Sub-MHz linewidth distributed feedback laser at 780.24-nm emission wavelength for 87Rb applications

“…The DFB lasers were fabricated on an aluminium-free active area [5,6] four-quantum-well GaAs/AlGaAs wafer material, with an epilayer structure that was designed for narrow-linewidth applications. The epilayer material was optimized over previous designs at 780.24 nm [5,6] to reduce modal propagation losses and far-field emission pattern to decrease the beam divergence in the epilayer direction to 20º, potentially improving the single-mode fibre coupling up to a simulated value of 80%. A third-order Bragg grating was patterned on a 500 nm thick hydrogen silsesquioxane (HSQ) resist mask by electron beam lithography (EBL).…”

“…High accuracy optical clocks require lasers with sufficiently narrow linewidth, in this case significantly less than the 87 Rb 2-photon transition of 300 kHz [1]. Such diode lasers can also be integrated with Si3N4 photonic platforms [2,3] whilst maintaining single mode and narrow linewidth operation [4][5][6] with the potential for future chip-scale quantum technology systems. In this paper we present 3 mm long cavity DFB lasers with over 48 mW power output, side-mode suppression ratios (SMSRs) approaching 40 dB, and linewidths of 3.67 kHz that demonstrated suitable for 87 Rb two-photon transitions at 778.1 nm in free-running conditions.…”

Single-mode Distributed Feedback Lasers for ⁸⁷Rb Two-Photon Quantum Technology Systems

“…The DFB lasers were fabricated on an aluminium-free active area [5,6] four-quantum-well GaAs/AlGaAs wafer material, with an epilayer structure that was designed for narrow-linewidth applications. The epilayer material was optimized over previous designs at 780.24 nm [5,6] to reduce modal propagation losses and far-field emission pattern to decrease the beam divergence in the epilayer direction to 20º, potentially improving the single-mode fibre coupling up to a simulated value of 80%. A third-order Bragg grating was patterned on a 500 nm thick hydrogen silsesquioxane (HSQ) resist mask by electron beam lithography (EBL).…”

“…High accuracy optical clocks require lasers with sufficiently narrow linewidth, in this case significantly less than the 87 Rb 2-photon transition of 300 kHz [1]. Such diode lasers can also be integrated with Si3N4 photonic platforms [2,3] whilst maintaining single mode and narrow linewidth operation [4][5][6] with the potential for future chip-scale quantum technology systems. In this paper we present 3 mm long cavity DFB lasers with over 48 mW power output, side-mode suppression ratios (SMSRs) approaching 40 dB, and linewidths of 3.67 kHz that demonstrated suitable for 87 Rb two-photon transitions at 778.1 nm in free-running conditions.…”

Single-mode Distributed Feedback Lasers for ⁸⁷Rb Two-Photon Quantum Technology Systems

“…Where great stability and reliability are required this can be achieved with, e.g. : lasers using interference-filter based feedback [28,29]; modular laser systems demonstrating month-long sub-MHz locking [30]; micro-integrated ECDLs with no movable parts for harsh, challenging space-based environments [31]; and distributed bragg reflector (DBR [32]) or distributed feedback (DFB [33]) laser systems.…”

A simple, powerful diode laser system for atomic physics

“…Approaches to achieve this end range from semiconductor distributed feedback lasers (DFB) [12][13][14][15] and distributed Bragg reflector (DBR) lasers [16][17][18][19][20], to fiber-based ring lasers [1,[21][22][23][24][25][26]. While these single frequency devices may produce high power and a low linewidth, unfortunately, their tunability is typically low, on the order of a few nanometers.…”

Widely Tunable, Low Linewidth, and High Power Laser Source using an Electro-Optic Comb and Injection-Locked Slave Laser Array