دوره 17، شماره 1 - ( 10-1401 )
جلد 17 شماره 1 صفحات 80-73 |
برگشت به فهرست نسخه ها
Download citation:
BibTeX | RIS | EndNote | Medlars | ProCite | Reference Manager | RefWorks
Send citation to:
BibTeX | RIS | EndNote | Medlars | ProCite | Reference Manager | RefWorks
Send citation to:
Heydarinasab Z, Karami M, Sarreshtedari F. Investigation and Optimization of Sub-Doppler DAVLL Error Signal for ECDL Stabilization. IJOP 2023; 17 (1) :73-80
URL: http://ijop.ir/article-1-541-fa.html
URL: http://ijop.ir/article-1-541-fa.html
Investigation and Optimization of Sub-Doppler DAVLL Error Signal for ECDL Stabilization. . 1401; 17 (1) :73-80
چکیده: (108 مشاهده)
Sub-Doppler dichroic atomic vapor laser lock (DAVLL) is a modulation-free laser stabilization method that combines DAVLL and saturated absorption spectroscopy (SAS). The performance of this highly sensitive stabilization technique strongly depends on the characteristics of the generated error signal. The slope of the error signal determines the lock sensitivity or how fast the frequency compensation could be made in the feedback loop, and the amplitude of the error signal determines the lock stability or how much noise the feedback loop can tolerate before laser unlocking. We have analytically modeled the error signal of the sub-Doppler DAVLL considering all possible transitions between Zeeman sublevels and compared it with the experimental results. Using the analytical and experimental results, it is shown that the values of the required magnetic fields for maximizing the slope and amplitude of the error signal are close to each other. Selecting the mentioned values of the magnetic field for optimization of the sub-Doppler DAVLL error signal is highly useful for sensitive and stable laser locking.
نوع مطالعه: پژوهشي |
موضوع مقاله:
لیزرها، تقویت کنندههای اپتیکی و اپتیک لیزر
دریافت: 1402/5/30 | ویرایش نهایی: 1402/10/27 | پذیرش: 1402/10/29 | انتشار: 1402/11/1
دریافت: 1402/5/30 | ویرایش نهایی: 1402/10/27 | پذیرش: 1402/10/29 | انتشار: 1402/11/1
فهرست منابع
1. Debs, J., N. Robins, A. Lance, M. Kruger, and J. Close, Piezo-locking a diode laser with saturated absorption spectroscopy. Applied optics, 2008. 47(28): p. 5163-5166. [DOI:10.1364/AO.47.005163]
2. Kulatunga, P., H. Busch, L. Andrews, and C. Sukenik, Two-color polarization spectroscopy of rubidium. Optics Communications, 2012. 285(12): p. 2851-2853. [DOI:10.1016/j.optcom.2012.02.032]
3. Corwin, K.L., Z.-T. Lu, C.F. Hand, R.J. Epstein, and C.E. Wieman, Frequency-stabilized diode laser with the Zeeman shift in an atomic vapor, in Collected Papers Of Carl Wieman. 2008, World Scientific. p. 809-812. [DOI:10.1142/9789812813787_0114]
4. Ghashghaei, F., A. Rashedi, F. Sarreshtedari, and M. Sabooni, Effect of the magnetically induced dichroism on the distribution of atomic polarization in Cesium vapor cells. Advanced Optical Technologies, 2020. 9(4): p. 209-215. [DOI:10.1515/aot-2019-0066]
5. Kim, J.I., C.Y. Park, J.Y. Yeom, E.B. Kim, and T.H. Yoon, Frequency-stabilized high-power violet laser diode with an ytterbium hollow-cathode lamp. Optics letters, 2003. 28(4): p. 245-247. [DOI:10.1364/OL.28.000245]
6. Millett-Sikking, A., I.G. Hughes, P. Tierney, and S.L. Cornish, DAVLL lineshapes in atomic rubidium. Journal of Physics B: Atomic, Molecular and Optical Physics, 2006. 40(1): p. 187. [DOI:10.1088/0953-4075/40/1/017]
7. Su, D.-Q., R.-J. Liu, C.-B. Zhang, Z.-H. Ji, Y.-T. Zhao, L.-T. Xiao, and S.-T. Jia, Laser frequency stabilization in sub-nanowatt level using nanofibers. Journal of Physics D: Applied Physics, 2018. 51(46): p. 465001. [DOI:10.1088/1361-6463/aae2f8]
8. Yin, S., H. Liu, J. Qian, T. Hong, Z. Xu, and Y. Wang, Observation and optimization of DAVLL spectra on the 1S0-3P1 transition of neutral mercury atom. Optics Communications, 2012. 285(24): p. 5169-5174. [DOI:10.1016/j.optcom.2012.07.061]
9. Couturier, L., I. Nosske, F. Hu, C. Tan, C. Qiao, Y. Jiang, P. Chen, and M. Weidemüller, Laser frequency stabilization using a commercial wavelength meter. Review of Scientific Instruments, 2018. 89(4). [DOI:10.1063/1.5025537]
