Engineering school of Harvard University in Cambridge, Massachusetts
Harvard John A. Paulson School of Engineering and Applied Sciences
Former name
Lawrence Scientific School Harvard Engineering School Graduate School of Engineering Department of Engineering Sciences and Applied Physics Division of Engineering Sciences Division of Applied Science Division of Engineering and Applied Physics Division of Applied Sciences Division of Engineering and Applied Sciences School of Engineering and Applied Sciences (2007–2015)
It offers degrees in engineering and applied sciences to graduate students admitted directly to SEAS, and to undergraduates admitted first toHarvard College. Previously the Lawrence Scientific School and then the Division of Engineering and Applied Sciences, the school assumed its current structure in 2007. The school was renamed afterJohn Paulson in June 2015 following his US$400 million gift.
Harvard's efforts to provide formal education in advanced science and engineering began in 1847, when Massachusetts industrialistAbbott Lawrence gave Harvard $50,000 (equivalent to $1,400,000 in 2024) to form what became known as theLawrence Scientific School. In making his gift, Lawrence asked:[6]
But where can we send those who intend to devote themselves to the practical applications of science? Our country abounds in men of action. Hard hands are ready to work upon our hard materials; and where shall sagacious heads be taught to direct those hands?
James Emmanuel Jr. was the first dean of the school, which hosted astronomers, architects, naturalists, engineers, mathematicians, and even philosophers.
By the late 19th century, the School faced increasing competition from theMassachusetts Institute of Technology (MIT) and was constrained by the uncertain views about its role and status by the long-serving Harvard PresidentCharles William Eliot. Eliot was involved in at least five unsuccessful attempts to absorb MIT into Harvard.[7][better source needed] As a result of such uncertainty, the Lawrence Scientific School became less of an independent entity, losing its influence and students to other parts of the university.
In 1891, the industrialistGordon McKay designated the Lawrence Scientific School his primary beneficiary; there are now 40 McKay professorships.
In 1914, a merger ofMassachusetts Institute of Technology and Harvard's Applied Science departments was formally announced[8]and was to begin "when the Institute will occupy its splendid new buildings in Cambridge."[9] However, in 1917, the merger with MIT was canceled due to a decision by the State Judicial Court,[further explanation needed] so Harvard PresidentAbbott Lawrence Lowell moved to establish theHarvard Engineering School independently instead.[10]
In 1934, the School began offering graduate-level and professional programs in engineering. DuringWorld War II, Harvard participated in theV-12 Navy College Training Program to provide training for commissioned officers. In 1942, the undergraduate Department of Engineering Sciences changed to the Department of Engineering Sciences and Applied Physics to reflect an increased emphasis on applied physics. Harvard PresidentJames Bryant Conant created what was known as "Conant's Arsenal", a research hub for defense-related engineering projects includingradar jamming, night vision, aerial photography,sonar, explosives, napalm, andatomic bomb research.[11] One notable project from this era was theHarvard Mark I computer; one of the first programs to run on the Mark I was initiated on March 29, 1944, byJohn von Neumann, who worked on theManhattan Project at the time, and needed to determine whether implosion was a viable choice to detonate the atomic bomb that would be used a year later.[12]
By 1945, Harvard income from government contracts was $33.5 million, the third highest among U.S. universities.[13]
Between 1946 and 1949, theGraduate School of Engineering merged its faculty with theDepartment of Engineering Sciences and Applied Physics into theDivision of Engineering Sciences within theHarvard Faculty of Arts and Sciences. It was renamed several times:Division of Applied Science (1951),Division of Engineering and Applied Physics (1955),Division of Applied Sciences (1975),Division of Engineering and Applied Sciences (1996).[14] It was often informally called The Division.
