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1.
Summary The present paper is the continuation of two recent studies investigating the foehn-like valley wind system around Mittenwald
(Bavarian Isar Valley). We deal with the synoptic/mesoscale conditions causing the local foehn (“Minifoehn”), considering
field campaigns from both the mesoscale and the climatological point of view. Furthermore, we describe the structure and further
features of the local foehn at smaller scales, using both the results of the VERTIKATOR field campaign and numerical simulations.
We obtain as a new result that the foehn-caused local warm air pool around Mittenwald induces slight nocturnal upvalley winds
between an adjacent valley basin located some 8 km north of Mittenwald and the basin of Mittenwald. Furthermore, a weak northerly
flow may also occur at Mittenwald prior to the onset of the Minifoehn. Numerical simulations indicate that the local pressure
gradient responsible for this phenomenon is related to a gravity wave forming over the hill range southwest of Mittenwald.
Observations within a five-year period indicate that Minifoehn frequently occurs when ambient winds coming from the southern
sector are predominant, but, contrary to deep foehn, weather conditions with northerly synoptic-scale flows do not necessarily
exclude the development of the local foehn which comes from the southwest. We also present further evidence that in the presence
of southerly synoptic-scale winds, orographic gravity waves interact with the drainage flow. Another new result is that strong
synoptic-scale westerly winds are able to suppress the occurrence of Minifoehn. In addition, the possible influence of the
Inn Valley wind system as well as dynamical differences between the thermally driven up- and downvalley winds are briefly
discussed. 相似文献
2.
Matthias Hornsteiner 《Meteorology and Atmospheric Physics》2005,88(3-4):175-192
Summary An unusually strong nocturnal downvalley wind can be regularly observed in the upper Isar Valley close to Mittenwald (Bavarian Alps) when a high-pressure system is located over Central Europe or when ambient southerly winds are present. Due to the structure of the local topography, this downvalley wind has foehn-like properties in the sense that the breakthrough of the flow into the valley is characterized by a strong increase in temperature and a decrease in relative humidity. Therefore the author called this flow Minifoehn. In fact, wind speeds are low in comparison to deep foehn, but gusts may reach values up to 20ms–1, even under the influence of high pressure systems with weak atmospheric pressure gradients. To investigate the Minifoehn, surface stations have been installed for collecting temperature, humidity, wind and pressure data. Measurements have shown that the Minifoehn represents the upper part of one of the drainage currents which flows over a mountain ridge into the valley at Mittenwald. Nocturnally cooled air drains from a plateau south of Mittenwald through different valleys which merge again near Mittenwald. It seems that the forcing of the nocturnal currents is dominated by the temperature difference between this plateau and the free atmosphere above Mittenwald at the same level. Strong temperature differences are found during clear winter nights and in case of subsidence inversions. Moreover, the appearance of the Minifoehn in autumn and winter is so frequent that we even may find a climatic effect: the upper Isar Valley is usually free of fog during these seasons and nocturnal temperatures are often considerably higher than in other Bavarian Alpine valleys at comparable altitude. 相似文献
3.
G. Zängl 《Meteorology and Atmospheric Physics》2006,91(1-4):85-105
Summary This study presents high-resolution numerical simulations of north foehn in the Austrian Inn Valley which have been performed
with the Penn State/NCAR mesoscale model MM5. As the Inn Valley is located north of the Alpine crest, north foehn occurs comparatively
rarely in this valley, and there are only sparse observations available for this phenomenon. Simulations of the 24 January
1993 case as well as idealized simulations are performed to get a deeper insight into the dynamics of the north foehn. Moreover,
the synoptic conditions leading to the occurrence of north foehn in the Inn Valley are investigated.
The simulations indicate that there are at least four different paths for the foehn to penetrate into the valley. Two of them
are running along side valleys entering the upper Inn Valley from the west. These flow paths appear to be most important when
the large-scale flow has a significant westerly component. The other possible flow paths enter the Inn Valley from the northwest
or north and require a strong northerly component of the large-scale flow. From a dynamical point of view, north foehn appears
to be similar to the well researched south foehn in that vertically propagating gravity waves force the descent of the ambient
flow into the valleys. However, there are also indications that trapped lee waves have a significant impact on the surface
wind field, which has not been reported for south foehn so far. Moreover, the model results show that a precondition for the
formation of north foehn in the Inn Valley is the absence of significant orographic precipitation. Evaporative cooling induced
by precipitation falling into subsaturated air not only reduces the surface temperatures but also inhibits the formation of
large-amplitude gravity waves, suppressing the development of stormy surface winds. 相似文献
4.