10. Jia, F., J. Zhang, L. Zhang, F. Wang, J. Mei, Y. Yu, Z. Zhong, and F. Xie, Frequency stabilization method for transition to a Rydberg state using Zeeman modulation. Applied Optics, 2020. 59(7): p. 2108-2113. [DOI:10.1364/AO.384315]
11. Zi, F., X. Wu, W. Zhong, R.H. Parker, C. Yu, S. Budker, X. Lu, and H. Müller, Laser frequency stabilization by combining modulation transfer and frequency modulation spectroscopy. Applied optics, 2017. 56(10): p. 2649-2652. [DOI:10.1364/AO.56.002649]
12. Crump, P., C. Schultz, H. Wenzel, G. Erbert, and G. Tränkle, Efficiency-optimized monolithic frequency stabilization of high-power diode lasers. Journal of Physics D: Applied Physics, 2012. 46(1): p. 013001. [DOI:10.1088/0022-3727/46/1/013001]
13. Galiev, R.R., N.M. Kondratiev, V.E. Lobanov, A.B. Matsko, and I.A. Bilenko, Optimization of laser stabilization via self-injection locking to a whispering-gallery-mode microresonator. Physical Review Applied, 2020. 14(1): p. 014036. [DOI:10.1103/PhysRevApplied.14.014036]
14. Jeong, J., S. Lee, S. Hwang, J. Baek, H.-R. Noh, and G. Moon, Theoretical and Experimental Study of Optimization of Polarization Spectroscopy for the D2 Closed Transition Line of 87Rb Atoms. Applied Sciences, 2021. 11(16): p. 7219. [DOI:10.3390/app11167219]
15. Giannini, R., E. Breschi, C. Affolderbach, G. Bison, G. Mileti, H.-P. Herzig, and A. Weis. Sub-Doppler diode laser frequency stabilization with the DAVLL scheme on the D1 line of a 87Rb vapor-cell. in 14th International School on Quantum Electronics: Laser Physics and Applications. 2007. SPIE.
16. Petelski, T., M. Fattori, G. Lamporesi, J. Stuhler, and G. Tino, Doppler-free spectroscopy using magnetically induced dichroism of atomic vapor: a new scheme for laser frequency locking. The European Physical Journal D-Atomic, Molecular, Optical and Plasma Physics, 2003. 22: p. 279-283. [DOI:10.1140/epjd/e2002-00238-4]
17. Su, D.-Q., T.-F. Meng, Z.-H. Ji, J.-P. Yuan, Y.-T. Zhao, L.-T. Xiao, and S.-T. Jia, Application of sub-Doppler DAVLL to laser frequency stabilization in atomic cesium. Applied optics, 2014. 53(30): p. 7011-7016. [DOI:10.1364/AO.53.007011]
18. Wang, J., S. Yan, Y. Wang, T. Liu, and T. Zhang, Modulation-free frequency stabilization of a grating-external-cavity diode laser by magnetically induced sub-Doppler dichroism in cesium vapor cell. Japanese journal of applied physics, 2004. 43(3R): p. 1168. [DOI:10.1143/JJAP.43.1168]
19. Karami, M., Z. Heydarinasab, and F. Sarreshtedari Sub-Doppler dichroism as a useful tool in alkali atoms hyperfine spectroscopy. Laser Physics Letter, 2024: p. submitted for publication. [DOI:10.1088/1555-6611/ad04c7]
20. Choi, G.-W. and H.-R. Noh, Sub-Doppler DAVLL spectra of the D1 line of rubidium: a theoretical and experimental study. Journal of Physics B: Atomic, Molecular and Optical Physics, 2015. 48(11): p. 115008. [DOI:10.1088/0953-4075/48/11/115008]
21. Liu, H., S. Yin, J. Qian, Z. Xu, and Y. Wang, Optimization of Doppler-free magnetically induced dichroic locking spectroscopy on the 1S0-3P1 transition of a neutral mercury atom. Journal of Physics B: Atomic, Molecular and Optical Physics, 2013. 46(8): p. 085005. [DOI:10.1088/0953-4075/46/8/085005]
22. Mudarikwa, L., K. Pahwa, and J. Goldwin, Sub-Doppler modulation spectroscopy of potassium for laser stabilization. Journal of Physics B: Atomic, Molecular and Optical Physics, 2012. 45(6): p. 065002. [DOI:10.1088/0953-4075/45/6/065002]
23. Sarkisyan, D., A. Papoyan, T. Varzhapetyan, J. Alnis, K. Blush, and M. Auzinsh, Sub-Doppler spectroscopy of Rb atoms in a sub-micron vapour cell in the presence of a magnetic field. Journal of Optics A: Pure and Applied Optics, 2004. 6(3): p. S142. [DOI:10.1088/1464-4258/6/3/023]
24. M .Karami, Z.H.N., F. Sarreshtedari, Implementation of Sup-Doppler DAVLL laser lock on atomic transition, in INC29-1331. 2023.
| بازنشر اطلاعات | |
 |
این مقاله تحت شرایط Creative Commons Attribution-NonCommercial 4.0 International License قابل بازنشر است. |
