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1960-1969

Stanford Linear Accelerator Center (SLAC)
Society: IEEEMain Category: ElectricalSub Category: Nuclear and Plasma SciencesEra: 1960-1969DateCreated: 1962Stanford Linear AcceleratorPortola ValleyState: CAZip: 94028Country: USAWebsite: http://www.ieeeghn.org/wiki/index.php/Milestones:Stanford_Linear_Accelerator_Center,_1962Creator: Stanford University

The basic research tool at SLAC is an intense beam of electrons that have been accelerated by an electric field equivalent to 30 billion volts, making this the most powerful electron beam in the world.

The two-mile linear accelerator produces this field using high-power microwaves traveling through an evacuated waveguide. Electrons injected into one end of this pipe are continuously accelerated by this traveling field to very high energies.

YearAdded:
1984
Image Credit: Courtesy Wikipedia/Jvimal (CC BY 3.0)Image Caption: Stanford Linear Accelerator Center (SLAC)Era_date_from: 1962
Stanford Linear Accelerator Center
Society: ASMEMain Category: MechanicalSub Category: Research and DevelopmentEra: 1960-1969DateCreated: 1962Stanford Linear AcceleratorMenlo ParkState: CAZip: 94028Country: USAWebsite: http://www.asme.org/about-asme/history/landmarks/topics-m-z/research-and-development/-92-stanford-linear-accelerator-center-%281962%29, https://www.asme.org/getmedia/f8e54d6f-6e0d-4f7d-ad3a-ff357142f07b/92-Stanford-Linear-Accelerator-Center-1962.aspxCreator: Stanford University

The Stanford Linear Accelerator Center was renamed in 2009 to the SLAC National Accelerator Laboratory.

Notable for: unique electromechanical devices and systems in the longest accelerator in the world

YearAdded:
1984
Image Credit: Courtesy Flickr/Jeff Keyser (CC BY-SA 2.0)Image Caption: Stanford Linear Accelerator CenterEra_date_from: 1962
Society: ASMEMain Category: MechanicalSub Category: ManufacturingEra: 1960-1969DateCreated: 1966Robbins & Lawrence ArmoryWindsorState: VTZip: 05089Country: USAWebsite: http://www.asme.org/about-asme/history/landmarks/topics-m-z/manufacturing---2/-119-american-precision-museumCreator: Battison, Edwin Albert
In fulfilling a contract for 25,000 U.S. Army rifles (Model 1841) and a like quantity for the British government, Robbins and Lawrence were the first to achieve interchangeability of parts on a fully practical level, contributing greatly to all subsequent mass production of machine products. This was made possible by the systematic improvement and refinement of existing standard and special-purpose machine tools, enabling them to perform with the close-limit precision essential for "repeatability" and thus interchangeability (see the American Precision Museum).
YearAdded:
1987
Image Credit: Courtesy Flickr/Liz West (CC BY 2.0)Image Caption: American Precision MuseumEra_date_from: 1966
NS Savannah
Society: ASMEMain Category: MechanicalSub Category: Water TransportationEra: 1960-1969DateCreated: 19624601 Newgate AveBaltimoreState: MDZip: 21224Country: USAWebsite: https://www.asme.org/about-asme/who-we-are/engineering-history/landmarks/87-ns-savannahCreator: New York Shipbuilding Corporation, Babcock & Wilcox Company

The N.S. Savannah was the first nuclear-powered cargo-passenger ship, built by the New York Shipbuilding Corporation at Camden, New Jersey. The 74 maximum-power thermal megawatt pressurized-water reactor was supplied by the Babcock & Wilcox Company. Nearly 600 feet long with 22,000-tons displacement, the ship at top speed surged along at 24 knots, with more than 22,300 shaft horsepower to a single propeller. A joint venture by the U.S. Maritime Administration and the Atomic Energy Commission to the design of George G. Sharp Inc.

YearAdded:
1983
Image Credit: Public Domain (U.S. Government)Image Caption: NS SavannahEra_date_from: 1962
Newell Shredder
Society: ASMEMain Category: MechanicalSub Category: Solid WasteEra: 1960-1969DateCreated: 1969Newell IndustriesSan AntonioState: TXCountry: USAWebsite: http://www.asme.org/about-asme/history/landmarks/topics-m-z/solid-waste/-179-newell-shredder-%281969%29, https://www.asme.org/getmedia/2c664309-172d-48d9-a822-5327e310a107/179-Newell-Shredder-1969.aspxCreator: Newell, Alton

This machine, designed by Alton S. Newell, efficiently reduced automobile bodies into scrap metal for recycling. A body was fed into the shredder at a controlled rate, and rotating hammers, driven by a 500-hp motor, shredded it into small pieces that were easily shipped. The process took about 10 minutes a car and used less energy than other shredding and crushing machines. 