Summary In this paper, very-high-resolution numerical simulations are presented to analyze the small-scale dynamics of the foehn in
the lower Wipp Valley and the adjacent parts of the Inn Valley. This region was one of the target areas for foehn observations
during the Mesoscale Alpine Programme (MAP). Our simulations consider two MAP cases that markedly differed in the depth of
the foehn flow. To isolate the dynamical effect of the key orographic features in the Wipp Valley region, we performed sensitivity
experiments with different topography modifications. These involve lowering or even removing the Nordkette range, which constitutes
the northern side wall of the east–west-oriented Inn Valley, and closing the Stubai Valley, which is the northernmost and
largest tributary of the Wipp Valley. A comparison with surface and lidar observations indicates that our present model resolution
of 467 m significantly improves the realism of the simulations compared to a resolution of 800 m, as used in a previous study.
The Nordkette is found to have a twofold impact on the dynamics of foehn breakthrough into the Inn Valley. In reality, this
mountain chain deflects part of the southerly foehn current coming from the Wipp Valley into the perpendicularly oriented
Inn Valley. Our sensitivity tests indicate that this flow deflection tends to accelerate the foehn breakthrough into the Inn
Valley, while upstream blocking effects induced by the Nordkette act to slow down the process of foehn breakthrough. The flow
pattern in the Wipp Valley reveals that the upstream effects of the Nordkette are not quite far-reaching. The amplitude of
the gravity waves over the lower Wipp Valley gets somewhat reduced by these upstream effects, but the overall flow pattern
remains largely unaffected. Closing the Stubai Valley also has a minor effect of the wave structure and tends to reduce the
cross-valley variability of the foehn flow in the lower Wipp Valley. 相似文献
5.
Summary Numerical simulations of the 24 October 1999 south foehn (MAP-IOP 10) are performed with the Penn State/NCAR mesoscale model MM5 for the Wipp Valley and the adjacent parts of the Inn Valley. The model is run in a multiple-nest configuration, the area of interest being resolved at a mesh size of 800m in most experiments. The study serves to complement an earlier work in which typical flow features of the foehn in the Wipp Valley region were investigated by means of idealized simulations, assessing whether it is possible to reproduce the temporal evolution and the spatial structure of a particular foehn case. A further objective of the paper is to examine the dependence of the model performance on the horizontal resolution, giving some information which resolution will probably be needed for future high-resolution forecasts.An encouragingly large part of the observed flow features could be well reproduced in the simulations. Except for a small region to the east of Innsbruck, the foehn breakthrough is predicted correctly to within an hour. The spatial structure of the so-called pre-foehn, an enhanced westerly wind occurring at Innsbruck prior to the breakthrough of the foehn, also agrees very well with the observations. Moreover, the maximum extent of the foehn in the Inn Valley, the structure of the gravity wave field above the Wipp Valley and the upvalley progression of a shallow cold front in the evening are consistent with the observations. Except for a few places where the airmass boundary between the warm foehn air and the adjacent colder air is not captured correctly throughout the time, the simulated surface temperatures range within 2K of the observed values. Discrepancies between the model results and the observations are found in the vicinity of Innsbruck where a flow-splitting phenomenon induces a very complex flow pattern at low levels. Another source of problems is the surface potential temperature along the Wipp Valley. The observed potential-temperature increase between the Brenner Pass and Innsbruck, which appears to be related to turbulent vertical mixing of stably stratified air, is underestimated by the model. Reducing the horizontal resolution from 800m to 1.4km deteriorates the model performance in marginally resolved side valleys, but the results obtained for the Wipp Valley and the Inn Valley are still of high quality. 相似文献
6.
G. Zängl 《Meteorology and Atmospheric Physics》2003,83(3-4):237-261
Summary ?Numerical simulations of the south foehn in the region of Innsbruck are presented. They are semi-idealized in the sense that
realistic orography but idealized initial and boundary conditions are used. The focus of this study is on typical features
of the fully developed foehn, the breakthrough phase of the foehn and the diurnal cycle of the foehn. In addition, the impact
of the large-scale wind direction is examined, including conditions leading to shallow foehn.
