Airborne Coherent Wind Lidar measurements of vertical and horizontal wind speeds for the investigation of gravity waves 18 th Coherent Laser Radar Conference, Boulder, CO, USA 27 June to 1 July 2016 Benjamin Witschas Stephan Rahm Johannes Wagner Andreas Dörnbrack
Recent gravity waves campaigns Overview and objectives Campaigns objectives Study dynamical coupling processes by gravity waves from the troposphere into the stratosphere and mesosphere by characterizing their complete life cycle: Gravity wave excitation propagation dissipation Improve GW parameterizations for use in climate models GW-LCYCLE I (Kiruna, Sweden) 2-14 Dec. 2013 DLR Falcon (e.g. Wind Lidar) Radiosondes (Alomar, Esrange, Sodankylä) Ground-based lidar and radar observations (ALOMAR, Esrange) GW-LCYCLE II (Kiruna, Sweden) 12 Jan. - 3 Feb. 2016 Instruments as in GW-LCYCLE I + coordinated flights with HALO Rayleigh lidar in Sodankylä DEEPWAVE (Christchurch, NZ) [1] Total period: 6 Jun. 22 Jul. 2014 NCAR GV (e.g. Rayleigh + Na-Lidar) DLR Falcon (29 Jun. 21 Jul.) Ground-based instruments (e.g. Rayleigh lidar) [1] Fritts et al., BAMS, 2016 The Deep Propagating Gravity Wave Experiment 18th CLRC - Boulder, CO, USA- 27th Jun.to 1. Jul. 2016 2
The 2µ airborne coherent Doppler Wind Lidar of DLR Instrument description Cooling + power supply Data acquisition 2µ transceiver + scanner Wavelength 2.022 µm repetition rate 500 Hz pulse energy 1.8 mj pulse length 0.5 µs (150 m) Off-axis telescope: Aperture 10 cm Resolution: Vertical 100 m Horizontal (scan) ~6.7 km (32 s) Horizontal (Nadir) ~0.2 km (1 s) Double Wedge Scanner: Elevation ±30 18th CLRC - Boulder, CO, USA- 27th Jun.to 1. Jul. 2016 3
The 2µ airborne coherent Doppler Wind Lidar of DLR Operation modes Scanning mode Fixed LOS-mode 20 0 2µm wind vector N D E 2µm wind vector 3 D wind vector Horizontal resolution ~ 6.7 km Vertical resolution = 100 m forcing/inflow conditions LOS wind (vertical wind speed) Horizontal resolution ~ 200 m Vertical resolution = 100 m GW amplitude and spectrum 18th CLRC - Boulder, CO, USA- 27th Jun.to 1. Jul. 2016 4
Vertical wind retrieval and correction GW-LCYCLE I 13.12.2013 Example case 1. Determine the actual lidar installation position [1] the actual laser beam pointing position can be calculated. 2. Using horizontal wind speed and direction from ECMWF re-analysis in order to calculate the projection in LOS direction. 3. Validate ECMWF data with lidar measurements 4. Correct LOS wind in order to retrieve vertical wind [1] Chouza et al., ACP, 2016 Vertical wind retrieved by airborne lidar 18th CLRC - Boulder, CO, USA- 27th Jun.to 1. Jul. 2016 5
Vertical wind retrieval and correction GW-LCYCLE I 13.12.2013 Example case Comparison of model and measurement (linear fit) yields: - r 2 = 0.85 - Slope = 1.00 - Intercept = 0.01 m/s ECMWF data is suitable for a reliable wind correction 18th CLRC - Boulder, CO, USA- 27th Jun.to 1. Jul. 2016 6
Vertical wind retrieval and correction GW-LCYCLE I 13.12.2013 Example case 18th CLRC - Boulder, CO, USA- 27th Jun.to 1. Jul. 2016 7
counts counts Vertical wind retrieval and correction GW-LCYCLE I 13.12.2013 Example case 900 800 Gauss-fit: x center = -0.23 m/s, = 0.42 m/s x center = -0.04 m/s, = 0.43 m/s x center = +0.20 m/s, = 0.45 m/s x center = - 0.01 m/s, = 0.42 m/s 800 700 700 600 500 400 600 500 400 300 300 200 200 100 100 0-1.5-1.0-0.5 0.0 0.5 1.0 1.5 LOS/(m/s) 0-1.5-1.0-0.5 0.0 0.5 1.0 1.5 LOS/(m/s) After correction, the bias of the vertical wind speed can be estimated to be less than 10 cm/s. The standard deviation (precision) is better than 0.5 m/s. 18th CLRC - Boulder, CO, USA- 27th Jun.to 1. Jul. 2016 8
Wind Lidar measurements for gravity wave research 2013-12-13a case example WRF model comparison Horizontal structure well represented by WRF model calculations. However, the amplitudes are by a factor of 2 underestimated. 18th CLRC - Boulder, CO, USA- 27th Jun.to 1. Jul. 2016 9
Results GW-LCYCLE II 2016-01-28a Scanning mode Vertical wind mode 18th CLRC - Boulder, CO, USA- 27th Jun.to 1. Jul. 2016 10
Results GW-LCYCLE II 2016-01-28a 18th CLRC - Boulder, CO, USA- 27th Jun.to 1. Jul. 2016 11
Results GW-LCYCLE II 2016-01-28a Wavelet analysis Tropopause Wave-breaking/secondary wave generation at the tropopause region 18th CLRC - Boulder, CO, USA- 27th Jun.to 1. Jul. 2016 12
wavelength/(km) wavelength/(km) wavelength/(km) Results GW-LCYCLE II 2016-01-28a 100 6.7-7.2 km power/(m 2 /s 2 ) 0.0 10 0.1 1 100 10 0 8.7-9.2 km 50 100 150 200 distance/(km) 0.2 1 0 50 100 150 200 distance/(km) 100 9.7 km 10 1 0 50 100 150 200 distance/(km) 18th CLRC - Boulder, CO, USA- 27th Jun.to 1. Jul. 2016 13
Summary The DLR airborne coherent Doppler wind lidar was successfully deployed in three campaigns aiming to investigate the life cycle of gravity waves from excitation to dissipation. Vertical wind speeds were measured with an accuracy of better than 10 cm/s and a precision of better than 0.5 m/s. Both, the horizontal and the vertical wind measurements yield valuable data for characterizing gravity waves e.g., inflow/excitation conditions, wave excitation, breaking, dissipation, etc. Outlook Combining measured vertical and horizontal wind profiles with other airborne and ground based data sets (currently performed). Implementing the possibility of determining the actual lidar installation position wrt. to the aircraft during flight flight attitude offset correction can be adapted for each flight leg or rather altitude Adapt the scan pattern for horizontal wind retrieval in areas of strong gravity wave forcing 18th CLRC - Boulder, CO, USA- 27th Jun.to 1. Jul. 2016 14