In 2007, theHarvard Corporation and Overseers voted for the Division of Engineering and Applied Sciences to become theSchool of Engineering and Applied Sciences (SEAS).[15][16]
Undergraduates can pursue programs incomputer science (AB and as a secondary field), engineering sciences (AB and SB), biomedical engineering (AB), electrical engineering (SB), environmental science and engineering (AB), mechanical engineering (SB), andapplied mathematics (AB and as a secondary field). SB options for environmental science and engineering as well as biomedical engineering are also available through the engineering sciences program; ABET accreditation is offered for all of the traditional engineering disciplines. Prospective undergraduates must apply toHarvard College (Harvard's undergraduate college encompassing all concentrations): once enrolled, Harvard College students may declare a SEAS concentration in their sophomore year.[20]
As of January 2020, the School had 148 faculty members.[21] The faculty has particularly close ties (including joint appointments) with theFAS departments of Physics, Earth and Planetary Science, as well as Chemistry and Chemical Biology. The campus provides 600,000 square feet (56,000 m2) of interconnected labs, classrooms, clusters, and offices in six buildings.[22] SEAS is expected to expand into the new Science and Engineering Complex (SEC) under construction in Allston, across the Charles River from Harvard's main location in Cambridge.[23] The SEC will be adjacent to the Enterprise Research Campus in synergy withHarvard Business School andHarvard Innovation Labs to encourage technology- and life science-focused startups as well as collaborations with mature companies.[4]
Areas of significant research focus include applied mathematics, applied physics, bioengineering, geophysics, computer science, electrical engineering, artificial intelligence, mechanical engineering, and computational neuroscience.[24]
1919 –George Washington Pierce (PhD, 1900), Rumford Professor of Physics and director of Harvard's Cruft High-Tension Electrical Laboratory invented an oscillator that enabled a given radio station to stay "fixed" at a proper frequency and allowed multiple telephone calls to occur over a single line.
1938 – Acyclotron was constructed at the Graduate School of Engineering's Gordon McKay Engineering Laboratory to support research in biology and medicine as well as physics. It was projected to be the world's largest such facility. In 1942, it was sent to Los Alamos for work on theManhattan Project to develop an atomic bomb.
1944 – Howard Aiken '37 (PhD) developed theMark I series of computers, the first large-scale automatic digital computer in the U.S. Around the same time, a new generation of technically trained students began to share their knowledge well beyond Harvard's campus. Alumnus and donor Allen E. Puckett SB '39, SM '41 created an endowed professorship at SEAS, went on to define modern aerodynamics, served as CEO ofHughes Aircraft Company, and won the National Medal of Honor in Technology.
Stopping light –Lene Hau and her colleagues created a new form of matter, aBose-Einstein Condensate, to slow light to 17 meters per second and later to bring a light beam to a complete stop, then restart it again.[26]
Unbreakable hyper-encryption –Michael O. Rabin embedded messages in rapidly moving streams of random digital bits in ways that cannot be decoded, even with unlimited computing power.
Black silicon –Eric Mazur's group created a new material that efficiently traps light and has potential use in solar cells, global warming sensors and ultra-thin television screens.
The mathematics of nature –L. Mahadevan and colleagues discovered how the Venus flytrap snaps up its prey in a mere tenth of a second by actively shifting the curved shape of its mouth-like leaves.
Atmospheric modeling – Loretta J. Mickley, Dan Jacob and colleagues found that the frequency of cold fronts bringing cool, clear air out of Canada during the summer months declined by about 20 percent. These cold fronts are responsible for breaking up the hot, stagnant air that builds up regularly in summer, generating high levels of ground level ozone pollution.
High speed nanowire circuits –Donhee Ham andCharles Lieber made robust circuits from minuscule nanowires that align themselves on a chip of glass during low-temperature fabrication, creating rudimentary electronic devices that offer performance without high-temperature production or high-priced silicon.
Double emulsions – A new microfluidics-based device made byDavid A. Weitz and colleagues at Harvard University andUnilever makes precisely controlled doubleemulsions in a single step. Double emulsions, or droplets inside droplets, could be useful for encapsulating products such as drugs, cosmetics, or food additives.
Applied physicistLene Hau caused a light pulse disappeared from one cold cloud then was retrieved from another cloud nearby. In the process, light was converted into matter then back into light.
