Sr. Hanna et al., EVALUATION OF PHOTOCHEMICAL GRID MODELS (UAM-IV, UAM-V, AND THE ROM UAM-IV COUPLE) USING DATA FROM THE LAKE MICHIGAN OZONE STUDY (LMOS)/, Atmospheric environment, 30(19), 1996, pp. 3265-3279
Data from two ozone episodes from the 1991 Lake Michigan Ozone Study (
LMOS) have been used to evaluate two commonly used photochemical grid
models-UAM-IV and UAM-V. To assure a fair comparison, the models were
run on the same domain and grid size, with the same inputs of source e
missions, diagnostic meteorology, and initial and boundary conditions.
In addition, UAM-V was run in nested-grid mode with input meteorology
taken from a prognostic model (CALRAMS), and UAM-IV was run in regula
tory mode with boundary conditions taken from ROM. Little difference w
as found between the UAM-IV and UAM-V daily peak ozone predictions, wh
ich showed mean relative biases of +/- 5 to 10%. The use of diagnostic
vs prognostic meteorological model inputs had little effect on UAM-V
performance statistics, although the spatial location of the broad reg
ional ozone plume was better with the prognostic meteorological model.
The ROM/UAM-IV couple tended to consistently underpredict peak ozone
by about 20%, primarily due to ROM underpredictions of ozone on the up
wind domain boundaries. It was found that all models tended to underpr
edict ozone precursors (VOCs and NOx) by as much as a Factor of two, a
lthough the UAM-V underpredictions were not as large. Furthermore, all
models consistently underpredicted ozone and precursors at large dist
ances (200-500 km) from the source regions, where relatively high ozon
e concentrations (150-180 pb) were sometimes observed. The relative re
sponses of the models to 50% reductions in anthropogenic VOC and NOx e
missions were also evaluated. The directions and magnitudes of the pre
dicted ozone changes were roughly consistent for the models. The best
agreement occurred for the 50% anthropogenic VOC emissions reductions,
where all models predicted about a 15% decrease in peak ozone concent
rations. When a 50% anthropogenic NOx emissions reduction was imposed,
UAM-IV and UAM-V/CALRAMS predicted about a 3 or 4% increase in peak o
zone concentration and UAM-V/CALMET and the ROM/UAM-IV couple predicte
d about a 5-20% increase in peak ozone. Copyright (C) 1996 Elsevier Sc
ience Ltd