Previous Draper Prize winners over the past 25 years include the inventors of the mobile phone and supporting infrastructure, the World Wide Web, GPS, and the turbojet engine.
Cambridge, MA (PRWEB) January 06, 2014
The rechargeable battery pioneers who laid the groundwork for today’s lithium ion battery will be presented with engineering’s highest honor during a Feb. 18 ceremony in Washington.
The National Academy of Engineering (NAE) will honor John Goodenough, Rachid Yazami, Akira Yoshino, and Yoshio Nishi with the Charles Stark Draper Prize for Engineering, which annually recognizes engineers whose accomplishments have significantly benefited society, and is considered the Nobel Prize of engineering. The prize, which is in its 25th year, includes a $500,000 award.
Thirty five years ago, Goodenough demonstrated the feasibility of a rechargeable lithium ion battery at four volts with the use of lithium cobalt oxide as the positive node. In 1980, Yazami showed that graphite could be used as the battery’s negative node. Yoshino assembled the first prototype lithium ion battery in 1985, and six years later, Sony released the first commercial lithium ion battery, with research, development, and production led by Nishi.
The market for lithium ion batteries, an important feature in devices including laptops, smartphones, hearing aids, and electric cars, is projected to reach nearly $60 billion by 2020, according to an IHS iSuppli study.
The Charles Stark Draper Prize was established and endowed by Draper Laboratory in 1988 in tribute to its founder, Dr. Charles Stark Draper, who pioneered inertial navigation. It honors those who have contributed to the advancement of engineering and to improve public understanding of the importance of engineering and technology. Previous winners over the past 25 years include the inventors of the mobile phone and supporting infrastructure, the World Wide Web, GPS, and the turbojet engine.
Draper Laboratory is a not-for-profit, engineering research and development organization dedicated to solving critical national problems in national security, space systems, biomedical systems, and energy. Core capabilities include guidance, navigation and control; miniature low power systems; highly reliable complex systems; information and decision systems; autonomous systems; biomedical and chemical systems; and secure networks and communications.