A research team led by Mike Aziz and Earth and Planetary Sciences' Kurt House invented an engineered weathering process that mightmitigate climate change.
Working with a team of Dutch researchers and software developers, SEAS computer scientists used a novel peer-to-peer video sharing application to explore a model for e-commerce that uses bandwidth as a global currency.
Rob Wood's team launched a robotic fly that could be used in everything from surveillance to chemical sensing.
MIT'sTechnology Review named the creation of light-focusing optical antennas (that could lead to DVDs that hold hundreds of movies) as one of their Top 10 emerging technologies for 2007.
Kit Parker's lab found that an elastic film coated with a single layer of cardiac muscle cells can semi-autonomously engage in lifelike gripping, pumping, walking and swimming.
Nan Sun andDonhee Ham built what may be the smallest complete nuclear magnetic resonance (NMR) system to date in a 0.1-kilogram (0.22 lb) package.[27]
Engineers and applied physicists demonstrated the first room-temperature electrically pumpedsemiconductor laser source ofterahertz (THz) radiation, also known as T-rays.
A team composed of Harvard students and alumni was among the winners of the World Bank'sLighting Africa 2008 Development Marketplace competition, held in Accra, Ghana. The innovation,microbial fuel cell-based lighting systems suitable for Sub-Saharan Africa, netted the group a $200,000 prize.[28]
In collaboration with SiEnergy Systems, materials scientists at SEAS have demonstrated the first macro-scale thin-film solid-oxide fuel cell (SOFC).[29]
An interdisciplinary research effort investigated digitizedtext corpuses containing about 4% of all books ever printed in English, between 1800 and 2000. It was co-founded and co-directed by Erez Aiden and Jean-Baptiste Michel, whose prototype was instrumental in creatingGoogle Ngram Viewer.
Howard Wilson Emmons (PhD '38) - mechanical engineer considered "the father of modern fire science" for his contribution to the understanding of flame propagation and fire dynamics, helped design the firstsupersonic wind tunnel, identified a signature of the transition toturbulence inboundary layer flows (now known as "Emmons spots"), and was the first to observecompressor stall in a gas turbine compressor
Simon Newcomb (SB 1858) - Rear Admiral in the United States Navy and a leader in mathematical astronomy
^"Abbott Lawrence".John A. Paulson School of Engineering and Applied Sciences. Harvard. 18 March 2013. Archived fromthe original on 2 February 2017. RetrievedJanuary 27, 2017.
^Alexander, Philip N."MIT-Harvard Rivalry Timeline".MIT Music and Theater Arts News. Massachusetts Institute of Technology. Archived fromthe original on 2014-07-14. Retrieved2014-07-07.
^"Tech Alumni Holds Reunion. Record attendance, novel features. Cooperative plan with Harvard announced by Pres. Maclaurin. Gov. Walsh Brings Best Wishes of the State". Boston Daily Globe. 1914-01-11. p. 117. Maclaurin quoted: "in future Harvard agrees to carry out all its work in engineering and mining in the buildings of Technology under the executive control of the president of Technology, and, what is of the first importance, to commit all instruction and the laying down of all courses to the faculty of Technology, after that faculty has been enlarged and strengthened by the addition to its existing members of men of eminence from Harvard's Graduate School of Applied Science."
^"Harvard-Tech Merger. Duplication of Work to be Avoided in Future. Instructors Who Will Hereafter be Members of Both Faculties". Boston Daily Globe. 1914-01-25. p. 47.
^Ireland, Corydon (10 November 2011)."Harvard Goes to War".Harvard Gazette. Retrieved30 March 2017.
^Cohen, Bernard (2000). Howard Aiken, Portrait of a computer pioneer. Cambridge, Massachusetts: The MIT Press.ISBN978-0-2625317-9-5.
^Downs, Donald Alexander; Murtazashvili, Ilia (2012).Arms and the University: Military Presence and the Civic Education of Non-Military Students. New York: Cambridge University Press.ISBN9780521192323.
