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National Academy of Engineering

January 19, 2023

This article is about the United States institution. For other uses, see National Academy of Engineering (disambiguation).

The National Academy of Engineering (NAE) is an American nonprofit, non-governmental organization. The National Academy of Engineering is part of the National Academies of Sciences, Engineering, and Medicine, along with the National Academy of Sciences (NAS), the National Academy of Medicine, and the National Research Council (now the program units of NASEM).

National Academy of Engineering
Formation1964; 59 years ago (1964)
TypeNGO
Location
Websitenae.edu

The NAE operates engineering programs aimed at meeting national needs, encourages education and research, and recognizes the superior achievements of engineers. New members are annually elected by current members, based on their distinguished and continuing achievements in original research. The NAE is autonomous in its administration and in the selection of its members, sharing with the rest of the National Academies the role of advising the federal government.

History

The National Academy of Sciences was created by an Act of Incorporation dated March 3, 1863, which was signed by then President of the United States Abraham Lincoln[1] with the purpose to "...investigate, examine, experiment, and report upon any subject of science or art..."[1] No reference to engineering was in the original act, the first recognition of any engineering role was with the setup of the Academy's standing committees in 1899.[1] At that time, there were six standing committees: (mathematics and astronomy; physics and engineering; chemistry; geology and paleontology; biology; and anthropology.[1] In 1911, this committee structure was again reorganized into eight committees: biology was separated into botany; zoology and animal morphology; and physiology and pathology; anthropology was renamed anthropology and psychology with the remaining committees including physics and engineering, unchanged.[1]

In 1913, George Ellery Hale presented a paper on the occasion of the Academy's 50th anniversary, outlining an expansive future agenda for the Academy.[1] Hale proposed a vision of an Academy that interacted with the "whole range of science", one that actively supported newly recognized disciplines, industrial sciences and the humanities.[1][2] The proposed creation of sections of medicine and engineering was protested by one member because those professions were "mainly followed for pecuniary gain".[1] Hale's suggestions were not accepted.[1] Nonetheless, in 1915, the Section of Physics and Engineering was recommended to be changed to physics only, and a year later the Academy began planning a separate section of engineering.[1]

That same year of 1913, the Academy was requested to investigate the great slide in Culebra Cut late in 1913 which ultimately delayed the opening of the Panama canal by ten months. The study group, commissioned by the United States Army Corps of Engineers and although composed of both engineers and geologists resulted in a final report prepared by two geologists Charles Whitman Cross and Harry Fielding Reid.[1] The report, submitted to President Wilson in November 1917, concluded that claims of repeated interruptions in canal traffic for years to come were unjustified.[1]

During this time, the United States confronted the prospect of war with Germany and the question of preparedness was raised. Engineering societies responded to this crisis by offering technical services to the Federal government such as the Naval Consulting Board of 1915 and the Council of National Defense of 1916. On June 19 of that year, then US President Woodrow Wilson requested the National Academy of Sciences to organize a "National Research Council" albeit with the assistance of the Engineering Foundation.[1] (pg. 569) The purpose of the Council (at first called the National Research Foundation) was in part to foster and encourage "the increased use of scientific research in the development of American industries... the employment of scientific methods in strengthening the national defense... and such other applications of science as will promote the national security and welfare."[1]

During the period of national preparations, an increasing number of engineers were being elected to the physics and engineering section of the Academy, this did not, however, resolve the long-standing issue of where to place applied sciences such as engineering in the Academy.[1] In 1863, the founding members who were prominent military and naval engineers comprised almost a fifth of the membership.[1] during the latter part of the 19th century, this engineering membership steadily declined and by 1912, Henry Larcom Abbot, who had been elected in 1872, was the sole remaining representative of the Corps of Engineers.[1] With the Engineering Division in the wartime National Research Council being used as a precedent, the Academy established its first engineering section with nine members in 1919 with civil war veteran Henry Larcom Abbot as its first chairman.[1] OF those nine members, only two were new members, the others had transferred from existing sections; "... of the 164 members of the Academy that year, only seven chose to identify themselves as engineers."[3]

During this period of 1915-1916 activity by engineering societies, the National Academy of Sciences complained that there was a lack of scientists and the predominance of engineers on the Federal government's wartime technical committee, the Naval Consulting Board.[3] One of the mathematicians on the Board, Robert Simpson Woodward, was actually trained and early on practiced as a civil engineer.[3] The Academy's response was to move forward with the idea of achieving Academy control over the provision of technical services to the Government by means of formal recognition of the role played by the National Research Council (NRC) established the next year in 1916. Later in 1918, Wilson formalized the NRC's existence under Executive Order 2859.[4][5][6] Wilson's order declared the function of the NRC to be in general:

"(T)o stimulate research in the mathematical. physical, and biological sciences. and in the application of these sciences to engineering, agriculture. medicine. and other useful arts. with the object of increasing knowledge, of strengthening the national defense, and of contributing in other ways to the public welfare."[1]

In 1960, Augustus Braun Kinzel, an engineer with the Union Carbide Corporation and a member of the Academy, stated that the "..engineering profession was considering the establishment of an academy of engineering..."[1] confirmed by the Engineers Joint Council of the national engineering societies to afford themselves of opportunities and services similar to those the Academy provided in science. The question being, whether to affiliate with the National Academy or set up a separate Academy.[1]

During the past century of the Academy's existence, engineers had been part of the founding members and a sixth of its membership, the founding of the National Research Council in 1916 with the assistance of the Engineering Foundation, the contributions of the NRC Division of Engineering in the post-World War I period, the presidency of engineer Frank B. Jewett during World War II. In short, "...the ascendancy of science in the public mind since World War I had been partly at the expense of the prestige of the engineering profession."[1] (See also[7].)

The Academy worked with the Engineers Joint Council led by President Eric Arthur Walker as the prime mover,[7] to make plans to establish a new National Academy of Engineering that's independent, with a congressional charter of its own.[1] Walker noted that this moment offered a "...singular opportunity for the engineering profession to participate actively and directly in communicating objective advice to the government..." on engineering matters related to national policy.[7] A secondary function was to recognize distinguished individuals for their engineering contributions.[7]

Ultimately, the initial organizers decided to create the Academy of Engineering as part of the National Academy of Sciences (NAS).[1] On December 5, 1964, marking, "a major landmark in the history of the relationships between science and engineering in our country," the Academy approved the Articles of Incorporation of the new academy and its twenty-five charter members met to organize the National Academy of Engineering (NAE) as an autonomous parallel body in the National Academy of Sciences, with Augustus B. Kinzel as its first President.[1] OF the 675 members of the National Academy of Sciences at that time, only about 30 called themselves engineers.[7] The National Academy of Engineering then were a "purposeful compromise" given the fears of the NAS of expanded membership by engineers.[7]

The stated objects and purposes of the newly created National Academy of Engineering were to:[1]

  • To advise the Congress and the executive branch... whenever called upon... on matters of national import pertinent to engineering...
  • To cooperate with the National Academy of Sciences on matters involving both science and engineering...
  • To serve the nation... in connection with significant problems in engineering and technology...