The simulated flow fields have been found to be in very good agreement with observations except for a few minor details. In
the lower part of the Sill Valley (the valley going from the Brenner pass down to Innsbruck), the wind speed is significantly
higher than in the upper part. The acceleration can be traced back to the three-dimensional propagation of gravity waves excited
over the adjacent mountain ridges. The amplitude of the gravity waves over the various mountain ridges depends sensitively
on the wind direction, large wave amplitudes occurring only when the angle between the wind direction and the ridge line is
not too small. For southwesterly or south–southwesterly large-scale flow, wave amplitudes are significantly larger to the
east of Innsbruck than to the west. Foehn breakthrough at Innsbruck is usually preceded by a moderate westerly (downvalley)
wind that is restricted to a rather small area around Innsbruck. The simulations reveal that this so-called pre-foehn is mainly
a consequence of the gravity wave asymmetry, producing an asymmetric pressure perturbation with lower pressure to the east
of Innsbruck. Shallow foehn, defined as a foehn occurring when the large-scale flow at crest height (700 hPa) is approximately
westerly, is associated with relatively weak wave activity along the Sill Valley. It is found that at least a weak southerly
wind component below crest height is necessary to maintain a significant shallow foehn over a longer time.
Received October 10, 2001; accepted June 20, 2002
Published online: February 20, 2003 相似文献
7.
Dr. P. Seibert 《Meteorology and Atmospheric Physics》1990,43(1-4):91-103
Summary After the ALPEX Special Observing Period in 1982, further field measurement campaigns have been carried out to study the south foehn in the Eastern Alps. In addition, foehn situations were investigated statistically on the basis of a 4-years-record of upper-air and synoptic data combined with data from a special regional network. In this paper, distribution of air masses around the Alps, flow patterns and the typical evolution of a foehn situation are illustrated by the case 8 November 1982. Several possible definitions of shallow foehn are given, yielding a share of approximately 10% of shallow foehn observations. Mainly statistical data are used to falsify the wide-spread version of the thermodynamical foehn theory attributing the warmth of the foehn to release of latent heat and postulating foehn air rising from the ground of the Po Valley. Instead of this, the foehn air originates from 2000–2500 m asl over the Po Valley, while the air near ground remains blocked. The potential temperature difference between southern and northern valleys during foehn is to be explained by the stable stratification in the south, not by the effects of precipitation. These findings are in agreement with Hann's original theory.With 10 Figures 相似文献
8.
Analysis of the wind field and heat budget in an alpine lake basin during summertime fair weather conditions 总被引:2,自引:0,他引:2
M. Kossmann A. P. Sturman P. Zawar-Reza H. A. McGowan A. J. Oliphant I. F. Owens R. A. Spronken-Smith 《Meteorology and Atmospheric Physics》2002,81(1-2):27-52
Summary ?Observational data collected in the Lake Tekapo hydro catchment of the Southern Alps in New Zealand are used to analyse the
wind and temperature fields in the alpine lake basin during summertime fair weather conditions. Measurements from surface
stations, pilot balloon and tethersonde soundings, Doppler sodar and an instrumented light aircraft provide evidence of multi-scale
interacting wind systems, ranging from microscale slope winds to mesoscale coast-to-basin flows. Thermal forcing of the winds
occurred due to differential heating as a consequence of orography and heterogeneous surface features, which is quantified
by heat budget and pressure field analysis.
The daytime vertical temperature structure was characterised by distinct layering. Features of particular interest are the
formation of thermal internal boundary layers due to the lake-land discontinuity and the development of elevated mixed layers.
The latter were generated by advective heating from the basin and valley sidewalls by slope winds and by a superimposed valley
wind blowing from the basin over Lake Tekapo and up the tributary Godley Valley.
Daytime heating in the basin and its tributary valleys caused the development of a strong horizontal temperature gradient
between the basin atmosphere and that over the surrounding landscape, and hence the development of a mesoscale heat low over
the basin. After noon, air from outside the basin started flowing over mountain saddles into the basin causing cooling in
the lowest layers, whereas at ridge top height the horizontal air temperature gradient between inside and outside the basin
continued to increase.
In the early evening, a more massive intrusion of cold air caused rapid cooling and a transition to a rather uniform slightly
stable stratification up to about 2000 m agl. The onset time of this rapid cooling varied about 1–2 h between observation
sites and was probably triggered by the decay of up-slope winds inside the basin, which previously countered the intrusion
of air over the surrounding ridges. The intrusion of air from outside the basin continued until about mid-night, when a northerly
mountain wind from the Godley Valley became dominant. The results illustrate the extreme complexity that can be caused by
the operation of thermal forcing processes at a wide range of spatial scales.
Received June 25, 2001; Revised December 21, 2001 相似文献
9.
