TY - JOUR
T1 - Fluorescence double resonance optical pumping spectrum and its application for frequency stabilization in millimeter scale vapor cells
AU - Talker, Eliran
AU - Stern, Liron
AU - Naiman, Alex
AU - Barash, Yefim
AU - Levy, Uriel
N1 - Publisher Copyright:
© 2017 The Author(s).
PY - 2017/12
Y1 - 2017/12
N2 - In recent years, we are observing substantial efforts towards the miniaturization of atomic cells to a millimeter scale and below, with the ultimate goal of enabling efficient and compact light vapor interactions. However, such miniaturization results in a reduction in optical path, effectively reducing the contrast of the optical signal. In order to overcome this obstacle, we have introduced and demonstrated a new approach of fluorescence double resonance optical pumping (FDROP) in the ladder-type atomic system. We have developed a theoretical model to predict the FDROP spectrum and validated this model using experimental results in a millimeter-size cell. We show that the contrast of fluorescence signal of the FDROP approach is higher than the transmission signal in the double resonance optical pumping approach. Taking advantage of this desired property, we have used the FDROP for the purpose of stabilizing the frequency of a laser operating at the telecom waveband with the hyperfine structure of the 5P3/2–4D5/2 transition in a millimeter-size cell. By beating the stabilized laser to another stabilized laser, we obtained frequency instability floor of 9×10−10 at around 1000 s in terms of Allan deviation. Such sources which are stabilized to miniaturized cells may play an important building block in diverse fields ranging e.g. from communication to metrology.
AB - In recent years, we are observing substantial efforts towards the miniaturization of atomic cells to a millimeter scale and below, with the ultimate goal of enabling efficient and compact light vapor interactions. However, such miniaturization results in a reduction in optical path, effectively reducing the contrast of the optical signal. In order to overcome this obstacle, we have introduced and demonstrated a new approach of fluorescence double resonance optical pumping (FDROP) in the ladder-type atomic system. We have developed a theoretical model to predict the FDROP spectrum and validated this model using experimental results in a millimeter-size cell. We show that the contrast of fluorescence signal of the FDROP approach is higher than the transmission signal in the double resonance optical pumping approach. Taking advantage of this desired property, we have used the FDROP for the purpose of stabilizing the frequency of a laser operating at the telecom waveband with the hyperfine structure of the 5P3/2–4D5/2 transition in a millimeter-size cell. By beating the stabilized laser to another stabilized laser, we obtained frequency instability floor of 9×10−10 at around 1000 s in terms of Allan deviation. Such sources which are stabilized to miniaturized cells may play an important building block in diverse fields ranging e.g. from communication to metrology.
KW - Absorption spectroscopy
KW - Atomic excitation
KW - Atomic spectra
KW - Fluorescence spectroscopy
KW - Laser frequency stabilization
UR - http://www.scopus.com/inward/record.url?scp=85052566241&partnerID=8YFLogxK
U2 - 10.1088/2399-6528/aa9396
DO - 10.1088/2399-6528/aa9396
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AN - SCOPUS:85052566241
SN - 2399-6528
VL - 1
JO - Journal of Physics Communications
JF - Journal of Physics Communications
IS - 5
M1 - 055016
ER -