In 1966, the National Academy of Engineering established the Committee on Public Engineering Policy (COPEP).[1] In 1982, the NAE and NAS committees were merged to become the Committee on Science, Engineering, and Public Policy. In 1967, the NAE formed an aeronautics and space engineering board to advise NASA and other Federal agencies chaired by Horton Guyford Stever.[8]

In 1971, the National Academy of Engineering advised the Port Authority of New York and New Jersey not to construct additional runways at JFK airport as part of a $350,000 study commissioned by the Port Authority. The Port Authority accepted the recommendations of the NAE and NAS.[9]

In 1975, the NAE added eighty-six new engineer members including noted civil engineer and businessman Stephen Davison Bechtel Jr.[10] In 1986, Tha NAE issued a report encouraging foreign investment, calling for stronger Federal action.[11] That same year, NAE member Robert W. Rummel (1915-2009), space expert and aerospace engineer, served on The Presidential Commission on the Space Shuttle Challenger Accident.[12]

In 1989, the National Academy of Engineering in conjunction with the National Academy of Science advised the Department of Energy on a site location for the then proposed Superconducting Super Collider (SSC) from a number of States proposals.[13]

In 1995, the NAE along with the NAS and the National Academy of Medicine reported that the American system of doctoral education in science and engineering, while "...long a world model, should be reshaped to produce more 'versatile scientists,' rather than narrowly specialized researchers".[14] Again in 2000, NAE returned to this education theme with its detailed studies of engineering education as part of its "Engineer of 2020 Studies" project.[15][16] The reports concluded that engineering education must be reformed or American engineers will be poorly prepared for engineering practice. Soon after, the American Society of Civil Engineers adopted a policy advocating for the reconstruction of the academic foundation of the professional practice of civil engineering.

Membership

Formally, members of the NAE must be U.S. citizens.[17] The term "international member" is applied to non-citizens who are elected to the NAE.[17] "The NAE has more than 2,000 peer-elected members and international members, senior professionals in business, academia, and government who are among the world's most accomplished engineers", according to the NAE site's About page.[18] Election to the NAE is considered to be among the highest recognitions in engineering-related fields, and it often comes as a recognition of a lifetime's worth of accomplishments. Nomination for membership can only be done by a current member of the NAE for outstanding engineers with identifiable contributions or accomplishments in one or both of the following categories:

  • Engineering research, practice, or education, including, where appropriate, significant contributions to the engineering literature.
  • Pioneering of new and developing fields of technology, making major advancements in traditional fields of engineering, or developing/implementing innovative approaches to engineering education.

Since its founding, the Academy has elected 2,634 members. The Massachusetts Institute of Technology is associated with the most members, 199 or some 8% of the all-time total, while Stanford University is affiliated with 168 members and the University of California, Berkeley with 130. The top eleven institutions account for over 30% of all members ever elected.[19][20]

Top 11 Institutions Members (1969–2022) Living Members
MIT 199 111
Stanford 163 109
Berkeley 130 79
CMU 65 38
Caltech 58 34
UIUC 48 21
Michigan 45 31
Cornell 39 27
Georgia Tech 39 35
Harvard 39 31
Princeton 39 29

Program areas

Greatest Engineering Achievements of the 20th Century

In February 2000, a National Press Club luncheon during National Engineers Week 2000 sponsored by the NAE, astronaut/engineer Neil Armstrong announced the 20 top engineering achievements having the greatest impact on the quality of life in the 20th century.[21] Twenty-nine professional engineering societies provided 105 nominations which then selected and ranked the top 20 achievements.[21] The nominations were pared to less than fifty and then combined into 29 larger categories.

"Thus, bridges, tunnels, and roads were merged into the interstate highway system, and tractors, combines, robot cotton pickers, and chisel plows were simply lumped into agricultural mechanization."[22]

Some of the achievements, though, such as the telephone and the automobile which were not invented in the 20th century were included because of the impact they had were not really apparent until the 20th century.[21] The top achievement, electrification is essential for almost part of modern society and has "...literally lighted the world and impacted countless areas of daily life, including food production and processing, air conditioning and heating, refrigeration, entertainment, transportation, communication, health care, and computers."[21] Later in 2003, the National Academy of Engineering published A Century of Innovation: Twenty Engineering Achievements that Transformed our Lives.[23][24]

The ranked list of the top 20 achievements in the 20th century was published as follows:[21][24]

  1. Electrification
  2. Automobile
  3. Airplane
  4. Water Supply and Distribution
  5. Electronics
  6. Radio and Television
  7. Agricultural Mechanization
  8. Computers
  9. Telephone
  10. Air Conditioning and Refrigeration
  11. Highways
  12. Spacecraft
  13. Internet
  14. Imaging
  15. Household Appliances
  16. Health Technologies
  17. Petroleum and Petrochemical Technologies
  18. Laser and Fiber Optics
  19. Nuclear Technologies
  20. High-performance Materials

Reception

The NAE's achievements list was criticized for ranking space technology (listed as "Spacecraft") twelfth instead of number one despite NAE recognizing in its report that the Soviet Union's Sputnik "shocked the world and started a space race that launched the greatest engineering team effort in American history."[22] (NAE, 2000) Time magazine ran a similar poll of 20th-century accomplishments, and its website users ranked the first Moon landing in 1969 in second place versus NAE's 12th.[22] The NAE listing was also criticized for not recognizing the role physics played in laying the foundations for the engineering accomplishments such Michael Faraday and Joseph Henry for electrification.[22] NAE's list ranked electronics based upon two inventions, the transistor and integrated circuits, even it neglected to mention their physicist inventors, John Bardeen, Walter H. Brattain, William B. Shockley, Jack Kilby and Robert Noyce.[22] Another commentator noted that the list ignored the St. Lawrence seaway and power project, built between 1954 and 1959 and by extension the Panama Canal. The St. Lawrence seaway was "...one of the largest transborder projects ever undertaken by two countries and one of the greatest engineering achievements of the 20th century."[25]

It was also noted that these 20th-century accomplishments did not come without impacts on the environment or societies.[26] Electrification as an example, resulting in fossil-fuel-burning power plants, airplanes and automobiles which emit greenhouse gases while electronics manufacturing leaves heavy-metal byproducts.[26]

Grand Challenges for Engineering

The Grand Challenges confront wicked social issues that are inherently global in nature and require technological innovations and applications of systems thinking. Further, NAE argues that the solutions call upon engineers to persuasively influence "...public policy, transfer technical innovation to the market place, and to inform and be informed by social science and the humanities."[27] The NAE's Grand Challenges overlap with the United Nations' Millennium Development Goals and its 2015 successor, the Sustainable Development Goals (SDGs) which all depend upon "a strong engineering component" for success.[28]

Development of the Grand Challenges (2008)

The Academy introduced its "Grand Challenges for Engineering" project in 2007 with the commissioning of a blue-ribbon committee composed of leading technological thinkers from around the globe.[29] The committee, led by former Secretary of Defense William Perry was charged with the task of identifying "..key engineering challenges for improving life in the 21st century."[29] NAE's intent was to develop a set of challenges of such importance that they warranted serious investment and if successful, would "lead to a marked improvement in our quality of life."[30] The project received "...thousands of inputs from around the world to determine its list of Grand Challenges for Engineering, and its report was reviewed by more than 50 subject-matter experts, making it among the most reviewed of Academy studies."[31] In February 2008, the committee announced 14 Engineering Grand Challenges fitting into four broad categories: energy, sustainability, and global climate change; medicine, health informatics and health care delivery systems; reducing our vulnerability to natural and human threats; and advancing the human spirit and capabilities.[30] NAE noted that a number of engineering schools had developed coursework based upon Grand Challenge themes.[30]
The 14 Grand Challenges for Engineering developed by the NAE committee were to:

Make solar energy economical
Provide energy from fusion
Develop carbon sequestration
Manage the nitrogen cycle
Provide access to clean water
Restore and Improve urban infrastructure[32]
Advance health informatics
Engineer better medicines
Reverse-engineer the brain
Prevent nuclear terror
Secure cyberspace
Enhance virtual reality
Advance personalized learning
Engineer the tools of scientific discovery.