The so called Upper Río Negro Valley in Argentina is one of the most important fruit and vegetable production regions of the country. It comprises the lower valleys of the Limay and Neuquén rivers and the upper Negro river valley. Out of the 41,671 cultivated hectares, 84.6% are cultivated with fruit trees, especially apple, pear and stone fruit trees. Late frosts occurring when trees are sensitive to low temperatures have a significant impact on the regional production. This study presents an analysis of air flow characteristics in the Upper Río Negro Valley and its relationship with ambient air flow. To such effect, observations made when synoptic-scale weather patterns were favorable for radiative frosts (light wind and clear sky) or nocturnal temperature inversion in the lower layer were used. In the Negro river valley, both wind channeling and downward horizontal momentum transport from ambient wind were observed; in nighttime, very light wind events occurred, possibly associated with drainage winds from the nearby higher levels of the barda. In the Neuquén river valley, the prevailing effect appeared to be forced channeling, consistent with the results obtained in valleys where the synoptic scale wind crossed the axis of the valley. In the Limay river valley, the flow was observed to blow parallel to the longitudinal valley axis, possibly influenced by pressure gradient and forced channeling. 相似文献
10.
While nocturnal offshore precipitation, which produces rain cells and bands, has been studied in tropical areas, few studies have analyzed the occurrence of this phenomenon at higher latitudes. Using radar reflectivity, nocturnal rainfall in the western Mediterranean area has been detected near the coast of the Iberian Peninsula and North Africa. More than 50 events have been recorded since 2009. MM5 mesoscale simulations of some of the recorded events allow us to establish that the most likely causes for these precipitation events are: (1) the interaction between cold air masses conducted by drainage and katabatic winds, and (2) a wetter and warmer synoptic wind. Two different episodes are presented: one in the northeastern Iberian Peninsula, caused by stratiform clouds, which occurred at the mouths of three rivers; the other case, produced by convective clouds, occurred at the southern Iberian Peninsula and was caused by the drainage winds flowing down from some mountain ranges located close to the coast. 相似文献
11.
Measured and derived meteorological parameters are used to examine the changes in air mass associated with local winds of differing origin. Research conducted explores the usefulness of wet bulb potential temperature, equivalent potential temperature, virtual potential temperature and relative humidity as indicators of air mass change during sea breeze, foehn wind and nocturnal drainage flow events. The complex interactions between these different topographically-induced wind systems in South Canterbury, New Zealand, provide an environment in which marked changes in air mass characteristics are common. Results demonstrate that under a considerable range of boundary-layer conditions, measured wet bulb potential temperature when used in conjunction with windspeed and direction enables quick and accurate determination of air mass origin. Relative humidity was also found to respond closely to changes in local air mass type, but its dependence on air temperature makes it a less reliable indicator. 相似文献
12.
E. Mursch-Radlgruber 《Theoretical and Applied Climatology》1995,52(1-2):3-17
Summary Features of the mean flow structure in a small valley system in the Rosalian mountain range are discussed using data from a wind measurement network. Tethered balloon measurements during periods of clear sky form the basic dataset for the analysis of drainage winds and temperature inversions. During periods of weak ambient winds the existence of a pure thermally driven nocturnal valley wind system is shown. With strong ambient winds opposing the drainage flow, a reduced drainage height but the same jet maximum as with weak ambient winds is found. On the other hand with aiding flow the drainage winds are suppressed and flow reversal can occur. This strong valley flow interaction with the ambient wind indicates considerable dynamic influence on the evolution of drainage winds and on the breakup of temperature inversion structure for small valleys.With 15 Figures 相似文献
13.
