1. MEASUREMENT OF TROPOSPHERIC COMPOSITION FROM SPACE IS DIFFICULT!
Tropopause
Stratopause
clouds
particles (dust)
air scattering
water vapor
strat ozone layer
variable surf. albedo
low thermal contrast
Mesosphere
Stratosphere
Ozone
layer
Troposphere

2. PRESENT AND SCHEDULED SATELLITE INSTRUMENTS FOR TROPOSPHERIC CHEMISTRY

3. SOLAR BACKSCATTER OBSERVATIONS FROM SPACE (TOMS, GOME, SCIAMACHY, OMI, OCO)
absorption
Backscattered
intensity IB l1 l2
wavelength
Slant optical depth
“Slant column”
Scattering by
Earth surface
and by atmosphere
EARTH SURFACE

4. AIR MASS FACTOR (AMF) CONVERTS SLANT COLUMN WS TO VERTICAL COLUMN W
“Geometric AMF” (AMFG) for non-scattering atmosphere: q
EARTH SURFACE

5. Illustrative retrieval of HCHO column at 340 nm
IN SCATTERING ATMOSPHERE, AMF DEPENDS ON VERTICAL DISTRIBUTION OF COLUMN
Illustrative retrieval of HCHO column at 340 nm
“Sigma” vertical coordinate = normalized pressure
Instrument
sensitivity w(s)
(“scattering
weight”)
what
GOME
sees
Vertical shape
factor S(s)
(normalized mixing ratio)
AMFG = 2.08
actual AMF = 0.71
Palmer et al. [2001]

6. USE GLOBAL 3-D MODEL DRIVEN BY ASSIMILATED METEOROLOGICAL DATA TO PROVIDE AMFs FOR EVERY SATELLITE VIEWING SCENE
GEOS-CHEM
MODEL
LIDORT
RAD.TRANSFER MODEL
AMF
spectral
fit
SATELLITE
DATA
SLANT
COLUMN
VERTICAL
COLUMN
Best information applied to each scene
Consistency in comparing model and observed columns
Apply with any 3-D model (recalculate AMFs using tabulated scattering weights)
ADVANTAGES OF
3-D MODEL APPROACH
FOR COMPUTING AMFs

7. THE GOME SATELLITE INSTRUMENT
Nadir-viewing solar backscatter instrument ( nm)
Low-elevation polar sun-synchronous orbit, 10:30 a.m. observation time
Field of view 320x40 km2, three cross-track scenes
Complete global coverage in 3 days
Operational since 1995
APPLY HERE TO MAPPING OF HCHO AND NO2 TROPOSPHERIC COLUMNS

8. USE GOME MEASUREMENTS OF NO2 AND HCHO COLUMNS TO MAP NOxAND VOC EMISSIONS
Tropospheric NO2 column ~ ENOx
Tropospheric HCHO column ~ EVOC
~ 2 km
hn (420 nm)
BOUNDARY
LAYER
hn (340 nm)
NO2 NO
HCHO CO OH
hours
O3, RO2
hours
VOC
1 day
HNO3
Emission
Deposition
Emission
NITROGEN OXIDES (NOx)
VOLATILE ORGANIC CARBON (VOC)

9. GOME HCHO SLANT COLUMNS (JULY 1996)
T. Kurosu, P.I. Palmer
T. Kurosu (SAO) and P. Palmer (Harvard)
Hot spots reflect high VOC emissions from fires and biosphere

10. HCHO COLUMNS FROM GOME OVER U.S.: July 1996 means
Palmer et al. [2001]
BIOGENIC ISOPRENE IS THE MAIN SOURCE OF HCHO IN U.S. IN SUMMER
GEIA
isoprene
emissions
R = 0.83
Bias 14%
Precision:
4x1015 cm-2

11. STRATEGY FOR GOME VALIDATION: USE 3-D MODEL AS INTERMEDIARY
GOME OBSERVATIONS
IN SITU OBSERVATIONS
Aircraft
Ground-based
Compare
Compare
GEOS-CHEM
model