NAE noted in its report that the Grand Challenges for Engineering were not "...ranked in importance or likelihood of solution, nor was any strategy proposed for solving them. Rather, they were offered as a way to inspire the profession, young people, and the public at large to seek the solutions."[33] NAE also stated that the Grand Challenges were "...not targeted to any one country or corporate sector... (and)... are relevant to everyone in every country. In fact, some of them bear on the very survival of society. If solving these challenges can become an international movement, all will benefit."[33]

Reception

One writer favorably observed that the Academy's list of 20th-century engineering achievements was dominated by devices and when asked to project advances for the 21st, the result was again, device dominated.[34] With respect to the Grand Challenges, the NAE reframed its discussion from being device-centric to addressing complex or wicked social issues that cannot be solved by technology alone,[34] i.e. more devices. With the Grand Challenges though, NAE "...charted a course for... (engineering)... to move from devices to global social challenges, and has identified a number of exciting ones."[34]

One critical reaction to the NAE's challenges noted that engineers today are the "...unacknowledged legislators of the world... (and by)... designing and constructing new structures, processes, and products, they are influencing how we live as much as any laws enacted by politicians.[35] The author argued that NAE's Grand Challenges should have included the "...challenge of thinking about what we are doing as we turn the world into an (engineering) artifact and the appropriate limitations of this engineering power."[35] This is already happening in the Netherlands with its Delta Works as an example of a society being an engineered artifact but also with a community of philosophers of engineering and technology.[35]

Another commentator observed that challenges with respect to sustainability concentrated on specific elements of the problem without addressing "... "what level of energy use would be sustainable on a global scale."[26] While India and China are 1000-1500 Watt per person societies, the United States requires 12,000 W per person.[26] An estimate of a sustainable level of power consumption made by a Swiss group is 2,000 W per person.[26] Similar questions were raised on the NAE's challenge for access to clean water. The average daily per capita water consumption in American cities varies from 130 to 2000 liters (35 to 530 gallons).[36]

Grand Challenge Scholars Program (GCSP)

In 2010, NAE developed a plan for preparing engineering students at the undergraduate academic degree level to practice in career fields that emerged as a result of the effort to answer the Grand Challenges.[33] The program had five components, namely:[27]

  • Research experience based upon a project or independent research related to a NAE Grand Challenges.
  • Interdisciplinary curriculum materials inclusive of "..public policy, business, law, ethics, human behavior, risk as well as medicine and the sciences."[27]
  • Entrepreneurship inclusive of skills to translate "...invention to innovation... (and)... develop market ventures that scale to global solutions in the public interest."[27]
  • Global dimension and perspective necessary to "..address challenges that are inherently global as well as to lead innovation in a global economy."[27]
  • Service learning that develops and engages the engineer's social consciousness and its willingness to bring to bear the profession's technical expertise on societal problems through programs such as Engineers Without Borders, or Engineering World Health.[27]

STEM education, Technological Literacy and the Grand Challenges

While the National Academy of Engineering's GC SCholars (GCSP) program was primarily focused on undergraduate level curriculums, STEM focuses on K–12 education. The question for STEM educators was how to prepare K-12 students to participate in solving the wicked problems associated with the Grand Challenges.[37] One response was to align STEM program theories of learning and International Technology and Engineering Educators Association (ITEEA, formerly ITEA) Technological Literacy Standards with the National Academy of Engineering's Grand Challenges in order to guide current and pending curriculum development.[37] NAE's objective was also to inform instructional practices, particularly dealing with the connections among science, technology, engineering, and mathematics education. The Technological Literacy Standards were funded by the National Science Foundation and NASA and NAE's Technology Education Standards Committee led the Academy's efforts on the standards.[38]

Global Grand Challenges Summit

As a result of NAE's Grand Challenge efforts, three national engineering academies–The National Academy of Engineering of the United States, The Royal Academy of Engineering of the United Kingdom, and the Chinese Academy of Engineering–organized a joint Global Grand Challenges Summit, held in London on March 12–13, 2013.[39] In September 2015 a second Global Grand Challenges Summit was held in Beijing, with more than 800 attendees invited by the three academies. The third Global Grand Challenges Summit was hosted by the NAE in the United States in 2017.[33]

Frontiers of Engineering

The Frontiers of Engineering program assembles a group of emerging engineering leaders - usually aged 30–45 - to discuss cutting-edge research in various engineering fields and industry sectors. The goal of the meetings is to bring participants together to collaborate, network, and share ideas. There are three Frontiers of Engineering meetings every year: the U.S. Frontiers of Engineering Symposium, the German-American Frontiers of Engineering Symposium, and the Japan-America Frontiers of Engineering Symposium. The Indo-U.S. Frontiers of Engineering Symposium is held every other year.[40]

Diversity in the Engineering Workplace

The goal of the diversity office is to participate in studies addressing the issue of increasing and broadening a domestic talent pool. Through this effort the NAE convenes workshops, coordinators with other organizations, and identifies program needs and opportunities for improvement.

As part of this effort the NAE has launched both the EngineerGirl![41] and Engineer Your Life[42] webpages.

Engineering, Economics, and Society

This program area studies connections between engineering, technology, and the economic performance of the United States. Efforts aim to advance the understanding of engineering's contribution to the sectors of the domestic economy and to learn where engineering may enhance economic performance.[43]

The project also aims to investigate the best ways to determine levels of technological literacy in the United States among three distinct populations in the United States: K-12 students, K-12 teachers, and out-of-school adults. A report (and associated website), Technically Speaking,[44] explains what "technological literacy" is, why it's important, and what is being done in the U.S. to improve it.

Engineering and the Environment

This program, recognizing that the engineering profession has often been associated with causing environmental harm, looks to recognize and publicize that the profession is now at the forefront of mitigating negative environmental impacts. The program will provide policy guidance to government, the private sector, and the public on ways to create a more environmentally sustainable future.[45]

Center for the Advancement of Scholarship on Engineering Education

The Center for the Advancement of Scholarship on Engineering Education.[46] was established to advance engineering education in the United States, aiming for curriculum changes that address the needs of new generations of engineering students and the unique problems they will face with the challenges of the 21st century.

