Download presentation
Presentation is loading. Please wait.
1
Virtual Tall Towers and Inversions or How to Make Productive Use of Continental CO 2 Measurements in Global Inversions Martha Butler The Pennsylvania State University Department of Meteorology April 24, 2007 TransCom Meeting mpbutler@met.psu.edu
2
Outline The Problem with Continental CO 2 data Virtual Tall Tower Overview Inversion Setup Perfect Data Results Continuing Work
3
Problem Definition Continental data are messy: big signal with lots of noise. Confounded by boundary layer processes (diurnal, synoptic, seasonal) Transport models have problems representing the continental boundary layer, especially near the land surface. Most continental observations are made in this surface layer. Observation site density does not permit global estimation of fluxes at the resolution we would like, unless we use continental data.
4
What About Flux Towers? CO 2 is measured continuously at every continental flux tower, but… These data are not required to be either accurate or precise to support CO 2 flux calculations. What if? Flux tower CO 2 data could be high precision and calibrated with the global standards (at reasonable cost). The data could be “adjusted” (using meteorological and flux data available at the site) to represent a mid-day CO 2 mixing ratio value above the surface layer. This adjustment adds to the uncertainty of the observation; is it worth it?
5
What Is This Adjustment? Following the mixed layer similarity theory of Wyngaard & Brost [1984] and Moeng & Wyngaard [1989], the vertical gradient of a scalar in the boundary layer: where g b and g t are bottom-up and top-down gradient functions scaled by boundary layer depth z i w * is the convective velocity scale wc 0 and wc zi are the surface and entrainment fluxes of the scalar C
6
Example Adjusted Time Series Hourly (mid- day hours) adjusted CO 2 mixing ratios for: Harvard Forest Northern Old Black Spruce WLEF Courtesy of David Tyndall See also www.amerifluxco2.psu.edu for high-precision, calibrated measurements at flux towers and www.eol.ucar.edu/~stephens/RACCOON/ for the Rocky Mountains sites.www.amerifluxco2.psu.eduwww.eol.ucar.edu/~stephens/RACCOON/
7
Inversion Setup Forward transport model: PCTM, 2.5 ° longitude x 2 ° latitude using GEOS-4 met data (3-hr) for 2000, 2001, 2002 Background fluxes: –Seasonal fossil with 1995 spatial pattern (ORNL) –SiB3 hourly flux for 2000, 2001, 2002 (CSU) –Takahashi 2002 ocean Matrix inversion in the TransCom3 style solving for monthly fluxes in 36 land regions and 11 ocean regions in 2002 Forward model sampling strategy: –Entire atmospheric column sampled hourly in 2002 at each observation location. –Ten-day means of the atmospheric grid saved for analysis.
8
Networks Tested (so far) 85 station network: NOAA GMD sites active in 2002 159 station network: NOAA GMD + GAW 145 station network: –Remove some profiles and added VTT sites active in 2002 165 station network: –Add high-precision, well-calibrated sites active after 2002 Flux tower/VTT locations Britt Stephen’s mountain sites Bev Law’s Oregon transect 2 established sites in Africa 174 station network: –Add a few other sites in under-represented regions
10
85 Station Network
11
159 Station Network
12
145 Station Network
13
165 Station Network
14
174 Station Network
15
Tests of the Inversion Setup Sensitivity to Choice of Priors & Prior Uncertainty –Priors derived from TransCom3 Seasonal Mean Inversion –At least 0 ± 2 Gt C/yr for each region –0 ± 5 Gt C/yr for each region –0 ± 10 Gt C/yr for each region –At least 0 ± 3 Gt C/yr for each land region, TransCom for ocean regions Sensitivity of Posterior Flux Uncertainty to Choice of Networks –Boreal and Temperate North America –South America –Africa
16
Global Aggregated Results Thick colored lines show posterior flux (and the prior contained in the background flux). Dashed lines show the posterior uncertainty for the aggregated area for the 85 station network. Error bars show the posterior uncertainty for the 174 station network. Note that flux scales differ for land and ocean.
17
June Posterior Flux Uncertainties Oregon transect Flux Towers
18
Boreal North America and Tropical America Fraserdale Flux Towers Tapajos
19
Examples for the African Regions Hombori Skukuza
20
Continuing Work Noisy data tests with simulated observations Model sampling to match observation times Preparation of observation data “The real deal” Daytime forward pulse runs from land regions
21
Acknowledgements People –Davis Group at Penn State –Denning Group at CSU –Randy Kawa at NASA GSFC –Everyone, everywhere in the CO 2 measurement network Funding Agencies –NASA GSRP –NOAA, DOE, NSF –PSU, College of EMS Centennial Travel Grant Comments and suggestions are welcome! And thank you!
Similar presentations
© 2024 SlidePlayer.com. Inc.
All rights reserved.