Raman Doppler Velocimetry: a unified approach for measuring molecular flow velocity, temperature, and pressure
Abstract
Molecular flow velocity (one component), translational temperature, and static pressure of N2 are measured in a supersonic wind tunnel using inverse Raman spectroscopy. For velocity, the technique employs the large Doppler shift exhibited by the molecules when the pump and probe laser beams are counterpropagating (backward scattering). A retrometer system is employed to yield an optical configuration insensitive to mechanical vibration, which has the additional advantage of simultaneously obtaining both the forward and backward scattered spectra. The forward and backward line breadths and their relative Doppler shift can be used to determine the static pressure, translational temperature, and molecular flow velocity. A demonstration of the technique was performed in a continuous airflow supersonic wind tunnel in which data were obtained under the following conditions: (1) free-stream operation at five set Mach number levels over the 2.50-4.63 range; (2) free-stream operation over a range of Reynolds number (at a fixed Mach number) to vary systematically the static pressure; and (3) operation in the flow field of a simple aerodynamic model to assess beam steering effects in traversing the attached shock layer.
- Publication:
-
Applied Optics
- Pub Date:
- January 1986
- DOI:
- Bibcode:
- 1986ApOpt..25...14E
- Keywords:
-
- Flow Measurement;
- Flow Velocity;
- Laser Doppler Velocimeters;
- Molecular Flow;
- Raman Spectroscopy;
- Pressure Measurement;
- Spectral Line Width;
- Supersonic Wind Tunnels;
- Temperature Measurement;
- Velocity Measurement;
- Instrumentation and Photography;
- VELOCIMETRY;
- SPECTROSCOPY: RAMAN;
- SCATTERING: STIMULATED RAMAN;
- RAMAN EFFECT;
- FLOW;
- DOPPLER EFFECT;
- TEMPERATURE