%0 Journal Article %1 Wu2023 %A Wu, Junjun %A Grabe, Tobias %A Götz, Jan-Luca %A Trapp, Joshua %A de Souza, Aureo Serrano %A Biermann, Tobias %A Wolf, Alexander %A Ley, Peer-Phillip %A Duan, Kun %A Lachmayer, Roland %A Ren, Wei %D 2023 %J Applied Physics B %K Joshua_Trapp ito journal %N 6 %P 87 %R 10.1007/s00340-023-08031-w %T Linear scalability of dense-pattern Herriott-type multipass cell design %U https://doi.org/10.1007/s00340-023-08031-w %V 129 %X Multipass cells (MPC) have been widely used for high-sensitivity spectroscopic measurements. We report the linear scalability in the configuration design of an MPC, which is derived from ray transfer equations in the non-paraxial approximation. As a proof of principle, twelve sets of Herriot-type cells ranging from 4.6þinspace×þinspace4.6þinspace×þinspace12.3 to 57.1þinspace×þinspace57.1þinspace×þinspace147.7 mm3 were investigated with their beam patterns and optical path lengths modeled. By taking the non-intersecting seven-circle beam pattern as a typical example, the designated beam patterns were successfully reproduced by modeling and the optical path length scales linearly with the cell size. Two sets of MPCs were also fabricated by additive manufacturing to further justify the rationale of linear scalability. Possible effects of beam spot size and the signal-to-noise ratio on the miniaturization and escalation of MPCs were discussed. This work contributes to a new insight into the cell configuration and will be useful for accelerating the cell design at various scales.

@article{Wu2023, abstract = {Multipass cells (MPC) have been widely used for high-sensitivity spectroscopic measurements. We report the linear scalability in the configuration design of an MPC, which is derived from ray transfer equations in the non-paraxial approximation. As a proof of principle, twelve sets of Herriot-type cells ranging from 4.6{\thinspace}{\texttimes}{\thinspace}4.6{\thinspace}{\texttimes}{\thinspace}12.3 to 57.1{\thinspace}{\texttimes}{\thinspace}57.1{\thinspace}{\texttimes}{\thinspace}147.7 mm3 were investigated with their beam patterns and optical path lengths modeled. By taking the non-intersecting seven-circle beam pattern as a typical example, the designated beam patterns were successfully reproduced by modeling and the optical path length scales linearly with the cell size. Two sets of MPCs were also fabricated by additive manufacturing to further justify the rationale of linear scalability. Possible effects of beam spot size and the signal-to-noise ratio on the miniaturization and escalation of MPCs were discussed. This work contributes to a new insight into the cell configuration and will be useful for accelerating the cell design at various scales.}, added-at = {2023-08-16T14:22:19.000+0200}, author = {Wu, Junjun and Grabe, Tobias and G{\"o}tz, Jan-Luca and Trapp, Joshua and de Souza, Aureo Serrano and Biermann, Tobias and Wolf, Alexander and Ley, Peer-Phillip and Duan, Kun and Lachmayer, Roland and Ren, Wei}, biburl = {https://puma.ub.uni-stuttgart.de/bibtex/2534c17c8564481e298c0c5d454337031/joshua_trapp}, day = 09, doi = {10.1007/s00340-023-08031-w}, interhash = {14a035d91a3a20cd20f4803515c7513c}, intrahash = {534c17c8564481e298c0c5d454337031}, issn = {1432-0649}, journal = {Applied Physics B}, keywords = {Joshua_Trapp ito journal}, month = may, number = 6, pages = 87, timestamp = {2023-08-16T14:22:19.000+0200}, title = {Linear scalability of dense-pattern Herriott-type multipass cell design}, url = {https://doi.org/10.1007/s00340-023-08031-w}, volume = 129, year = 2023 }