. LINKABIT merged with M/A-COM in August 1980, and Dr. Jacobs served as executive vice president and a member of the board of directors until his resignation in April 1985. Over 100 San Diego communications companies trace their roots to LINKABIT.
From 1959 to 1966, Dr. Jacobs was an assistant, then associate professor of electrical engineering at Massachusetts Institute of Technology (MIT). From 1966 to 1972 he served as professor of computer science and engineering at the University of California, San Diego (UCSD). While at MIT, Dr. Jacobs co-authored with Jack Wozencraft a textbook in digital communications Principles of Communication Engineering. First published in 1965, the book remains in use today.
Dr. Jacobs received a bachelor's degree in electrical engineering in 1956 from Cornell University and Master of Science and Doctor of Science degrees in electrical engineering from MIT in 1957 and 1959, respectively. He holds fourteen CDMA patents.
Dr. Jacobs was named Chair of the Board of Trustees of the Salk Institute In November 2006 and served as Chair of the National Academy of Engineering from 2008 to 2012. He serves on the UCSD Foundation Board of Trustees in addition to the UC San Diego Health System Advisory Board and is past chairman of the University of California President’s Engineering Advisory Council. In June 2011, he was appointed by The Secretary of Education to serve on the Board of the National Center for Research in Advanced Information and Digital Technologies (aka, Digital Promise). Additionally, Dr. Jacobs is a board member of the Lang Lang Foundation, the Technion Board of Governors, the International Innovation and Entrepreneurship Board of Overseers of KACST in Saudi Arabia, the Pacific Council on International Policy, and has served on the Advisory Board of the Tsinghua University School of Economics and Management since its formation in 2000.
He is the recipient of numerous industry, education and business awards, including the National Medal of Technology in 1994 and the IEEE Medal of Honor in 2013. Irwin Jacobs was elected a member of the American Philosophical Socity in 2013. In 2015 he was awarded the Carnegie Medal of Philanthropy. | |
18 | Name: | Prof. Jack St. Clair Kilby | | Year Elected: | 2001 | | Class: | 1. Mathematical and Physical Sciences | | Subdivision: | 103. Engineering | | Residency: | Resident | | Living? : |
Deceased
| | Birth Date: | 1923 | | Death Date: | June 20, 2005 | | | |
19 | Name: | Dr. Augustus B. Kinzel | | Year Elected: | 1963 | | Class: | 1. Mathematical and Physical Sciences | | Subdivision: | 103. Engineering | | Residency: | Resident | | Living? : |
Deceased
| | Birth Date: | 1900 | | Death Date: | 10/23/87 | | | |
20 | Name: | Dr. Vladimir Kučera | | Institution: | Czech Institute of Informatics, Robotics and Cybernetics, Czech Technical University; Academy of Sciences of the Czech Republic | | Year Elected: | 2023 | | Class: | 1. Mathematical and Physical Sciences | | Subdivision: | 103. Engineering | | Residency: | International | | Living? : |
Living
| | Birth Date: | 1943 | | | | | Vladimír Kučera was born in Prague, Czechoslovakia in 1943. He received the graduate degree summa cum laude in electrical engineering from Czech Technical University, Prague, in 1966 and the CSc. and DrSc. research degrees in engineering cybernetics from the Czechoslovak Academy of Sciences, Prague, in 1970 and 1979, respectively.
During 1967-2017 he was a Research Scientist at the Institute of Information Theory and Automation, one of the research institutes of the Academy of Sciences in Prague. He held various research and managerial positions, including Vice-Director (1986-1990) and Director (1990-1998) of the Institute. Since 2018, he has been a Scientist Emeritus at the Academy of Sciences. Starting in 1992, he taught graduate courses at the Czech Technical University in Prague and was appointed Professor of Engineering Cybernetics in 1996. During 1999-2000, he assumed the position of Head of the Control Engineering Department; in 2000 he was elected Dean of the Faculty of Electrical Engineering for the period 2000-2006; and during 2007-2015, he was the Director of the Masaryk Institute of Advanced Studies. In 2015, he was appointed Distinguished Researcher and Vice-Director of the Czech Institute of Informatics, Robotics and Cybernetics, the newly established research institute at the Czech Technical University in Prague.