Philippe Philippe Alain M. Dabas Christian Haeberli Pierre H. Flamant 《Boundary-Layer Meteorology》2003,106(3):483-505
The flow structure at the intersection between the Rhine and the Seez valleys nearthe Swiss city of Bad Ragaz has been documented by means of wind and pressuremeasurements collected from 9 September to 10 November 1999 during the MesoscaleAlpine Programme (MAP) experiment. To understand better the dynamics of theageostrophic winds that develop in this part of the Rhine valley, some key questionsare answered in this paper including the following: (i) How does air blow at theintersection of the Rhine and Seez valleys? and (ii) what are the dynamical processes(mechanical or thermal) driving the flow circulations in the valleys? Statistical analysis of the wind and pressure patterns at synoptic scale and at the scaleof the valley shows that five main flow patterns, SE/S, NW/W, NW/N, NW/S, SE/N(wind direction in the Seez valley/wind direction in the Rhine valley) prevail. The SE/S regime is the flow splitting situation. It is mainly driven by a strong pressure gradient across the Alps leading to foehn, even though some nocturnal cases are generated bylocal thermal gradients. The NW/W and NW/N regimes are mechanically forced bythe synoptic pressure gradient (as the flow splitting case). The difference between thetwo regimes is due to the synoptic flow direction [westerly (northerly) synoptic flowfor the NW/W (NW/N) regime], showing that the Rhine valley (particularly from BadRagaz to Lake Constance) is less efficient in channelling the flow than the Seez valley.The NW/S (occurring mainly during nighttime) and SE/N (occurring mainly duringdaytime) regimes are mainly katabatic flows. However, the SE/N regime is also partlyforced at the synoptic scale during the foehn case that occurred between 18 October and 20 October 1999, with a complex layered vertical structure. This analysis also shows that, contrary to what was observed in a broad section of theupper Rhine valley near Mannheim, very few countercurrents were observed near BadRagaz where the valley width is much smaller. 相似文献
14.
Summary This study examines the exceptional Alpine south foehn event of 14–16 November 2002 using routine observations and high-resolution
numerical simulations. Besides its long duration and an extremely high temperature level related to warm-air advection from
the northern Sahara, this foehn event exhibited an unusual spatial structure of the low-level wind and temperature field.
Whereas the foehn was largely restricted to the first half of 14 November in the western part of the Alps (Switzerland), it
extended over the full period in the inner-Alpine valleys in the eastern Alps. The duration and intensity of the foehn also
tended to decrease from the Alpine crest towards the northern rim of the Alps. Most surprisingly, continuous foehn even occurred
on the windward side of the Alpine crest, namely in a basin located in the southeastern Alps. The distribution of the orographic
precipitation associated with the foehn case was unusual as well. In Switzerland, intense precipitation was not restricted
to the windward (southern) side of the Alps but extended to the northern side of the Alpine crest, particularly on 16 November.
The results indicate that the spatio-temporal distribution of the foehn in the northern Alps was related to the fact that
the western Alps were within a synoptic-scale transition zone between extremely warm air advected from the south and colder
air lying over western Europe. The colder air was advected around the western Alps whereas extremely warm air descended from
the Alpine crest farther east. Moreover, a small cyclone formed on 14 November north of the Alps and generated a shallow cold
front propagating eastward along the northern Alps. Thus, the tendency towards foehn decreased from west to east and from
the Alpine crest towards the north. The occurrence of foehn on the windward side of the Alpine crest was made possible by
the extreme strength of the large-scale southerly flow, combined with the fact that the upstream precipitation field did not
reach the southeastern edge of the Alps. Finally, the pronounced spillover of precipitation to the northern side in the Swiss
part of the Alps appears to be related to the colder air present north of the crest. This prevented the formation of orographic
gravity waves and downslope air motion, which usually leads to a rapid evaporation of the precipitation on the lee side of
the Alpine crest. 相似文献
15.
The impact of the PBL scheme and the vertical distribution of model layers on simulations of Alpine foehn 总被引:1,自引:0,他引:1
Summary This paper investigates the influence of the planetary boundary-layer (PBL) parameterization and the vertical distribution
of model layers on simulations of an Alpine foehn case that was observed during the Mesoscale Alpine Programme (MAP) in autumn
1999. The study is based on the PSU/NCAR MM5 modelling system and combines five different PBL schemes with three model layer
settings, which mainly differ in the height above ground of the lowest model level (z
1). Specifically, z
1 takes values of about 7 m, 22 m and 36 m, and the experiments with z
1 = 7 m are set up such that the second model level is located at z = 36 m. To assess if the different model setups have a systematic impact on the model performance, the simulation results
are compared against wind lidar, radiosonde and surface measurements gathered along the Austrian Wipp Valley. Moreover, the
dependence of the simulated wind and temperature fields at a given height (36 m above ground) on z
1 is examined for several different regions.
