Marin Soljačić | |
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Born | February 7, 1974 Zagreb, Yugoslavia (present-day Croatia) |
Residence | U.S. |
Nationality | Croat |
Fields | Physicist and Electrical Engineer |
Institutions | Massachusetts Institute of Technology |
Alma mater | Massachusetts Institute of Technology |
Doctoral advisor | Mordechai Segev |
Known for | WiTricity, Nonlinear optics |
Notable awards | Adolph Lomb Medal (2005) TR35 (2006) MacArthur Fellowship (2008)[1] |
Marin Soljačić (born February 7, 1974) is a Croatian physicist and electrical engineer known for wireless non-radiative energy transfer.
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Marin Soljačić was born in Zagreb in 1974. After graduating from XV Gymnasium (MIOC) in Zagreb he got a scholarship from MIT where he got his BSc in physics and electrical engineering in 1996.[2] In 1998 he got his MSc from Princeton University and in 2000 he got his PhD in Physics. In 2005 he became a professor of Physics at MIT.[3] In 2008, he was awarded a MacArthur Fellowship.[4][5]
In 2007 Marin Soljačić and his assistants successfully made the first efficient non-radiative power transfer at a distance of 2 meters turning on a 60 W light bulb. Energy transfer was 40% efficient. Professor Soljačić's experiments and work in wireless energy transfer are related in spirit to the work of Nikola Tesla in the early 20th century,[6] but also have significant differences: unlike Tesla's failed efforts at long-range wireless energy transfer, the Soljačić group focuses only on short-range transfer, and unlike Tesla coils which resonantly transfer power with electric fields (which couple strongly to surrounding matter, most famously inducing artificial lightning) the Soljačić proposal uses coupling primarily via magnetic fields.[6] This work is currently being pursued in Soljačić's WiTricity company. Soljačić believes that low-power commercial application of this technology, such as charging of mobile phones, is several years away.[7]
In addition to wireless energy transfer, Prof. Soljačić works on numerous problems on electromagnetism in materials structured on the scale of the wavelength, such as micro- and nano-structured materials for infrared and visible light, including nonlinear optical devices and surface plasmons. His recent research, supported by a US$20 million grant from the U.S. Department of Energy, focuses on use of photonic crystals in solar cells.[7]