Kučera held visiting positions at the National Research Council, Ottawa, Canada in 1970-1971; the University of Florida, Gainesville, the USA in 1977; Ecole Nationale Supérieure de Mécanique, Nantes, France in 1981-1982; Australian National University, Canberra, Australia in 1984; Uppsala Universitet, Sweden in 1989; Centro de Investigación y de Estudios Avanzados del IPN, Mexico City in 1991; ETH Zürich, Switzerland in 1992; the University of Newcastle, Australia in 1993; Politecnico di Milano, Italy in 1995 as well as many short visiting appointments. He was a Nippon Steel Professor at the Chair of Intelligent Control at the Tokyo Institute of Technology, Japan, in 1994.
The research interests of Kučera include the theory of systems and automatic control. He contributed to the theory of matrix Riccati equations by classifying the set of all nonnegative definite steady-state solutions, showing that the set is a distributive lattice, and establishing necessary and sufficient conditions for the existence of such solutions in terms of stabilizability and detectability; these results are fundamental for the design of linear-quadratic optimal control systems. He pioneered the use of polynomial diophantine equations in the synthesis of control systems; the polynomial equation approach found followers worldwide and inspired the development of efficient computational algorithms for polynomials and polynomial matrices.
The best-known result of Kučera is the parameterization of all controllers that stabilize a given system, known as the Youla-Kučera parameterization. It was obtained independently and at about the same time by Dante C. Youla and Kučera. The parameterization formula is due to Kučera, whereas the use of the parameter in H2 optimal control is due to Youla. The parameterization result launched an entirely new area of research with applications in optimal and robust control.
Recently, Kučera has resolved a long-standing open problem of control theory, the decoupling of linear systems by static-state feedback. He discovered the canonical form and the complete invariant of stable linear systems with respect to the group of stability-preserving system transformations and demonstrated the use of this result in control system design. During his research career, he had the pleasure of working with more than 80 researchers from 20 countries worldwide.
Kučera is the author of four books: Algebraic Theory of Discrete Linear Control (in Czech) (Academia, Prague 1978), Discrete Linear Control: The Polynomial Equation Approach (Wiley, Chichester 1979), Analysis and Design of Discrete Linear Control Systems (Prentice-Hall, London 1991), and Polynomial Methods for Control Systems Design, edited with M. J. Grimble (Springer, London 1996). In addition, he published over 400 research papers.
Kučera serves on the editorial boards of Int. J. Robust and Nonlinear Control, and Bull. Polish Acad. Sciences. He was Editor-in-Chief of Kybernetika (1990-1998), an Associate Editor of Automatica (1987-1996), and a member of the editorial boards of Syst. Control Letters (1987-1994), Int. J. Control (1990-1999), Int. J. Systems Science (1986-1999), and J. Math. Systems, Estimation and Control (1991-1998). He is a Life Advisor and Fellow (he was President 2002-2005) of the International Federation of Automatic Control (IFAC), Life Fellow of IEEE (the first Fellow ever in the Czech Republic/Czechoslovakia in 1996), and was a member of the IEEE Control Systems Society Board of Governors (1996-1998). He is a founding member and Fellow of the Engineering Academy of the Czech Republic (he was Vice-President from 1999 to 2006) and past Chairman of the Czech Committee for Automatic Control (1993-2002).
Kučera was the recipient of many prizes including the Prize of the Czechoslovak Academy of Sciences in 1973, the Kybernetika Best Paper Award in 1976, the National Prize of the Czech Republic in 1989 for his contributions to the theory and practice of automatic control, the Automatica Prize Paper Award in 1990 for the paper Fundamental Theorem of State Feedback for Singular Systems, Hlávka Foundation Prize in 1992, Outstanding Service Award from IFAC in 1996, Medal of the Ministry of Education of the Czech Republic in 2000, Felber Gold Medal of the Czech Technical University in Prague, and in 2006 he was appointed Chevalier dans l’ordre des Palmes Académiques, a national order of France for distinguished academics. He is an Honorary Professor at the Northeastern University, Shenyang, China (1996) and received Doctor honoris causa degrees from Université Paul Sabatier, Toulouse (2003), and Université Henri Poincaré, Nancy (2005). He is the 2021 laureate of the National Prize Česká hlava (Czech Mind), the most prestigious Czech award for science and research that scientists in the Czech Republic can achieve. | |
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