{"id":391,"date":"2018-11-15T10:39:19","date_gmt":"2018-11-15T15:39:19","guid":{"rendered":"http:\/\/www.montclair.edu\/physics-astronomy\/?p=391"},"modified":"2018-11-15T10:42:01","modified_gmt":"2018-11-15T15:42:01","slug":"revealing-the-secrets-of-the-universe","status":"publish","type":"post","link":"https:\/\/www.montclair.edu\/physics-astronomy\/2018\/11\/15\/revealing-the-secrets-of-the-universe\/","title":{"rendered":"Revealing the Secrets of the Universe"},"content":{"rendered":"
When black holes collide or neutron stars merge, they produce minute ripples in space-time that can be measured by gravitational-wave detectors. Since 2015, when the first gravitational wave from colliding black holes was measured by LIGO \u2013 the Laser Interferometer Gravitational-Wave Observatory \u2013 four more black hole collisions have been detected, as well as a binary neutron star merger. The significance of these discoveries, which confirmed century-old predictions made by Albert Einstein, were acknowledged by the 2017 Nobel Prize in Physics.<\/p>\n
Rodica Martin, a professor in the newly launched Department of Physics and Astronomy, is a member of the LIGO team. She has recently received a $90,000 National Science Foundation grant to study the optical properties of materials that can be used to develop the next generation of gravitational-wave detectors.<\/p>\n
This grant will allow me to deepen my studies in new areas that contribute to increasing the sensitivity of future detectors. With more sensitive instruments, LIGO can detect gravitational waves from sources that are much further away, or that are too weak to observe with current detectors, giving us new insights on the dynamics of the cosmos.<\/p>\n