The Center worked closely with the Committee on Engineering Education, which works to improve the quality of engineering education by providing advice to policymakers, administrators, employers, and other stakeholders.[47]

The Center is no longer active within the National Academy of Engineering.

Center for Engineering, Ethics, and Society

The Center for Engineering, Ethics, and Society seeks to engage engineers and the engineering profession in identifying and resolving ethical issues associated with engineering research and practice. The Center works is closely linked with the Online Ethics Center.[48]

Outreach efforts

To publicize the work of both the profession and the NAE, the institution puts considerable efforts into outreach activities.

A weekly radio spot produced by the NAE is broadcast on WTOP radio in the Washington, DC area and the file and text of the spot can be found on the NAE site.[49] The NAE also distributes a biweekly newsletter focusing on engineering issues and advancements.

In addition, NAE has held a series of workshops titled News and Terrorism: Communicating in a Crisis, in which experts from the National Academies and elsewhere provide reporters, state and local public information officers, emergency managers, and representatives from the public sector with important information about weapons of mass destruction and their impact. This project is conducted in collaboration with the Department of Homeland Security and the Radio and Television News Directors Foundation.

In addition to these efforts, the NAE fosters good relationships with members of the media to ensure coverage of the work of the institution and to serve as a resource for the media to use when they have technical questions or would like to speak to an NAE member on a particular matter. The NAE is also active in "social media," both to reach new and younger audiences and to reach traditional audiences in new ways.

Prizes

The Academy awards several prizes, with each recipient receiving $500,000. The prizes include the Bernard M. Gordon Prize, the Fritz J. and Dolores H. Russ Prize, and the Charles Stark Draper Prize. They are sometimes referred to collectively as the American version of a Nobel Prize for engineering.[50][51][52][53][54]

Gordon Prize

Main article: Gordon Prize

The Bernard M. Gordon Prize was started in 2001 by the NAE. It is named after Bernard Marshall Gordon, the founder of Analogic Corporation. Its purpose is to recognize leaders in academia for the development of new educational approaches to engineering.[55] Each year, the Gordon Prize awards $500,000 to the grantee, of which the recipient may personally use $250,000, and his or her institution receives $250,000 for the ongoing support of academic development.[55]

Russ Prize

Main article: Russ Prize

The Fritz J. and Dolores H. Russ Prize is an American national and international award established by the NAE in October 1999 in Athens, Ohio. The prize has been given biennially in odd years since 2001. Named after Fritz Russ, the founder of Systems Research Laboratories, and his wife Dolores Russ, it recognizes a bioengineering achievement that "has had a significant impact on society and has contributed to the advancement of the human condition through widespread use." The award was instigated at the request of Ohio University to honor Fritz Russ, one of its alumni.[56]

Charles Stark Draper Prize

Main article: Charles Stark Draper Prize

The NAE annually awards the Charles Stark Draper Prize, which is given for the advancement of engineering and the education of the public about engineering. The recipient receives $500,000. The prize is named for Charles S. Draper, the "father of inertial navigation", an MIT professor and founder of the Draper Laboratory.

See also

References

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  48. ^ "OEC - Home". www.onlineethics.org. Retrieved September 27, 2018.
  49. ^ . Archived from the original on October 6, 2010.
  50. ^ William A. Wulf and George M.C. Fisher "A Makeover for Engineering Education" Issues in Science & Technology Spring 2002 p. 35-39.
  51. ^ "GPS, dialysis inventors win top awards". Chicago Tribune. February 19, 2003. Retrieved January 11, 2011.
  52. ^ Laura A. Bischoff (January 31, 2001). "First Russ Prize to be Awarded". Dayton Daily News. Retrieved January 11, 2011.
  53. ^ Rex Graham (January 11, 2007). "Y.C. Fung Wins Russ Prize". Medical News Today. Retrieved January 11, 2011.
  54. ^ "Leroy Hood wins 2011 Russ Prize". Ohio University. January 5, 2011. Retrieved January 11, 2011.
  55. ^ a b . Archived from the original on December 7, 2006. Retrieved December 12, 2006.
  56. ^ "Fritz J. and Dolores H. Russ Prize". NAE. Retrieved December 28, 2010.

External links

  • Official NAE website
  • The Engineer of 2020: Visions of Engineering in the New Century (2004)
  • NAE Grand Challenges for Engineering report (2008 Report), (2017 Update of 2008 document)
  • National Academy of Engineering Grand Challenge Scholars Program Plan (2010)
  • [7] and [8], Committee on Science, Engineering, and Public Policy information
  • Greatest Engineering Achievements
  • ROBERT W. RUMMEL (1915–2009) obituary at NAE site

