Regional Chemistry from Global CTMs with
EC-Modeled Met-fields for the TRACE-P Mission
UC Irvine: M. J. Prather, PI, C. McLinden, B. Pak (mprather@uci.edu);
FRSGC Japan: J. Oliver Wild, co-I (oliver@frontier.esto.or.jp);
U. Oslo: J. Sundet and I. Isaksen, co-I's (j.k.sundet@geofysikk.uio.no)
Proposed Research & Scientific Goals
The IJO (Irvine-Japan-Oslo) group will enhance their existing 3-D global
chemistry-transport
models (CTM) to build a higher-resolution CTM (based on EC forecast fields)
to focus on the TRACE-P region and time frame. The goal would be to
understand how
different source regions and emission types in Asia are responsible for
primary and
secondary pollutants over the Pacific as measured in TRACE-P. Specifically,
the IJO
group will:
(1) provide a preliminary 3-D chemical climatology for the TRACE-P period and
region
based on a previous year (199x) meteorology for the purposes of mission
planning.
(when needed? when available?);
(2) provide general field-support for chemical modeling based out of FRSGC
(Frontier
Research System for Global Change), Tokyo, but no real-time forecasts;
(3) post-mission, develop CTM met-fields based on EC forecasts for the
TRACE-P
period and apply them in the IJO chemical model;
(4) determine the contributions to global tropospheric oxidant capacity (O3
and OH)
from different source regions and emissions types in the Asian outflow; and
(5) use TRACE-P observations with CTM sensitivity studies to understand how
different
source regions and emission types in Asia are responsible for primary and
secondary pollutants over the Pacific.
Direct Field Involvement
Participation in deployment is desirable, but not absolutely required. It
would focus
through FRSGC Japan. The IJO group will be able to provide some quick
turn-around
for low-resolution CTM simulations in response to questions raised in the
field
Basic Tools
The modeling will be derived from two established CTMs developed at UCI/FRSGC
and
U.Oslo. The met fields will be taken from EC forecasts at T63 (1.9
o
x 1.9
o
), 19 levels,
with 3-hourly averages. The CTM will use the same resolution, but can also
run with
reduced resolution (T42, T21) for fast turnaround.
Existing diagnostics allow detailed chemical budget calculations, including
net
production-loss over any spatial and temporal scales.
The global CTM with accurate stratospheric ozone fluxes allows identification
of
stratospheric and long-range sources during TRACE-P.