Autonomous "OBuoy" observations of the Arctic atmosphere William Simpson, University of Alaska Fairbanks, wrsimpson@alaska.edu Paty Matrai, Bigelow Laboratory for Ocean Sciences Francisco Chavez, Monterey Bay Aquarium Research Institute Paul Shepson, Purdue University, Donald Perovich, Cold Regions Research and Engineering Laboratory, Peter Peterson, University of Michigan, John Halfacre, Purdue University, The Obuoy Team 1
Sea Ice + O-Buoy CO2 Exchange Oxidation Inversions Findings Future Sea ice is changing Summer sea ice is declining. Winter sea ice is getting younger, saltier, more leads. How does this affect the air? 17-19 Nov 2015 From NSIDC Arctic Sea Ice data. http://nsidc.org AOOSM Seattle, WA 2
O-Buoy sentinel species CO 2 Greenhouse gas, ocean exchange O 3 Indicates oxidation capacity BrO Modifies oxidation capacity Meteorology and Time-lapse images 17-19 Nov 2015 AOOSM Seattle, WA 3
O-Buoy data covers the Arctic Ocean Data available at http://www.aoncadis.org 17-19 Nov 2015 AOOSM Seattle, WA 4
O-Buoys sense CO 2 exchange CO 2 is transported into and out of the Arctic and can exchange with the Arctic Ocean, possibly moderated by sea ice. 17-19 Nov 2015 AOOSM Seattle, WA 5
CO 2 observations (Matrai / Chavez) These observations help us understand Airocean exchange and its moderation by sea ice. See talk by Paty Matrai in Robust Autonomous Arctic Observations (Wed 3:00 PM) 17-19 Nov 2015 AOOSM Seattle, WA 6
Oxidation capacity...... is the ability of the atmosphere to clean itself by chemically oxidizing pollutants.... globally controls methane lifetime.... produces new particles.... makes existing particles better CCN. O 3 photochemistry produces OH radicals, the primary global oxidizer, thus O 3 typically indicates oxidation capacity. 17-19 Nov 2015 AOOSM Seattle, WA 7
Models fail for O 3 2008 annual O 3 cycle, observational error bars are 1σ We do not understand or cannot model O 3 in the Arctic, esp. Spring + Summer. This impacts our understanding of Arctic oxidation capacity. From Monks et al. (2015) Atmos. Chem. Phys., 15, 3575, doi:10.5194/acp-15-3575-2015 17-19 Nov 2015 AOOSM Seattle, WA 8
O-Buoys observe surface O 3 Spring (March May) O 3 is episodically depleted. See poster by John Wes Halfacre in Arctic Atmosphere I 17-19 Nov 2015 AOOSM Seattle, WA 9
Springtime Artic Chemistry Photochemistry on snow and aerosol releases reactive halogens detected here as BrO (bromine monoxide) Reactive halogens destroy O 3 and alter oxidation capacity BrO animation from Andreas Richter, IUP Bremen, Germany 17-19 Nov 2015 AOOSM Seattle, WA 10
O-Buoy BrO observations UV-Vis Spectrometer in O-Buoy measures scattered light Tangent geometry isolates lower troposphere and measures BrO in lowest 200m and 2000m 17-19 Nov 2015 AOOSM Seattle, WA 11
Inversions control BrO profile Shallow 60 50 Event Type Spectrum VCD 200 /LT VCD 40 30 20 Distributed 10 10 to 4 4 to 8 >8 Neutral dt/dz Stable = Inversion From Peterson et al. (2015) Atmos. Chem. Phys., 15, 2119, doi:10.5194/acp-15-2119-2015 17-19 Nov 2015 AOOSM Seattle, WA 12
High BrO column events are mixed 80 x 10 12 10 Shallow 70 9 8 60 Event Type Spectrum VCD 200 /LT VCD 50 40 30 20 7 6 5 4 3 2 VCD 200m (molecules/cm 2 ) Distributed 10 0 0 1 2 3 4 5 6 7 8 LT VCD (molecules/cm 2 ) High column events are distributed, while shallower events have less total BrO column. 17-19 Nov 2015 AOOSM Seattle, WA 13 x 10 13 1 0
O-Buoys also sense oxidizers During springtime, photochemistry releases reactive bromine from sea ice, which depletes O 3. After snowmelt, halogens are gone and O 3 now controls oxidation capacity. 17-19 Nov 2015 AOOSM Seattle, WA 14
O-Buoy initial findings O-Buoys provide a rich data set that observes air over Arctic sea ice. Vertical exchange effects are critical to understand. We welcome collaboration to understand these data and their impacts. How might halogens and oxidation affect other parts of the Arctic climate system? 17-19 Nov 2015 AOOSM Seattle, WA 15
Iodine in new particle production Allan and co-workers observed new particle production events in the Arctic and found iodine (another halogen) in the particles. From Allan et al. (2015), Atmos. Chem. Phys., 15, 5599, doi:10.5194/acp-15-5599-2015 17-19 Nov 2015 AOOSM Seattle, WA 16
Oxidation modifies particles Jimenez and co-workers found that oxidation, which increases O:C ratio, made organic matter more hydrophyllic, which would make it better CCN From Jimenez et al. (2009), Science, 326, 1525, doi:10.1126/science.1180353 17-19 Nov 2015 AOOSM Seattle, WA 17
Future work Analysis of O-Buoy data can improve understanding of how changing ice affects the atmosphere. Oxidation may affect CCN and clouds needs future study We look forward to working on these problems We acknowledge funding from NSF AON under grants to our five institutions: ARC-1022834, ARC-1022773, ARC-1023221, ARC-1023393, and ARC-1023118 17-19 Nov 2015 AOOSM Seattle, WA 18