January 19, 2023
national, academy, engineering, this, article, about, united, states, institution, other, uses, disambiguation, american, nonprofit, governmental, organization, part, national, academies, sciences, engineering, medicine, along, with, national, academy, science. This article is about the United States institution For other uses see National Academy of Engineering disambiguation The National Academy of Engineering NAE is an American nonprofit non governmental organization The National Academy of Engineering is part of the National Academies of Sciences Engineering and Medicine along with the National Academy of Sciences NAS the National Academy of Medicine and the National Research Council now the program units of NASEM National Academy of EngineeringFormation1964 59 years ago 1964 TypeNGOLocation2101 Constitution Ave NW Washington D C U S 20418Websitenae wbr eduThe NAE operates engineering programs aimed at meeting national needs encourages education and research and recognizes the superior achievements of engineers New members are annually elected by current members based on their distinguished and continuing achievements in original research The NAE is autonomous in its administration and in the selection of its members sharing with the rest of the National Academies the role of advising the federal government Contents 1 History 2 Membership 3 Program areas 3 1 Greatest Engineering Achievements of the 20th Century 3 1 1 Reception 3 2 Grand Challenges for Engineering 3 2 1 Development of the Grand Challenges 2008 3 2 2 Reception 3 2 3 Grand Challenge Scholars Program GCSP 3 2 4 STEM education Technological Literacy and the Grand Challenges 3 2 5 Global Grand Challenges Summit 3 3 Frontiers of Engineering 3 4 Diversity in the Engineering Workplace 3 5 Engineering Economics and Society 3 6 Engineering and the Environment 3 7 Center for the Advancement of Scholarship on Engineering Education 3 8 Center for Engineering Ethics and Society 4 Outreach efforts 5 Prizes 5 1 Gordon Prize 5 2 Russ Prize 5 3 Charles Stark Draper Prize 6 See also 7 References 8 External linksHistory EditThe National Academy of Sciences was created by an Act of Incorporation dated March 3 1863 which was signed by then President of the United States Abraham Lincoln 1 with the purpose to investigate examine experiment and report upon any subject of science or art 1 No reference to engineering was in the original act the first recognition of any engineering role was with the setup of the Academy s standing committees in 1899 1 At that time there were six standing committees mathematics and astronomy physics and engineering chemistry geology and paleontology biology and anthropology 1 In 1911 this committee structure was again reorganized into eight committees biology was separated into botany zoology and animal morphology and physiology and pathology anthropology was renamed anthropology and psychology with the remaining committees including physics and engineering unchanged 1 In 1913 George Ellery Hale presented a paper on the occasion of the Academy s 50th anniversary outlining an expansive future agenda for the Academy 1 Hale proposed a vision of an Academy that interacted with the whole range of science one that actively supported newly recognized disciplines industrial sciences and the humanities 1 2 The proposed creation of sections of medicine and engineering was protested by one member because those professions were mainly followed for pecuniary gain 1 Hale s suggestions were not accepted 1 Nonetheless in 1915 the Section of Physics and Engineering was recommended to be changed to physics only and a year later the Academy began planning a separate section of engineering 1 That same year of 1913 the Academy was requested to investigate the great slide in Culebra Cut late in 1913 which ultimately delayed the opening of the Panama canal by ten months The study group commissioned by the United States Army Corps of Engineers and although composed of both engineers and geologists resulted in a final report prepared by two geologists Charles Whitman Cross and Harry Fielding Reid 1 The report submitted to President Wilson in November 1917 concluded that claims of repeated interruptions in canal traffic for years to come were unjustified 1 During this time the United States confronted the prospect of war with Germany and the question of preparedness was raised Engineering societies responded to this crisis by offering technical services to the Federal government such as the Naval Consulting Board of 1915 and the Council of National Defense of 1916 On June 19 of that year then US President Woodrow Wilson requested the National Academy of Sciences to organize a National Research Council albeit with the assistance of the Engineering Foundation 1 pg 569 The purpose of the Council at first called the National Research Foundation was in part to foster and encourage the increased use of scientific research in the development of American industries the employment of scientific methods in strengthening the national defense and such other applications of science as will promote the national security and welfare 1 During the period of national preparations an increasing number of engineers were being elected to the physics and engineering section of the Academy this did not however resolve the long standing issue of where to place applied sciences such as engineering in the Academy 1 In 1863 the founding members who were prominent military and naval engineers comprised almost a fifth of the membership 1 during the latter part of the 19th century this engineering membership steadily declined and by 1912 Henry Larcom Abbot who had been elected in 1872 was the sole remaining representative of the Corps of Engineers 1 With the Engineering Division in the wartime National Research Council being used as a precedent the Academy established its first engineering section with nine members in 1919 with civil war veteran Henry Larcom Abbot as its first chairman 1 OF those nine members only two were new members the others had transferred from existing sections of the 164 members of the Academy that year only seven chose to identify themselves as engineers 3 During this period of 1915 1916 activity by engineering societies the National Academy of Sciences complained that there was a lack of scientists and the predominance of engineers on the Federal government s wartime technical committee the Naval Consulting Board 3 One of the mathematicians on the Board Robert Simpson Woodward was actually trained and early on practiced as a civil engineer 3 The Academy s response was to move forward with the idea of achieving Academy control over the provision of technical services to the Government by means of formal recognition of the role played by the National Research Council NRC established the next year in 1916 Later in 1918 Wilson formalized the NRC s existence under Executive Order 2859 4 5 6 Wilson s order declared the function of the NRC to be in general T o stimulate research in the mathematical physical and biological sciences and in the application of these sciences to engineering agriculture medicine and other useful arts with the object of increasing knowledge of strengthening the national defense and of contributing in other ways to the public welfare 1 In 1960 Augustus Braun Kinzel an engineer with the Union Carbide Corporation and a member of the Academy stated that the engineering profession was considering the establishment of an academy of engineering 1 confirmed by the Engineers Joint Council of the national engineering societies to afford themselves of opportunities and services similar to those the Academy provided in science The question being whether to affiliate with the National Academy or set up a separate Academy 1 During the past century of the Academy s existence engineers had been part of the founding members and a sixth of its membership the founding of the National Research Council in 1916 with the assistance of the Engineering Foundation the contributions of the NRC Division of Engineering in the post World War I period the presidency of engineer Frank B Jewett during World War II In short the ascendancy of science in the public mind since World War I had been partly at the expense of the prestige of the engineering profession 1 See also 7 The Academy worked with the Engineers Joint Council led by President Eric Arthur Walker as the prime mover 7 to make plans to establish a new National Academy of Engineering that s independent with a congressional charter of its own 1 Walker noted that this moment offered a singular opportunity for the engineering profession to participate actively and directly in communicating objective advice to the government on engineering matters related to national policy 7 A secondary function was to recognize distinguished individuals for their engineering contributions 7 Ultimately the initial organizers decided to create the Academy of Engineering as part of the National Academy of Sciences NAS 1 On December 5 1964 marking a major landmark in the history of the relationships between science and engineering in our country the Academy approved the Articles of Incorporation of the new academy and its twenty five charter members met to organize the National Academy of Engineering NAE as an autonomous parallel body in the National Academy of Sciences with Augustus B Kinzel as its first President 1 OF the 675 members of the National Academy of Sciences at that time only about 30 called themselves engineers 7 The National Academy