YearAdded:
1994
Image Caption: Newell ShredderEra_date_from: 1969
Neil Bartlett and the Reactive Noble Gases
Society: ACSMain Category: ChemicalSub Category: Frontiers of KnowledgeEra: 1960-1969DateCreated: 1962Dept of ChemistryVancouverState: BCZip: V6T 1Z1Country: CanadaWebsite: https://www.acs.org/content/acs/en/education/whatischemistry/landmarks/bartlettnoblegases.htmlCreator: Bartlett, Neil

In 1962 Neil Bartlett demonstrated the first reaction of a noble gas. The noble gas family of elements - helium, neon, argon, krypton, xenon, and radon - had previously been regarded as inert. By combining xenon with a platinum fluoride, Bartlett created the first noble gas compound. This reaction began the field of noble gas chemistry, which became fundamental to the scientific understanding of the chemical bond. Noble gas compounds have helped create anti-tumor agents and have been used in lasers.

YearAdded:
2006
Image Credit: Image courtesy University of British Columbia Library.Image Caption: Neil Bartlett and the Reactive Noble GasesEra_date_from: 1962
NAIC/Arecibo Radiotelescope
Society: IEEEMain Category: ElectricalSub Category: SignalsEra: 1960-1969DateCreated: 1963Arecibo ObservatoryAreciboState: PRZip: 00612Country: USAWebsite: http://www.asme.org/about-asme/history/landmarks/topics-m-z/research-and-development/-216-arecibo-radiotelescope-%281963%29Creator: Gordon, William , Doundoulakis, Helias

The Arecibo Observatory has the largest radio telescope ever constructed. Maintaining the greatest electromagnetic wave gathering capacity of any telescope, it has been an essential tool in modern astronomy, ionosphere and planetary studies. Several feats of mechanical engineering went into the construction of this observatory, most notable of which is a drive system which allows all active parts of the antenna to be kept focused with millimeter precision regardless of environmental factors—such as thermal expansion.

YearAdded:
2001
Image Caption: NAIC/Arecibo RadiotelescopeEra_date_from: 1963
Society: IEEEMain Category: ElectricalSub Category: CommunicationsEra: 1960-1969DateCreated: 1969Computer History MuseumMountain ViewState: CAZip: 94043Country: USAWebsite: http://www.ieeeghn.org/wiki/index.php/Milestones:Birthplace_of_the_Internet,_1969Creator: Kleinrock, Leonard
"At 10:30 p.m., 29 October 1969, the first ARPANET message was sent from this UCLA site to the Stanford Research Institute. Based on packet switching and dynamic resource allocation, the sharing of information digitally from this first node of ARPANET launched the Internet revolution." (The plaque can be seen at the UCLA Henry Samueli School of Engineering and Applied Sciences, 405 Hilgard Ave., Los Angeles, California, U.S.A.) The deployment of the ARPANET set in motion a train of developments that led to the Internet as we know it today.
YearAdded:
2009
Image Credit: Courtesy Flickr/FastLizard4 (CC BY-SA 2.0)Image Caption: The original Interface Message Processor, a primitive router, and considered widely to be the beginning (or "birth") of the internetEra_date_from: 1969
Deciphering the Genetic Code
Society: ACSMain Category: ChemicalSub Category: Frontiers of KnowledgeEra: 1960-1969DateCreated: 1961NIH Mark O. Hatfield Clinical Research CtrBethesdaState: MDZip: 20892Country: USAWebsite: https://www.acs.org/content/acs/en/education/whatischemistry/landmarks/geneticcode.htmlCreator: Nirenberg, Marshall

In 1961, in the National Institutes of Health Headquarters (Bethesda, MD), Marshall Nirenberg and Heinrich Matthaei discovered the key to breaking the genetic code when they conducted an experiment using a synthetic RNA chain of multiple units of uracil to instruct a chain of amino acids to add phenylalanine. The uracil (poly-U) served as a messenger directing protein synthesis. This experiment demonstrated that messenger RNA transcribes genetic information from DNA, regulating the assembly of amino acids into complex proteins.

YearAdded:
1997
Image Credit: Courtesy Wikipedia/Infocan (CC BY-SA 3.0)Image Caption: Deciphering the Genetic CodeEra_date_from: 1961
Society: ASMEMain Category: MechanicalSub Category: Air and Space TransportationEra: 1960-1969DateCreated: 1964Marshall Space Flight CenterHuntsvilleState: ALZip: 35808Country: USAWebsite: http://www.asme.org/about-asme/history/landmarks/topics-a-l/air-and-space-transportation/-170-advanced-engine-test-facility-at-marshall-%2819Creator: von Braun, Wernher
The Advanced Engine Test Facility was built in 1964, three years after President John F. Kennedy committed the United States to world leadership in aeronautical science. Conceived and designed by Wernher von Braun, the first director of the Marshall Space Flight Center, this facility was used to perform static tests on the booster of the Saturn V rocket, which launched Apollo 11 to the moon on July 16, 1969. The stand has four concrete legs, each four feet thick and rising 144 feet to a steel superstructure supporting a 200-ton crane.
YearAdded:
1993
Image Credit: Courtesy ASMEImage Caption: Saturn V Rocket being lifted onto the A-2 Test Stand at NASA's John C. Stennis Space CenterEra_date_from: 1964
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