G. Caniaux et al., A NUMERICAL STUDY OF THE STRATIFORM REGION OF A FAST-MOVING SQUALL LINE .1. GENERAL DESCRIPTION AND WATER AND HEAT BUDGETS, Journal of the atmospheric sciences, 51(14), 1994, pp. 2046-2074
A two-dimensional nonhydrostatic cloud model is applied to the simulat
ion of a tropical squall line that occurred on 23 June during the COPT
81 experiment. Owing to the use of an ice parameterization scheme, th
e simulation reproduces many interesting features of the stratiform pa
rt observed with Doppler radars. In particular, this includes the dyna
mical, thermodynamical, and microphysical structures of the stratiform
part. Different parts are clearly identified from the simulation and
observations: a leading convective zone 40-km wide with large precipit
ation; a developed stratiform zone stretching over 150 km with moderat
e precipitation; between these two regions, a transition zone 20-km wi
de giving only light precipitation; and a forward anvil near 12 km. Th
e mean horizontal circulation is characterized by two mean flows: the
front-to-rear flow that represents upward and rearward injection of bo
undary-layer air and the underlying rear-to-front flow. The simulated
vertical velocity, except in the convective part, is in good agreement
with observations and is characterized by a mesoscale updraft in the
midtroposphere just behind the transition zone and a mesoscale downdra
ft under the anvil. The level of zero vertical motion, separating the
mesoscale updraft from the mesoscale downdraft, has a weak slope in th
e horizontal as observed, and stays under the 0-degrees-C isotherm eve
rywhere. One consquence is that the bright band is embedded in the mes
oscale ascent. Detailed thermodynamical and microphysical budgets of t
he stratiform region are performed and lead to the following conclusio
ns for the present simulation: 1) the warming in the poststratiform pa
rt is a consequence of the history of the storm when the subsiding low
levels were dry; 2) the cooling in the mesoscale downdraft is mainly
due to rainwater evaporation; 3) this net cooling is a temporal proces
s that occurs when the stratiform anvil produced enough precipitation
to counter the adiabatic warming; 4) the cooling at the base of the an
vil is not due to melting but is the consequence of upward transport o
f low theta. The apparent heat source and moisture sink of the whole s
ystem, as well as those of the convective and stratiform parts, are al
so presented at different times and compared with previous numerical r
esults and observations.