TY - JOUR
T1 - The seasonal cycle amplitude of total column CO2: Factors behind the model-observation mismatch
AU - Basu, Sourish
AU - Houweling, Sander
AU - Peters, Wouter
AU - Sweeney, Colm
AU - Machida, Toshinobu
AU - Maksyutov, Shamil
AU - Patra, Prabir K.
AU - Saito, Ryu
AU - Chevallier, Frederic
AU - Niwa, Yosuke
AU - Matsueda, Hidekazu
AU - Sawa, Yousuke
PY - 2011/12/1
Y1 - 2011/12/1
N2 - CO2 surface fluxes that are statistically consistent with
surface layer measurements of CO2, when propagated forward in
time by atmospheric transport models, underestimate the seasonal cycle
amplitude of total column CO2 in the northern temperate
latitudes by 1-2 ppm. In this paper we verify the systematic nature of
this underestimation at a number of Total Carbon Column Observation
Network (TCCON) stations by comparing their measurements with a number
of transport models. In particular, at Park Falls, Wisconsin (United
States), we estimate this mismatch to be 1.4 ppm and try to attribute
portions of this mismatch to different factors affecting the total
column. We find that errors due to (1) the averaging kernel and prior
profile used in forward models, (2) water vapor in the model atmosphere,
(3) incorrect vertical transport by transport models in the free
troposphere, (4) incorrect aging of air in transport models in the
stratosphere, and (5) air mass dependence in TCCON data can explain up
to 1 ppm of this mismatch. The remaining 0.4 ppm mismatch is at the edge
of the ≤0.4 ppm accuracy requirement on satellite measurements to
improve on our current estimate of surface fluxes. Uncertainties in the
biosphere fluxes driving the transport models could explain a part of
the remaining 0.4 ppm mismatch, implying that with corrections to the
factors behind the accounted-for 1 ppm underestimation, present inverse
modeling frameworks could effectively assimilate satellite
CO2 measurements.
AB - CO2 surface fluxes that are statistically consistent with
surface layer measurements of CO2, when propagated forward in
time by atmospheric transport models, underestimate the seasonal cycle
amplitude of total column CO2 in the northern temperate
latitudes by 1-2 ppm. In this paper we verify the systematic nature of
this underestimation at a number of Total Carbon Column Observation
Network (TCCON) stations by comparing their measurements with a number
of transport models. In particular, at Park Falls, Wisconsin (United
States), we estimate this mismatch to be 1.4 ppm and try to attribute
portions of this mismatch to different factors affecting the total
column. We find that errors due to (1) the averaging kernel and prior
profile used in forward models, (2) water vapor in the model atmosphere,
(3) incorrect vertical transport by transport models in the free
troposphere, (4) incorrect aging of air in transport models in the
stratosphere, and (5) air mass dependence in TCCON data can explain up
to 1 ppm of this mismatch. The remaining 0.4 ppm mismatch is at the edge
of the ≤0.4 ppm accuracy requirement on satellite measurements to
improve on our current estimate of surface fluxes. Uncertainties in the
biosphere fluxes driving the transport models could explain a part of
the remaining 0.4 ppm mismatch, implying that with corrections to the
factors behind the accounted-for 1 ppm underestimation, present inverse
modeling frameworks could effectively assimilate satellite
CO2 measurements.
KW - CO2 sources and sinks
KW - atmospheric inverse modeling
KW - Atmospheric Composition and Structure: Constituent sources and sinks
U2 - 10.1029/2011JD016124
DO - 10.1029/2011JD016124
M3 - Article
SN - 0148-0227
VL - 116
JO - Journal of Geophysical Research
JF - Journal of Geophysical Research
IS - D23, CiteID D23306
ER -