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Advanced noise reduction techniques for ultra-low phase noise optical-to-microwave division with femtosecond fiber combs

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arxiv 1012.0852 v2 pith:6DQ6KW3W submitted 2010-12-03 physics.optics physics.ins-det

Advanced noise reduction techniques for ultra-low phase noise optical-to-microwave division with femtosecond fiber combs

classification physics.optics physics.ins-det
keywords noisephasefrequencycombsdivisioncombfemtosecondfiber
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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We report what we believe to be the lowest phase noise optical-to-microwave frequency division using fiber-based femtosecond optical frequency combs: a residual phase noise of -120dBc/Hz at 1 Hz offset from a 11.55GHz carrier frequency. We furthermore report a detailed investigation into the fundamental noise sources which afflicts the division process itself. Two frequency combs with quasi-identical configurations are referenced to a common ultrastable cavity laser source. To identify each of the limiting effects we implement an ultra-low noise carrier-suppression measurement system, which circumvents the detection and amplification noise of more conventional techniques. This technique now allows the suppression of these unwanted sources of noise to very low levels. In the Fourier frequency range of ~200 Hz to 100 kHz, a fed-forward technique based on a voltage-controlled phase shifter delivers a further noise reduction of 10 dB. For lower Fourier frequencies, optical power stabilization is implemented in order to reduce the relative intensity noise which causes unwanted phase noise through power to phase conversion in the detector. We implement and compare two possible control schemes based on an acousto-optical modulator and comb pump current. We also present wideband measurements on the relative intensity noise of the fiber comb.

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