12. MODEL vs. OBSERVED HCHO VERTICAL PROFILES OVER U.S. AND N. ATLANTIC
Aircraft observations from Y.-N. Lee (SOS) and A. Fried (NARE)
SOS (southeast U.S., Jul 1995)
Observations
Model
NARE (N. Atlantic, Sept 1997)
Palmer et al. [2001]

13. MODEL vs. OBSERVED SURFACE HCHO
Mean daytime HCHO surface observations
Jun-Aug
Model (1996) vs. observations
Palmer et al. [2002]

14. SLANT COLUMNS OF HCHO FROM GOME High values over southeast U. S
SLANT COLUMNS OF HCHO FROM GOME High values over southeast U.S. are due to biogenic isoprene emission
Note “isoprene volcano” over the Ozarks
Palmer et al. [2002]

15. DEPENDENCE OF GOME HCHO COLUMNS OVER THE OZARKS ON SURFACE AIR TEMPERATURE
Temperature dependence
of isoprene emission (GEIA)
Palmer et al. [2002]

16. USING GOME HCHO COLUMNS TO MAP ISOPRENE EMISSIONS
hours OH
hn, OH
Displacement/smearing length scale km
Get EISOP vs. WHCHO relationship from GEOS-CHEM

17. Model HCHO column [1016 molec cm-2] model without isoprene
GEOS-CHEM RELATIONSHIP BETWEEN HCHO COLUMNS AND ISOPRENE EMISSIONS IN N AMERICA Use relationship to map isoprene emissions from GOME observations NW NE
GEOS-CHEM
July 1996
Model HCHO column [1016 molec cm-2] SW SE
model without isoprene
Palmer
et al. [2002]
Isoprene emission [1013 atomC cm-2 s-1]

18. GOME GEIA (IGAC inventory) BEIS2 COMPARE TO…
MAPPING OF ISOPRENE EMISSIONS FOR JULY 1996 BY SCALING OF GOME FORMALDEHYDE COLUMNS [Palmer et al., 2002]
GOME
COMPARE TO…
GEIA (IGAC inventory)
BEIS2
(official EPA inventory)

19. SLANT COLUMNS OF NO2 FROM GOME Dominant stratospheric contribution (NO2 produced from N2O oxidation) Also see tropospheric hot spots (fossil fuel and biomass burning)
Remove stratospheric column and instrument artifacts using data over Pacific
Martin et al. [2002a]

20. SLANT COLUMNS OF TROPOSPHERIC NO2 FROM GOME
1996
Martin et al. [2002]

21. PROPAGATION OF ERRORS IN NO2 RETRIEVAL (errors e in 1015 molecules cm-2)
GOME SPECTRUM ( nm)
SLANT NO2 COLUMN
TROPOSPHERIC SLANT NO2 COLUMN
TROPOSPHERIC NO2 COLUMN
Fit spectrum
e1 = 0.8
Use Central Pacific GOME data with:
HALOE to test strat zonal invariance
PEM-Tropics, GEOS-CHEM 3-D model to treat tropospheric residual
Remove stratospheric contribution, diffuser plate artifact
e2 = 0.4
Use radiative transfer model with:
local vertical shape factors from GEOS-CHEM
local cloud information from CRAG
Apply AMF to convert slant column to vertical column
e3 =
Martin et al. [2002a]

22. GOME RETRIEVAL OF TROPOSPHERIC NO2 vs. GEOS-CHEM SIMULATION (July 1996)
Martin et al. [2002a]
GEIA emissions
scaled to 1996

23. CAN WE USE GOME TO ESTIMATE NOx EMISSIONS. TEST IN U. S
CAN WE USE GOME TO ESTIMATE NOx EMISSIONS? TEST IN U.S. WHERE GOOD A PRIORI EXISTS
Comparison of GOME retrieval (July 1996) to GEOS-CHEM model fields
using EPA emission inventory for NOx
GOME
GEOS-CHEM
(EPA emissions)
BIAS = +3%
R = 0.79
R = 0.78
Bias = +18%
Martin et al. [2002a]