Abstract
We have investigated the adhesion effect on the hyperfine frequency shift of an alkali metal vapor cell with paraffin coating using the peak-force tapping AFM (atomic force microscopy) technique by developing a uniform and high-quality paraffin coating method. We observed a relatively uniform temperature field on the substrate can be obtained theoretically and experimentally with the closed-type previse temperature-controlled evaporation method. The roughness and adhesion of the coating surface as low as 0.8 nm and 20 pN were successfully obtained, respectively. Furthermore, the adhesion information dependence of the topography was investigated from the force spectroscopy, which indicates that the adhesion force jumped on the edge of the particles and stepped but remained constant above the particles and steps regardless of their height for paraffin coating. Finally, we can evaluate the relaxation and the hyperfine frequency shift of an alkali metal vapor cell through accurately calculating the surface adsorption energy of the paraffin coating from peak-force tapping information. This finding is crucial for improving the sensitivity of the atomic sensors through directly analyzing the adhesion effect of the paraffin coating films instead of measuring the relaxation times.
Highlights
Coated alkali vapor cells with paraffin coating have been extensively investigated because of their long spin-polarization lifetime and high detection sensitivity for application in a wide range of atomic sensors, such as atomic magnetometers, atomic clocks, and magneto-optical traps [1,2,3,4]
The second point is the adhesion effect, occurring during the energy transfer in the process of surface adsorption [11], which seriously affects the hyperfine frequency shift closely related to the relaxation time for the alkali-metal atoms that interact with the paraffin coating
We successfully obtained a relatively flat paraffin coating with closed-type precise temperature-controlled evaporation and explored the adhesion effect on the hyperfine frequency shift of alkali metal vapor cell using the peak force tapping technique from simultaneous topography and adhesion information, which involves the energy transfer mechanism of the alkali atom colliding with vapor cell wall
Summary
Coated alkali vapor cells with paraffin coating have been extensively investigated because of their long spin-polarization lifetime and high detection sensitivity for application in a wide range of atomic sensors, such as atomic magnetometers, atomic clocks, and magneto-optical traps [1,2,3,4]. The coating performance is mainly measured by the relaxation time of the alkali metal vapor cell through optical quantum detection [14,15,16,17]. The second point is the adhesion effect, occurring during the energy transfer in the process of surface adsorption [11], which seriously affects the hyperfine frequency shift closely related to the relaxation time for the alkali-metal atoms that interact with the paraffin coating. We calculated the surface adsorption energy of the paraffin coating by analyzing the energy transfer of the force curve measurement, which provides a new idea for estimating the relaxation and the hyperfine frequency shift of alkali metal vapor cells
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
