https://community.element14.com/learn/publications/w/documents/7512/microscopic-switches-designed-for-future-optoelectronicsen-USTelligent Community 12https://community.element14.com/learn/publications/w/documents/7512/microscopic-switches-designed-for-future-optoelectronicsThu, 07 Oct 2021 07:38:07 GMT93d5dcb4-84c2-446f-b2cb-99731719e767:acf1c595-ab1c-451e-bc8d-09bddc6a5560e14newshttps://community.element14.com/learn/publications/w/documents/7512/microscopic-switches-designed-for-future-optoelectronics#commentsCurrent Revision posted to Documents by e14news on 10/7/2021 7:38:07 AM<br /> <span>Optoelectronics systems in the future could benefit from the creation of light-based switches which work in the same way as a conventional transistor.</span><br /><br /><span>Professor Tobias Kippenberg, who is a tenure track assistant professor at Ecole Polytechnique Federale de Lausanne (EPFL) and a team leader at the Max Planck Institute of Quantum Optics, headed up the group at the EPFL Laboratory of Photonics and Quantum Measurements.</span><br /><br /><span>Their research has yielded a means of using lasers within optoelectronics systems to operate switches similar to transistors; a strong beam is used to turn on or off a secondary, output stream of light.</span><br /><br /><span>Light entering the optical microresonator is trapped within a glass structure which guides it into a circular path while vibrating at a frequency 10,000 times that of a wine glass.</span><br /><br /><span>Radiation pressure of light entering the device can deform its interior cavity, causing the light to become coupled with the vibrations in a way that can be controlled using a secondary beam.</span><a href="http://feeds.directnews.co.uk/feedtrack/justcopyright.gif?feedid=1785&amp;itemid=800232512"><img alt="ADNFCR-1785-ID-800232512-ADNFCR" src="http://feeds.directnews.co.uk/feedtrack/justcopyright.gif?feedid=1785&amp;itemid=800232512" /></a><div style="clear:both;"></div>