Abstract
Laser-induced grating spectroscopy (LIGS) is for the first time explored in a configuration based on the crossing of two focused femtosecond (fs) laser pulses (800-nm wavelength) and a focused continuous-wave (cw) laser beam (532-nm wavelength). A thermal grating was formed by multi-photon absorption of the fs-laser pulses by hbox {N}_{{2}} with a pulse energy around 700 upmu J (sim 45 TW/hbox {cm}^{2}). The feasibility of this LIGS configuration was investigated for thermometry in heated nitrogen gas flows. The temperature was varied from room temperature up to 750 K, producing strong single-shot LIGS signals. A model based on the solution of the linearized hydrodynamic equations was used to extract temperature information from single-shot experimental data, and the results show excellent agreement with the thermocouple measurements. Furthermore, the fluorescence produced by the fs-laser pulses was investigated. This study indicates an 8-photon absorption pathway for hbox {N}_{{2}} in order to reach the hbox {B}^{3}Pi _{g} state from the ground state, and 8 + 5 photon excitation to reach the hbox {B}^{2}Sigma _{u}^{+} state of the hbox {N}_{2}^{+} ion. At pulse energies higher than 1 mJ, the LIGS signal was disturbed due to the generation of plasma. Additionally, measurements in argon gas and air were performed, where the LIGS signal for argon shows lower intensity compared to air and hbox {N}_{{2}}.
Highlights
Laser-induced grating spectroscopy (LIGS) is for the first time explored in a configuration based on the crossing of two focused femtosecond laser pulses (800-nm wavelength) and a focused continuous-wave laser beam (532-nm wavelength)
The feasibility of this LIGS configuration was investigated for thermometry in heated nitrogen gas flows
The top part shows the emission spectrum recorded in N2 gas flow at 293 K for a fs-laser pulse energy of 1.9 mJ and the simulated spectrum in PGOPHER
Summary
Laser-induced grating spectroscopy (LIGS) is for the first time explored in a configuration based on the crossing of two focused femtosecond (fs) laser pulses (800-nm wavelength) and a focused continuous-wave (cw) laser beam (532-nm wavelength). A thermal grating was formed by multiphoton absorption of the fs-laser pulses by N2 with a pulse energy around 700 μ J (∼ 45 TW/cm[2 ]). The feasibility of this LIGS configuration was investigated for thermometry in heated nitrogen gas flows. In order to probe such processes, proper analytical techniques with a sufficient degree of spatial and temporal resolution should be employed. These techniques should at the same time not alter the chemistry and gas flow, and since many species are unstable, measurements should be performed in-situ. Several different laser-based diagnostic techniques have been developed, e.g. for species concentration, temperature, velocity and particle measurements, in order to meet these high demands[1,2,3]
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
