
DFC波长扩展
从1560 nm到420-2000 nm的波长转换
- 模块化扩展
- 用于DFC CORE +
- 独立的远程控制不同的扩展
- 每个DFC EXT最多三个扩展
- DFC EXT外壳中的自定义扩展和节拍检测
可以使用各种扩展模块将DFC CORE+的无偏移量基本输出从1560 nm转换到420 nm到2000 nm之间的任意波长。这些模组的波长转换是通过TOPTICA公司成熟的超快光纤激光器技术实现的。所有扩展模块均使用高度稳定的全光纤放大,非线性转换和压缩。 所有扩展模块的输出功率均可实现连续激光器的锁相。 可应要求提供特殊的波长扩展,或将其包含在TOPTICA的完整稳定激光器系统中。
Request a Quotation Application Note Phase and Frequency Locking of Diode Lasers
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Specification
模型 描述 DFC EXT 波长扩展外壳 DFC IR 中心@1560nm,带宽>80nm,典型值100nm DFC NIR 中心@780nm,带宽>35nm,典型值40nm DFC DVIS* 波长范围420(frep = 80 MHz),450(frep = 200 MHz)-860 nm,带宽典型值 5nm@ 698nm,典型值 1nm@ 420nm DFC SCNIR* 波长范围840 nm(frep = 80 MHz),860 nm(frep = 200 MHz)-980 nm,带宽> 50 nm,典型 100nm@ 935nm DFC SCIR* 波长范围980-2000 nm,带宽> 150 nm 可根据要求提供其他扩展,*可调(受专利保护,US 8284808B2),请咨询更多详细信息
- Additional Information
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Applications
- Microwave Generation
- Laser Reference
- High-resolution Spectroscopy
- Dual-comb Spectroscopy
- Direct Frequency Comb Spectroscopy
- Interferometry
- Transportable AMO Systems
- Quantum Computing
- CEP-stable Seeders
- Rydberg Excitation (Rydberg Flyer for complete laser solutions)
- Optical Clocks
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Literature
- Scientific Article: E. Benkler et al., End-to-end topology for fiber comb based optical frequency transfer at the 10−21 level, Optics Express [27], 36886 (2019)
- Scientific Article: E. C. Cook et al., Resonant two-photon spectroscopy of the 2s3d 1D2 level of neutral 9Be Phys. Rev. Applied 101, 042503 (2020)
- Scientific Article: M. Collombon et al., Experimental Demonstration of Three-Photon Coherent Population Trapping in an Ion Cloud, Phys. Rev. Applied 12, 034035, (2019)
- Scientific Article: M. Collombon et al., Phase transfer between three visible lasers for coherent population trapping, Optics Letters Vol. 44, Issue 4 (2019)
- Scientific Article: A. Liehl et al., Ultrabroadband out-of-loop characterization of the carrier-envelope phase noise of an offset-free Er:fiber frequency comb. Optics Letters Vol. 42, Issue 10 (2017)
- Scientific Article: T. Puppe et al., Characterization of a DFG comb showing quadratic scaling of the phase noise with frequency, Optics Letters Vol. 41, Issue 8 (2016)
- Scientific Article: G. Krauss et al., All-passive phase locking of a compact Er:fiber laser system, Opt. Lett., 36, 540 (2011)
- Scientific Article: D. Fehrenbacher et al., Free-running performance and full control of a passively phase-stable Er:fiber frequency comb. Optica Vol. 2, Issue 10 (2015)
- Scientific Article: R. Kliese et al., Difference-frequency combs in cold atom physics, arXiv:1605.02426v1 (2016)
- Scientific Article: D. Brida et al., Ultrabroadband Er:fiber lasers, Laser & Photonics Review 8(3) (2014)
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