of Engineering then were a purposeful compromise given the fears of the NAS of expanded membership by engineers 7 The stated objects and purposes of the newly created National Academy of Engineering were to 1 To advise the Congress and the executive branch whenever called upon on matters of national import pertinent to engineering To cooperate with the National Academy of Sciences on matters involving both science and engineering To serve the nation in connection with significant problems in engineering and technology In 1966 the National Academy of Engineering established the Committee on Public Engineering Policy COPEP 1 In 1982 the NAE and NAS committees were merged to become the Committee on Science Engineering and Public Policy In 1967 the NAE formed an aeronautics and space engineering board to advise NASA and other Federal agencies chaired by Horton Guyford Stever 8 In 1971 the National Academy of Engineering advised the Port Authority of New York and New Jersey not to construct additional runways at JFK airport as part of a 350 000 study commissioned by the Port Authority The Port Authority accepted the recommendations of the NAE and NAS 9 In 1975 the NAE added eighty six new engineer members including noted civil engineer and businessman Stephen Davison Bechtel Jr 10 In 1986 Tha NAE issued a report encouraging foreign investment calling for stronger Federal action 11 That same year NAE member Robert W Rummel 1915 2009 space expert and aerospace engineer served on The Presidential Commission on the Space Shuttle Challenger Accident 12 In 1989 the National Academy of Engineering in conjunction with the National Academy of Science advised the Department of Energy on a site location for the then proposed Superconducting Super Collider SSC from a number of States proposals 13 In 1995 the NAE along with the NAS and the National Academy of Medicine reported that the American system of doctoral education in science and engineering while long a world model should be reshaped to produce more versatile scientists rather than narrowly specialized researchers 14 Again in 2000 NAE returned to this education theme with its detailed studies of engineering education as part of its Engineer of 2020 Studies project 15 16 The reports concluded that engineering education must be reformed or American engineers will be poorly prepared for engineering practice Soon after the American Society of Civil Engineers adopted a policy advocating for the reconstruction of the academic foundation of the professional practice of civil engineering Membership EditFormally members of the NAE must be U S citizens 17 The term international member is applied to non citizens who are elected to the NAE 17 The NAE has more than 2 000 peer elected members and international members senior professionals in business academia and government who are among the world s most accomplished engineers according to the NAE site s About page 18 Election to the NAE is considered to be among the highest recognitions in engineering related fields and it often comes as a recognition of a lifetime s worth of accomplishments Nomination for membership can only be done by a current member of the NAE for outstanding engineers with identifiable contributions or accomplishments in one or both of the following categories Engineering research practice or education including where appropriate significant contributions to the engineering literature Pioneering of new and developing fields of technology making major advancements in traditional fields of engineering or developing implementing innovative approaches to engineering education Since its founding the Academy has elected 2 634 members The Massachusetts Institute of Technology is associated with the most members 199 or some 8 of the all time total while Stanford University is affiliated with 168 members and the University of California Berkeley with 130 The top eleven institutions account for over 30 of all members ever elected 19 20 Top 11 Institutions Members 1969 2022 Living MembersMIT 199 111Stanford 163 109Berkeley 130 79CMU 65 38Caltech 58 34UIUC 48 21Michigan 45 31Cornell 39 27Georgia Tech 39 35Harvard 39 31Princeton 39 29Program areas EditGreatest Engineering Achievements of the 20th Century Edit In February 2000 a National Press Club luncheon during National Engineers Week 2000 sponsored by the NAE astronaut engineer Neil Armstrong announced the 20 top engineering achievements having the greatest impact on the quality of life in the 20th century 21 Twenty nine professional engineering societies provided 105 nominations which then selected and ranked the top 20 achievements 21 The nominations were pared to less than fifty and then combined into 29 larger categories Thus bridges tunnels and roads were merged into the interstate highway system and tractors combines robot cotton pickers and chisel plows were simply lumped into agricultural mechanization 22 Some of the achievements though such as the telephone and the automobile which were not invented in the 20th century were included because of the impact they had were not really apparent until the 20th century 21 The top achievement electrification is essential for almost part of modern society and has literally lighted the world and impacted countless areas of daily life including food production and processing air conditioning and heating refrigeration entertainment transportation communication health care and computers 21 Later in 2003 the National Academy of Engineering published A Century of Innovation Twenty Engineering Achievements that Transformed our Lives 23 24 The ranked list of the top 20 achievements in the 20th century was published as follows 21 24 Electrification Automobile Airplane Water Supply and Distribution Electronics Radio and Television Agricultural Mechanization Computers Telephone Air Conditioning and Refrigeration Highways Spacecraft Internet Imaging Household Appliances Health Technologies Petroleum and Petrochemical Technologies Laser and Fiber Optics Nuclear Technologies High performance Materials Reception Edit The NAE s achievements list was criticized for ranking space technology listed as Spacecraft twelfth instead of number one despite NAE recognizing in its report that the Soviet Union s Sputnik shocked the world and started a space race that launched the greatest engineering team effort in American history 22 NAE 2000 Time magazine ran a similar poll of 20th century accomplishments and its website users ranked the first Moon landing in 1969 in second place versus NAE s 12th 22 The NAE listing was also criticized for not recognizing the role physics played in laying the foundations for the engineering accomplishments such Michael Faraday and Joseph Henry for electrification 22 NAE s list ranked electronics based upon two inventions the transistor and integrated circuits even it neglected to mention their physicist inventors John Bardeen Walter H Brattain William B Shockley Jack Kilby and Robert Noyce 22 Another commentator noted that the list ignored the St Lawrence seaway and power project built between 1954 and 1959 and by extension the Panama Canal The St Lawrence seaway was one of the largest transborder projects ever undertaken by two countries and one of the greatest engineering achievements of the 20th century 25 It was also noted that these 20th century accomplishments did not come without impacts on the environment or societies 26 Electrification as an example resulting in fossil fuel burning power plants airplanes and automobiles which emit greenhouse gases while electronics manufacturing leaves heavy metal byproducts 26 Grand Challenges for Engineering Edit The Grand Challenges confront wicked social issues that are inherently global in nature and require technological innovations and applications of systems thinking Further NAE argues that the solutions call upon engineers to persuasively influence public policy transfer technical innovation to the market place and to inform and be informed by social science and the humanities 27 The NAE s Grand Challenges overlap with the United Nations Millennium Development Goals and its 2015 successor the Sustainable Development Goals SDGs which all depend upon a strong engineering component for success 28 Development of the Grand Challenges 2008 Edit The Academy introduced its Grand Challenges for Engineering project in 2007 with the commissioning of a blue ribbon committee composed of leading technological thinkers from around the globe 29 The committee led by former Secretary of Defense William Perry was charged with the task of identifying key engineering challenges for improving life in the 21st century 29 NAE s intent was to develop a set of challenges of such importance that they warranted serious investment and if successful would lead to a marked improvement in our quality of life 30 The project received thousands of inputs from around the world to determine its list of Grand Challenges for Engineering and its report was reviewed by more than 50 subject matter experts making it among the most reviewed of Academy studies 31 In February 2008 the committee announced 14 Engineering Grand Challenges fitting into four broad categories energy sustainability and global climate change medicine health informatics and health care delivery systems reducing our vulnerability to natural and human threats and advancing the human spirit and capabilities 30 NAE noted that a number of engineering schools had developed coursework based upon Grand Challenge themes 30 The 14 Grand Challenges for Engineering