1. Airborne Trace Gas Retrievals from GeoTASO and GCAS
Caroline Nowlan
Harvard-Smithsonian Center for Astrophysics
Kelly Chance, Gonzalo Gonzalez Abad, Xiong Liu, Amir Souri (Harvard-Smithsonian)
James Leitch, Lyle Ruppert (Ball Aerospace)
Alan Fried (INSTAAR, CU-Boulder)
Scott Janz, Matthew Kowalewski, Melanie Follette-Cook, Ken Pickering (NASA GSFC)
Chris Loughner (NOAA)
Jay Al-Saadi, Laura Judd (NASA LaRC)
Jay Herman (University of Maryland Baltimore County)
Elena Spinei (Virginia Tech)
Sally Pusede and Andrew Mondschein (University of Virginia)

2. GeoTASO and GCAS Airborne Instruments
GeoTASO = Geostationary Trace gas and Aerosol Sensor Optimization
GCAS = GEO-CAPE Airborne Simulator
NASA test-bed instruments for geostationary missions
Trace gas footprint at surface is ~250 m × 250 m to ~1 km x 1 km

3. GeoTASO NO2: DISCOVER-AQ Texas
13 September 2013 GeoTASO DISCOVER-AQ
9:15-10:20 Local Time
[Nowlan et al., AMT, 2016]

4. Mapping Morning and Afternoon NO2 Over Denver
2 August 2014: GeoTASO DISCOVER-AQ Colorado
8:00 – 11:30 AM Local time
2:00 – 4:00 pm local time
Slant
Column

5. SO2 Power Plant Plumes
Photo by J.B. Forbes
NO2 and SO2 downwind from Labadie Power Station (Missouri) on GeoTASO DISCOVER-AQ transit, 13 August 2014

6. GCAS NO2: Houston Validation
25 September 2013
Ignoring Pandora viewing geometry leads to a 20% bias in comparisons
P-3B spirals pass in and out of NO2 plumes

7. GCAS NO2: Houston Validation
Pandora vs. GCAS NO2
P-3B NCAR P-CL vs. GCAS NO2
GCAS NO2 50% higher than Pandora direct Sun NO2 but agrees with P-3B

8. GCAS NO2: Colorado Validation
Pandora NO2 vs. GCAS, DISCOVER-AQ Colorado 2014
Large difference with Pandora seen in Texas comparisons does not show up in Colorado

9. GCAS NO2: Colorado Validation
Pandora NO2 vs. GCAS, DISCOVER-AQ Colorado 2014
Large difference with Pandora seen in Texas comparisons does not show up in Colorado
Fort Collins site

10. First HCHO Observations from an Airborne Pushbroom Sensor
GCAS, 09/25/2013, Houston
Good agreement with P-3B spirals
HCHO retrieval meets 1e16 molecules/cm2 TEMPO precision at:
1 km × 1 km (GCAS)
250 m × 250 m (GeoTASO)

11. Validation and Error Estimation
DISCOVER-AQ provided a wealth of coincident data for validation and error estimation.
Error examples from Texas:
Heterogeneity of air mass factor along aircraft swath results almost entirely from 4 km CMAQ and 1 km MODIS surface BRDF
Parameter
Effect on NO2 VCD
Source
Neglecting aerosols
+10% bias overall
-15 – 25% individual
Simulations with HSRL lidar profiles
NO2 profile shape
+4% bias
CMAQ 4km
P3B in situ profiles
HCHO profile shape
+2% bias
Neglecting ground-based viewing geometry in comparisons
+20% overall
0 to >100 % at site
Pandora ground-based spectrometers
MODIS BRDF uncertainties
+5 – 23 % bias
Pandora
(Souri et al. 2018)

12. Airborne Remote Sensing Constraints on NOx Emissions
Several studies of Southeast US emissions [e.g., Souri et al., 2016, AE; Travis et al., 2016, ACP; Li et al., 2017, ACP] show that models tend to overestimate anthropogenic NOx sources and underestimate biogenic ones.
Possible causes:
Inadequate sampling (e.g., footprint)
Observation uncertainties
Model uncertainties other than emissions
Souri et al., 2016, AE

13. Airborne Remote Sensing Constraints on NOx Emissions
Airborne observations may alleviate some of these concerns
GCAS pixel is 2500 finer than OMI pixel
We can validate airborne observations against other campaign instruments
We performed a Kalman Filter inversion day by day using high resolution CMAQ-DDM (1x1 km2) in the Houston-Galveston-Brazoria area.

14. Houston, 25 Sept 2013: An Exceptional Event
NO2 Column
NO2 Surface
The 25th September experienced elevated ozone, NO2 and several VOCs [Pan et al., 2017; 2018, AE].
Such an underprediction in the model could not be mitigated using OMI.
GCAS provided a unique opportunity to detect and constrain an emission event anomaly in the Houston area.
Results ensure that next generation satellites (with better spatial and temporal resolutions) should have a unique capability to detect and constrain emissions anomalies.
Souri et al., 2018, JGR

15. Observational constraints on community-scale air pollution exposure inequalities
Air pollution in U.S. cities is often higher in low-income communities and communities of color.
U.S. EPA Surface Monitors
Does higher-resolution data reveal
greater disparities?
Sally Pusede, University of Virginia
Jeff Geddes, Boston University
Caroline Nowlan, Harvard Smithsonian Center for Astrophysics
Laura Judd and Jay Al-Saadi, NASA Langley Research Center
GeoTASO in black box region

16. Observational constraints on community-scale air pollution exposure inequalities
Exposure is a function of human travel patterns throughout the day.
To quantify exposure disparities, we are combining GeoTASO and GCAS measurements with travel-activity data for tens of thousands of individuals in Los Angeles and Houston.
Sally Pusede and Andrew Mondschein, University of Virginia

17. KORUS-AQ: New Molecules
First Detection of Glyoxal from an Airborne Instrument
First Detection of Nitrous Acid using Nadir Remote Sensing
Seoul
9 June 2016
16-18 LT
Seoul
9 June 2016
16-18 LT

18. Next Steps
Final GCAS and GeoTASO trace gas products for DISCOVER-AQ Colorado should be archived this summer
O3 profile work will be continued under KORUS-AQ and TEMPO projects
SAO is starting projects to produce OMPS (Suomi-NPP and NOAA- 20) products
Planning extensive satellite validation using in situ and remote sensing aircraft (GeoTASO and GCAS) HCHO data

19. Extra Slides

20. Air Quality Airborne Campaigns
Location
Date
Instrument
DISCOVER-AQ
Texas
September 2013
GeoTASO, GCAS
Colorado
July-August 2014
KORUS-AQ
South Korea
May-June 2016
GeoTASO
Lake Michigan
Ozone Study
Wisconsin &
Michigan
May-June 2017
GOES-R lightning study (NO2)
Southeast, Midwest US
2017
GCAS
Student Airborne Research Program
California
June 2017
Both GeoTASO and GCAS have participated in several additional ocean color campaigns.

21. SO2 Power Plant Plumes
Photo by J.B. Forbes
NO2 and SO2 downwind from Labadie Power Station (Missouri) on GeoTASO DISCOVER-AQ transit, 13 August 2014

22. GeoTASO and GCAS
Coincident flights within 20 minutes show NO2 variability over short time scales (Houston 09/13/2013 AM flight shown below)
[Nowlan et al., AMT, 2016]

23. Ozone Profiles
Ozone profile retrieval works but results are highly dependent on input parameters
No reference spectrum is ideal for airborne measurements
Current UV radiances imply a negative albedo  Absolute calibration and stray light corrections in early campaigns need improvement