Dr.Aydogan Ozcan, “Second-Order Nonlinearities in Silica”
“Second-Order Nonlinearities in Silica”
Dr. Aydoğan Özcan
Ginzton Lab,
Stanford University,
CA, USA
Silica,
being a centrosymmetric material, does not naturally have a
second-order optical nonlinearity. This is the fundamental reason for
the lack of any second order nonlinear processes in fiber optic cables.
Poling techniques have been developed in the last several years to
induce a high second-order nonlinear coefficient in silica on the order
of ~0.8 pm/V. Silica-based electro-optic devices
such as modulators, switches, tunable filters or short wavelength
sources utilizing this nonlinearity would find important applications
in telecommunication networks, data storage and fiber optic sensor
applications. A thorough understanding of the magnitude and
extent of the nonlinear region is necessary in order to design
practical devices. The characterization of poled silica is made
difficult because the
induced nonlinearity is spatially nonuniform and thin (less than
40 µm) and the usual techniques to measure the nonlinearity are not
applicable.
In this talk, a group of novel techniques to uniquely characterize
the induced nonlinearity profile of poled silica films is discussed.
These tools help us to understand the physics of the poling induced
nonlinearity and to improve the poling process. As a result, applying these
characterization tools, a record-high peak nonlinear coefficient of
1.6 pm/V in thermally poled germanosilicate thin films is reported.
Finally, initial progress for the design, fabrication and testing of
novel electro-optic devices utilizing this poled glass technology is presented.
Jan. 3rd, 2005, 13:40, FENS L030