developed by the NAE committee were to Make solar energy economical Provide energy from fusion Develop carbon sequestration Manage the nitrogen cycle Provide access to clean water Restore and Improve urban infrastructure 32 Advance health informatics Engineer better medicines Reverse engineer the brain Prevent nuclear terror Secure cyberspace Enhance virtual reality Advance personalized learning Engineer the tools of scientific discovery NAE noted in its report that the Grand Challenges for Engineering were not ranked in importance or likelihood of solution nor was any strategy proposed for solving them Rather they were offered as a way to inspire the profession young people and the public at large to seek the solutions 33 NAE also stated that the Grand Challenges were not targeted to any one country or corporate sector and are relevant to everyone in every country In fact some of them bear on the very survival of society If solving these challenges can become an international movement all will benefit 33 Reception Edit One writer favorably observed that the Academy s list of 20th century engineering achievements was dominated by devices and when asked to project advances for the 21st the result was again device dominated 34 With respect to the Grand Challenges the NAE reframed its discussion from being device centric to addressing complex or wicked social issues that cannot be solved by technology alone 34 i e more devices With the Grand Challenges though NAE charted a course for engineering to move from devices to global social challenges and has identified a number of exciting ones 34 One critical reaction to the NAE s challenges noted that engineers today are the unacknowledged legislators of the world and by designing and constructing new structures processes and products they are influencing how we live as much as any laws enacted by politicians 35 The author argued that NAE s Grand Challenges should have included the challenge of thinking about what we are doing as we turn the world into an engineering artifact and the appropriate limitations of this engineering power 35 This is already happening in the Netherlands with its Delta Works as an example of a society being an engineered artifact but also with a community of philosophers of engineering and technology 35 Another commentator observed that challenges with respect to sustainability concentrated on specific elements of the problem without addressing what level of energy use would be sustainable on a global scale 26 While India and China are 1000 1500 Watt per person societies the United States requires 12 000 W per person 26 An estimate of a sustainable level of power consumption made by a Swiss group is 2 000 W per person 26 Similar questions were raised on the NAE s challenge for access to clean water The average daily per capita water consumption in American cities varies from 130 to 2000 liters 35 to 530 gallons 36 Grand Challenge Scholars Program GCSP Edit In 2010 NAE developed a plan for preparing engineering students at the undergraduate academic degree level to practice in career fields that emerged as a result of the effort to answer the Grand Challenges 33 The program had five components namely 27 Research experience based upon a project or independent research related to a NAE Grand Challenges Interdisciplinary curriculum materials inclusive of public policy business law ethics human behavior risk as well as medicine and the sciences 27 Entrepreneurship inclusive of skills to translate invention to innovation and develop market ventures that scale to global solutions in the public interest 27 Global dimension and perspective necessary to address challenges that are inherently global as well as to lead innovation in a global economy 27 Service learning that develops and engages the engineer s social consciousness and its willingness to bring to bear the profession s technical expertise on societal problems through programs such as Engineers Without Borders or Engineering World Health 27 STEM education Technological Literacy and the Grand Challenges Edit While the National Academy of Engineering s GC SCholars GCSP program was primarily focused on undergraduate level curriculums STEM focuses on K 12 education The question for STEM educators was how to prepare K 12 students to participate in solving the wicked problems associated with the Grand Challenges 37 One response was to align STEM program theories of learning and International Technology and Engineering Educators Association ITEEA formerly ITEA Technological Literacy Standards with the National Academy of Engineering s Grand Challenges in order to guide current and pending curriculum development 37 NAE s objective was also to inform instructional practices particularly dealing with the connections among science technology engineering and mathematics education The Technological Literacy Standards were funded by the National Science Foundation and NASA and NAE s Technology Education Standards Committee led the Academy s efforts on the standards 38 Global Grand Challenges Summit Edit As a result of NAE s Grand Challenge efforts three national engineering academies The National Academy of Engineering of the United States The Royal Academy of Engineering of the United Kingdom and the Chinese Academy of Engineering organized a joint Global Grand Challenges Summit held in London on March 12 13 2013 39 In September 2015 a second Global Grand Challenges Summit was held in Beijing with more than 800 attendees invited by the three academies The third Global Grand Challenges Summit was hosted by the NAE in the United States in 2017 33 Frontiers of Engineering Edit The Frontiers of Engineering program assembles a group of emerging engineering leaders usually aged 30 45 to discuss cutting edge research in various engineering fields and industry sectors The goal of the meetings is to bring participants together to collaborate network and share ideas There are three Frontiers of Engineering meetings every year the U S Frontiers of Engineering Symposium the German American Frontiers of Engineering Symposium and the Japan America Frontiers of Engineering Symposium The Indo U S Frontiers of Engineering Symposium is held every other year 40 Diversity in the Engineering Workplace Edit The goal of the diversity office is to participate in studies addressing the issue of increasing and broadening a domestic talent pool Through this effort the NAE convenes workshops coordinators with other organizations and identifies program needs and opportunities for improvement As part of this effort the NAE has launched both the EngineerGirl 41 and Engineer Your Life 42 webpages Engineering Economics and Society Edit This program area studies connections between engineering technology and the economic performance of the United States Efforts aim to advance the understanding of engineering s contribution to the sectors of the domestic economy and to learn where engineering may enhance economic performance 43 The project also aims to investigate the best ways to determine levels of technological literacy in the United States among three distinct populations in the United States K 12 students K 12 teachers and out of school adults A report and associated website Technically Speaking 44 explains what technological literacy is why it s important and what is being done in the U S to improve it Engineering and the Environment Edit This program recognizing that the engineering profession has often been associated with causing environmental harm looks to recognize and publicize that the profession is now at the forefront of mitigating negative environmental impacts The program will provide policy guidance to government the private sector and the public on ways to create a more environmentally sustainable future 45 Center for the Advancement of Scholarship on Engineering Education Edit The Center for the Advancement of Scholarship on Engineering Education 46 was established to advance engineering education in the United States aiming for curriculum changes that address the needs of new generations of engineering students and the unique problems they will face with the challenges of the 21st century The Center worked closely with the Committee on Engineering Education which works to improve the quality of engineering education by providing advice to policymakers administrators employers and other stakeholders 47 The Center is no longer active within the National Academy of Engineering Center for Engineering Ethics and Society Edit The Center for Engineering Ethics and Society seeks to engage engineers and the engineering profession in identifying and resolving ethical issues associated with engineering research and practice The Center works is closely linked with the Online Ethics Center 48 Outreach efforts EditTo publicize the work of both the profession and the NAE the institution puts considerable efforts into outreach activities A weekly radio spot produced by the NAE is broadcast on WTOP radio in the Washington DC area and the file and text of the spot can be found on the NAE site 49 The NAE also distributes a biweekly newsletter focusing on engineering issues and advancements In addition NAE has held a series of workshops titled News and Terrorism Communicating in a Crisis in which experts from the National Academies and elsewhere provide reporters state and local public information officers emergency managers and representatives from the public sector with important information about weapons of mass destruction and their impact This project is