1 motivation 2 instrumentation and retrieval 3 contrast profile comparison stratospheric case study...
TRANSCRIPT
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1 Motivation2 Instrumentation and Retrieval3 CONTRAST• Profile Comparison• Stratospheric case study4 TORERO • NH/SH gradients5 Summary and conclusions
Iodine Oxide observations from CU AMAX-DOAS aboard the NSF NCAR GV
KA-12-01
Theodore Koenig, Sunil Baidar, Barbara Dix, Rainer VolkamerDepartment of Chemistry and Biochemistry & CIRES
University of Colorado
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1 Motivation
• Why do we need to know about IO?– IO modifies the atmosphere’s oxidative capacity– IO catalytically destroys ozone– IO may impact the creation and growth of aerosol particles
• What don’t we know about IO?– Source chemistry and atmospheric lifetime
• Organic biological/photochemical vs inorganic sources• Multiphase chemistry in aerosols• Aerosol loss vs Aerosol recycling
– Vertical and global distribution– Only upper limits are known in the lower stratosphere– The magnitude of its importance for atmospheric chemistry and
climate
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1 Motivation – Uncertainty in stratospheric IO MR
IO mixing ratios in the lower stratosphere are low.
Current knowledge of IO in the stratosphere is limited mostly to upper limits.
Previous measurements are limited to Direct Sun DOAS gathering most or all information at high Solar Zenith Angle (sunrise and sunset)
Authors Year Method Lower Stratospheric (12-15km) IO Mixing Ratio
Wennberg et al. 1997 Ground DOAS (Direct Sun) 0.2 ppt (0-0.3ppt)
Pundt et al. 1998 Balloon DOAS (Direct Sun) <0.1 ppt
Butz et al. 2006 Balloon DOAS (Direct Sun) <0.1 ppt
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1 Motivation – IO over the PacificSchönhardt et al., ACP 2008
® CONTRAST study area is expected to be an IO minimum
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2 Instrumentation - CU AMAX-DOAS
Colorado University-Airborne Multi-AXis Differential Optical Absorption Spectroscopy
Sun
elevation angle
height
concentration
solar zenith angle
spectrographs/detectors
Volkamer et al., 2009, SPIECoburn et al., 2011, AMTBaidar et al., 2013, AMTDix et al., 2013, PNAS
telescope pylon
motionstabilized
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Measured signal below detection
2 DOAS detection of IO
A strong signal from RF15A weaker but still clear signalNear Single point detectionZero Signal
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3 CONTRAST – RF15 Parameterization derived Profile
Parameterization is faster than inversion but has larger errors
Higher and lower altitudes are irretrievable due to cloud effects
Free Troposphere shows background of ~0.2 ppt IO
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3 CONTRAST – Comparison with TORERO
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3 CONTRAST – Overview of Data Retrieval
Cloud conditions are good entering and exiting the stratosphere, but require assessment by sensitivity studies in stratosphere
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3 CONTRAST – Cloud Sensitivity
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3 CONTRAST – Comparison with CamCHEM
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3 CONTRAST – RF15 Jet Crossing
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Conclusions & Outlook
• IO is detected and quantified in the LS- First detection of IO in the stratosphere by limb
measurements- AMAX measurements qualitatively match models but
show more IO overall in the LS (up to a factor 2)- A more direct comparison with model requires design of an instrument mask
• FT-IO in the NH over the Western Pacific is similar to the levels that had been observed in the SH over the Eastern Pacific (TORERO)
• Understanding Stratospheric IO:- Further collaboration with CamCHEM team
• Process Level Understanding:- Use TORERO and CONTRAST observations of IO, organoiodine, and aerosols to better constrain iodine chemistry (WRF-Chem, GEOS-Chem)
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- NCAR/EOL staff for support during HEFT-10, TORERO and CONTRAST- Volkamer group for campaign participation/support - The CONTRAST Team for acquiring and sharing data- T. Deutschmann for providing the McArtim radiative transfer code
- NSF-sponsored Lower Atmospheric Observing Facilities, managed and operated by NCAR-EOL
- TORERO (Tropical Ocean tRoposphere Exchange of Reactive halogen species and Oxygenated VOC) is funded by NSF award AGS-1104104 (PI: R. Volkamer)
- CONTRAST (CONvective TRansport of Active Species in the Tropics) is funded by NSF award AGS-1261740
Thank You!
Acknowledgements:
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Thank you for your attention