GLOBAL BUDGET OF ATMOSPHERIC ACETONE
ATMOSPHERIC OBSERVATIONS OF ACETONE (0.2-3 ppbv)
OCEANIC SIGNATURE IN ATMOSPHERIC ACETONE OBSERVATIONS?
ROLE OF OCEAN IN ATMOSPHERIC BUDGET OF ACETONE
INVERSE MODEL ANALYSIS OF ACETONE BUDGET
CONSTRUCTING THE A PRIORI: SIMULATION OF C3-5 ISOALKANES TO IMPROVE CONSTRAINT ON EMISSIONS
CONTRIBUTION OF DIFFERENT SOURCES TO A PRIORI BUDGET OF ACETONE (symbols: observations lines: model)
FITTING OF OCEAN SATURATION RATIO R TO MINIMIZE MODEL vs. OBSERVED CHI-SQUARE IN A POSTERIORI OPTIMIZED SOURCES
OPTIMIZED GLOBAL 3-D MODEL SIMULATION OF ATMOSPHERIC ACETONE
SURFACE AIR ACETONE CONCENTRATIONS IN OPTIMIZED SIMULATION
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Global budget of atmospheric acetone

1. GLOBAL BUDGET OF ATMOSPHERIC ACETONE

Singh et al.
[2000]
SOURCES (Tg yr-1)
56 (37-80)
Terrestrial vegetation
15 (10-20)
Plant decay
6 (4-8)
Biomass burning
5 (3-10)
Industry
2 (1-3)
Oceans
0
Oxidation of isoalkanes
17 (12-24)
Oxidation of terpenes, MBO 11 (7-15)
SINKS (Tg yr-1)
Photolysis
Oxidation by OH
Deposition to land
Uptake by ocean
LIFETIME
56 (37-80)
36 (24-51)
13 (9-19)
7 (4-10)
0
16 days
This work
(a priori)
78 (49-105)
26 (0-52)
9 (0-18)
3 (2-5)
1 (1-2)
10 (0-20)
20 (10-30)
9 (3-15)
78
44
25
9
0
20 days
This work
(optimized)
95 (80-110)
33 (24-42)
2 (-3-7)
5 (3-7)
1 (1-2)
27 (21-33)
21 (16-26)
7 (3-11)
95
46
27
9
14
15 days

2. ATMOSPHERIC OBSERVATIONS OF ACETONE (0.2-3 ppbv)

ABLE
-3B
SONEX
PEM-TB
TRACE-A
Surface sites
PEM
-WB

3. OCEANIC SIGNATURE IN ATMOSPHERIC ACETONE OBSERVATIONS?

South Pacific
[Singh et al., 2001]
southern Sweden
[Solberg et al., 1996]
Low winter values
over Europe:
ocean sink?
High values over
South Pacific:
ocean source?

4. ROLE OF OCEAN IN ATMOSPHERIC BUDGET OF ACETONE

SOURCE?
SINK?
H298 = 30 M atm-1;
physical uptake limited
by both gas- and
aqueous-phase transfer
Zhou and
Mopper (1997)
hn
Organic microlayer
Biological uptake
(Kieber et al., 1990)
organic microlayer
Model sink as adjustable
saturation ratio R
Model source as proportional
To UV-B flux

5. INVERSE MODEL ANALYSIS OF ACETONE BUDGET

Global 3-D model (“forward model”):
defines sensitivity of atmospheric concentrations
to global sources/sinks (“state vector”)
A priori best estimate
of sources/sinks
(with errors)
Observed atmospheric
concentrations
(with “errors”)
A posteriori optimized estimate
of sources/sinks

6. CONSTRUCTING THE A PRIORI: SIMULATION OF C3-5 ISOALKANES TO IMPROVE CONSTRAINT ON EMISSIONS

observed
model
(EDGAR)
model
(Piccot+)
Global propane source of 12 Tg C yr-1, mainly natural gas

7. CONTRIBUTION OF DIFFERENT SOURCES TO A PRIORI BUDGET OF ACETONE (symbols: observations lines: model)

8. FITTING OF OCEAN SATURATION RATIO R TO MINIMIZE MODEL vs. OBSERVED CHI-SQUARE IN A POSTERIORI OPTIMIZED SOURCES

Best fit for
R = 0.7-0.85

9. OPTIMIZED GLOBAL 3-D MODEL SIMULATION OF ATMOSPHERIC ACETONE

a priori sources/sinks; c2 = 1.3
Optimized sources/sinks
(including “microbial” ocean sink,
photochemical ocean source); c2 = 0.39

10. SURFACE AIR ACETONE CONCENTRATIONS IN OPTIMIZED SIMULATION

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