conducted in collaboration with the Department of Homeland Security and the Radio and Television News Directors Foundation In addition to these efforts the NAE fosters good relationships with members of the media to ensure coverage of the work of the institution and to serve as a resource for the media to use when they have technical questions or would like to speak to an NAE member on a particular matter The NAE is also active in social media both to reach new and younger audiences and to reach traditional audiences in new ways Prizes EditThe Academy awards several prizes with each recipient receiving 500 000 The prizes include the Bernard M Gordon Prize the Fritz J and Dolores H Russ Prize and the Charles Stark Draper Prize They are sometimes referred to collectively as the American version of a Nobel Prize for engineering 50 51 52 53 54 Gordon Prize Edit Main article Gordon Prize The Bernard M Gordon Prize was started in 2001 by the NAE It is named after Bernard Marshall Gordon the founder of Analogic Corporation Its purpose is to recognize leaders in academia for the development of new educational approaches to engineering 55 Each year the Gordon Prize awards 500 000 to the grantee of which the recipient may personally use 250 000 and his or her institution receives 250 000 for the ongoing support of academic development 55 Russ Prize Edit Main article Russ Prize The Fritz J and Dolores H Russ Prize is an American national and international award established by the NAE in October 1999 in Athens Ohio The prize has been given biennially in odd years since 2001 Named after Fritz Russ the founder of Systems Research Laboratories and his wife Dolores Russ it recognizes a bioengineering achievement that has had a significant impact on society and has contributed to the advancement of the human condition through widespread use The award was instigated at the request of Ohio University to honor Fritz Russ one of its alumni 56 Charles Stark Draper Prize Edit Main article Charles Stark Draper Prize The NAE annually awards the Charles Stark Draper Prize which is given for the advancement of engineering and the education of the public about engineering The recipient receives 500 000 The prize is named for Charles S Draper the father of inertial navigation an MIT professor and founder of the Draper Laboratory See also EditNational Academies of Sciences Engineering and Medicine List of founding members of the National Academy of Engineering List of members of the National Academy of Engineering List of engineering awardsReferences Edit a b c d e f g h i j k l m n o p q r s t u v w x y z aa Rexmond Cochrane 1978 The National Academy of Sciences The First Hundred Years 1863 1963 NAP pp 209 211 ISBN 0 309 02518 4 Cochrane 1978 citing George Ellery Hale National Academies and the Progress of Research III The Future of the National Academy of Sciences Science 40 907 919 December 15 1914 41 12 25 January I 1915 Hale s complete study was published as National Academies and the Progress of Research Lancaster Pennsylvania New Era Printing Co n d a b c Pursell Carroll Engineering Organization and the Scientist in World War I The Search for National Service and Recognition Prometheus 24 3 2006 257 268 Executive Orders August 15 2016 Retrieved September 27 2018 A Chronicle of Public Laws Calling for Action by the National Academy of Sciences National Academy of Engineering Institute of Medicine and National Research Council Washington DC National Academies 1985 p xiii NAP 11820 Retrieved March 22 2014 William Henry Welch NAS a b c d e f ENGINEER COUNCIL TO JOIN SCIENTISTS New York Times 1963 Retrieved November 2 2017 Unit Formed to Aid NASA New York Times 1967 Retrieved November 2 2017 PORT AUTHORITY DROPS BAY PLAN New York Times 1971 Retrieved November 2 2017 ENGINEERS GROUP ADDS 86 MEMBERS New York Times 1975 Retrieved November 2 2017 Academy of Engineers Says U S Should Welcome Foreign Investors New York Times 1990 Retrieved November 2 2017 THE SHUTTLE FINDINGS HARSH CRITICISM AND THE REACTIONS New York Times 1986 Retrieved November 2 2017 U S PLANS TO PICK SITE FOR ATOM SMASHER IN 1989 New York Times 1989 Retrieved November 2 2017 Scientists and Engineers Need Broader Training Report Says New York Times 1995 Retrieved November 2 2017 National Academy of Engineering NAE 2004 The engineer of2020 Visions of engineering in the new century National Academies Washington DC National Academy of Engineering NAE 2005 Educating the engineer of 2020 Adapting engineering education to the new century National Academies Washington DC 192 a b Becoming a Member NAE website About NAE National Academy of Engineering Member Directory National Academy of Engineering Awards Carnegie Mellon University a b c d e Business amp Manufacturing Editors National Academy of Engineering Reveals Top Engineering Impacts of the 20th Century Electrification Cited as most Important Business Wire Feb 22 2000 pp 1 ABI INFORM Collection ProQuest Central a b c d e Goodwin Irwin Engineers proclaim top achievements of 20th century but neglect attributing feats to roots in physics Physics Today 53 5 2000 48 49 Constable George Somerville Bob 2003 A Century of Innovation Twenty Engineering Achievements that Transformed our Lives National Academies Press doi 10 17226 10726 ISBN 978 0 309 08908 1 a b Greatest Engineering Achievements of the Twentieth Century National Academy of Engineering Retrieved September 26 2010 Macfarlane Daniel Caught between Two Fires International Journal vol 67 no 2 2012 pp 465 482 ProQuest Central Research Library a b c d e Petroski Henry Great Achievements amp Grand Challenges Civil Engineering Magazine Archive 80 2 2010 48 57 a b c d e f Workshop on developing a national network of Grand Challenge Scholars Programs 2010 National Academy of Engineering Washington DC Accessed at 1 on November 3 2017 Olson Steve Grand Challenges for Engineering Imperatives Prospects and Priorities Summary of a Forum National Academies Press 2016 Accessed at 2 on November 3 2017 a b National Academy of Engineering NAE Annual Report for 2007 Washington DC Accessed at 3 a b c National Academy of Engineering Annual Report for 2008 Washington DC Letter from President Accessed at 4 Olson Steve Grand Challenges for Engineering Imperatives Prospects and Priorities Summary of a Forum National Academies Press 2016 O Leary Maureen Grand Challenges for Engineering The National Academies in Focus vol 8 no 1 2008 pp 20 21 ABI INFORM Collection ProQuest Central a b c d Front Matter National Academy of Engineering 2016 Grand Challenges for Engineering Imperatives Prospects and Priorities Summary of a Forum Washington DC The National Academies Press doi 10 17226 23440 a b c KATSOULEAS TOM LAST WORD New Challenges Same Education ASEE Prism 18 8 2009 60 60 Accessed at 5 a b c Mitcham Carl The true grand challenge for engineering Self knowledge Issues in Science and Technology 31 1 2014 19 22 Fang Xing et al Environmental impacts on surface water and groundwater for expanding urban water supply capacity using stone quarries World Environmental and Water Resources Congress 2009 Great Rivers 2009 Citing McGhee and Steel 1991 a b EbD and the NAE Grand Challenges for Engineering Technology and Engineering Teacher vol 71 no 6 2012 pp 3 Education Database ProQuest Central Pearson Greg ITEA Technological Literacy Standards National Academy of Engineering National Academy of Engineering Retrieved November 3 2017 Regli William and Jeff Heisserman Report from the Royal Academy of Engineering s Global Grand Challenges Summit Computer Aided Design 11 45 2013 1485 1487 6 Frontiers of Engineering Homepage EngineerGirl Retrieved September 27 2018 Homepage EngineerGirl Archived from the original on February 1 2013 Retrieved September 27 2018 Engineering Economics and Society Archived from the original on March 24 2009 Technically Speaking Archived from the original on March 12 2009 Engineering and the Environment Archived from the original on June 10 2011 Retrieved April 1 2009 CASEE NAE Website Retrieved September 27 2018 Committee on Engineering Education Archived from the original on September 20 2008 OEC Home www onlineethics org Retrieved September 27 2018 Engineering Innovation Radio Series Archived from the original on October 6 2010 William A Wulf and George M C Fisher A Makeover for Engineering Education Issues in Science amp Technology Spring 2002 p 35 39 GPS dialysis inventors win top awards Chicago Tribune February 19 2003 Retrieved January 11 2011 Laura A Bischoff January 31 2001 First Russ Prize to be Awarded Dayton Daily News Retrieved January 11 2011 Rex Graham January 11 2007 Y C Fung Wins Russ Prize Medical News Today Retrieved January 11 2011 Leroy Hood wins 2011 Russ Prize Ohio University January 5 2011 Retrieved January 11 2011 a b Gordon Prize information Archived from the original on December 7 2006 Retrieved December 12 2006 Fritz J and Dolores H Russ Prize NAE Retrieved December 28 2010 External links EditOfficial NAE website The Engineer of 2020 Visions of Engineering in the New Century 2004 NAE Grand Challenges for Engineering report 2008 Report 2017 Update of 2008 document National Academy of Engineering Grand Challenge Scholars Program Plan 2010 7 and 8 Committee on Science Engineering and Public Policy information Greatest Engineering Achievements ROBERT W RUMMEL 1915 2009 obituary at NAE site Retrieved from https en wikipedia org w index php title National Academy of Engineering amp oldid 1123583249, wikipedia, wiki, book, books, library,

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