Title :
Thermal noise in optical reference resonators
Author :
Sterr, Uwe ; Legero, Thomas ; Mattei, Dan ; Kessler, T. ; Hagemann, Ch ; Riehle, Fritz ; Ye, John ; Martin, Miquel ; Wei Zhang
Author_Institution :
Phys.-Tech. Bundesanstalt (PTB), Braunschweig, Germany
Abstract :
Thermal noise fundamentally limits the frequency stability of optical resonators used in optical clocks or to generate ultrapure microwaves by optical frequency division. We will give an overview of the relevant noise mechanisms, their calculation and discuss different current developments to reduce the noise. In one approach a cryogenic silicon resonator with very low thermal noise operated at a temperature of 124 K, the point of zero thermal expansion, will be presented. With a laser stabilized to this resonator a fractional laser frequency instability of 10-16 for averaging times around one second has been reached.
Keywords :
cryogenics; elemental semiconductors; laser frequency stability; laser noise; microwave generation; optical resonators; silicon; thermal expansion; thermal noise; Si; cryogenic silicon resonator; fractional laser frequency instability; frequency stability; laser stability; optical clock; optical frequency division; optical reference resonator; point of zero thermal expansion; temperature 124 K; thermal noise; ultrapure microwave generation; Cavity resonators; Laser stability; Mirrors; Noise; Optical resonators; Silicon; Thermal noise;
Conference_Titel :
Metrology for Aerospace (MetroAeroSpace), 2014 IEEE
Conference_Location :
Benevento
DOI :
10.1109/MetroAeroSpace.2014.6865980
