Schermer Ross T, Bucholtz Frank, Villarruel Carl A, Gil Gil Jesus, Andreadis Tim D, Williams Keith J
U.S. Naval Research Laboratory, 4555 Overlook Avenue, SW, Washington, D.C. 20375, USA.
Opt Express. 2009 Dec 7;17(25):22586-602. doi: 10.1364/OE.17.022586.
This paper presents a detailed investigation of the physical mechanisms underlying the disruption of a lithium niobate electrooptic modulator by RF pulses. It is shown that short-term modulator disruption is a direct consequence of resistive heating within the metal conductor of the coplanar waveguide electrode, which leads to a thermo-optic optical phase shift in the waveguides of the modulator. Resistive heating is also shown to contribute to permanent modulator damage at higher RF power. These results indicate that short-term RF disruption, and possibly RF damage, can be mitigated through improved thermal management. They also predict that short-term photonic link disruption can be reduced, if not eliminated, by use of a phase modulated photonic link.
本文详细研究了射频脉冲对铌酸锂电光调制器造成破坏的物理机制。结果表明,调制器的短期破坏是共面波导电极金属导体内部电阻性发热的直接后果,这会导致调制器波导中出现热光光学相移。研究还表明,在较高射频功率下,电阻性发热也会导致调制器永久性损坏。这些结果表明,通过改进热管理可以减轻射频的短期破坏,甚至可能减轻射频损伤。研究还预测,使用相位调制光子链路,即使不能消除,也可以减少光子链路的短期中断。