Our validation results show that at least over the Wipp Valley, the dependence of the model skill on z
1 tends to be larger and more systematic than the impact of the PBL scheme. The agreement of the simulated wind field with
observations tends to benefit from moving the lowest model layer closer to the ground, which appears to be related to the
dependence of lee-side flow separation on z
1. However, the simulated 2 m-temperatures are closest to observations for the intermediate z
1 of 22 m. This is mainly related to the fact that the simulated low-level temperatures decrease systematically with decreasing
z
1 for all PBL schemes, turning a positive bias at z
1 = 36 m into a negative bias at z
1 = 7 m. The systematic z
1-dependence is also observed for the temperatures at a fixed height of 36 m, indicating a deficiency in the self-consistency
of the model results that is not related to a specific PBL formulation. Possible reasons for this deficiency are discussed
in the paper. On the other hand, a systematic z
1-dependence of the 36-m wind speed is encountered only for one out of the five PBL schemes. This turns out to be related to
an unrealistic profile of the vertical mixing coefficient.
Correspondence: Günther Z?ngl, Meteorologisches Institut der Universitat München, 80333 München, Germany 相似文献
16.
Mini-Sodar Observations of Drainage Flows in the Rocky Mountains 总被引:1,自引:0,他引:1
F. A. Woülfelmaier C. W. King E. Mursch-Radlgruber G. Rengarajan 《Theoretical and Applied Climatology》1999,64(1-2):83-91
Summary Vertical profiles of drainage winds were monitored continuously by a Doppler-Mini-Sodar during case studies in two valleys,
on both sides of the U. S. Continental Divide. A tethered balloon provided additional information on the vertical temperature
and wind structure up to the Divide level. Ambient wind data were collected by a radar wind profiler on the west side, and
a tower on the crest of the Divide. The onset, evolution and breakup of the drainage flow were studied on two nights, when
the ridge-top winds were westerly and skies were clear. To study the influence of the ambient flow on drainage winds, changes
in drainage wind speed, direction and depth, along with the volume flux were examined. It was found that, on the leeward side,
the drainage was strongly influenced by the ambient winds (King, 1995b), which led to interruption and erosion of the locally
generated valley flow. The drainage on the windward side of the Divide was almost undisturbed. A comparison of balloon and
sodar wind profiles showed very good agreement during steady drainage conditions.
Received October 21, 1996 Revised November 30, 1998 相似文献
17.
Characteristics of the winter boundary layer over the (elevation 1600 m) in the vicinity of Johannesburg, 26 ° S, 29 ° E, are described in relation to air pollution potential by means of doppler sounder observations and background climatological data. Regional mean winds for the 800 h Pa level show that the winter boundary layer is dominated by a cell of high pressure over the Limpopo River Valley to the northeast of Johannesburg. To the south of Johannesburg, westerly circumpolar flow is prevalent and encroaches onto the plateau during the passage of frontal perturbations. Doppler sounder wind and turbulence profiles, averaged for the months of August 1984 and June 1985, are presented to establish a boundary-layer climatology. Diurnally averaged doppler sounder profiles for both months revealed a very consistent convective/day — stable/night cycle in the very dry winter conditions. A sharp radiation inversion formed just after sunset up to the 150–200 m level and grew in depth to reach 300 m on average near sunrise. The inversion caused a reduction in frictional drag and the formation of nocturnal low level jet during westerly encroachment. A case study is evaluated to determine the detailed structure of the low level jet near Johannesburg. The thermal wind plays a role in the nocturnal acceleration; mechanisms for its development and maintenance are explored. Additional work is presented on the synoptic cycle and its influence on air pollution dispersion over the African Plateau. 相似文献
18.
Summary Upper level and surface wind data for 1994 are used to provide an initial identification of the orographic effect on regional
airflow patterns upwind of the mountain barrier. A case study of the development of upstream blocking and barrier jets is
also provided.
The predominance of gradient airflow from between northwest and southwest through this region results in frequent trans-mountain
winds. The mountains are seen to have a major effect on airflow in the lowest 2000 m above sea level, with clear evidence
of orographic blocking and barrier wind development. Some variability in the extent of this blocking was noted during 1994,
which appeared to be associated with changes in the synoptic circulation and air mass characteristics. The frequent occurrence
of southwesterly winds between 300 m and 2000 m indicates significant deflection of the predominant winds to follow the southwest-northeast
orientation of the mountains. These southwesterly barrier winds occur in opposition to the apparent pressure gradient. Northeasterly
barrier winds occur mainly below 300 m, and represent a down-gradient, localised flow that is frequently separated from overlying
northwesterly gradient winds by a transitional layer, within which the wind backs with height. The controls of the extent
of orographic blocking are only assessed superficially, due to the lack of good thermodynamic data upstream of the mountains,
although a combination of wind speed and atmospheric stability is obviously important. These initial results provide a useful
insight into the extent of orographic effects on regional windfields, which will serve as the basis for future observational
and modelling studies.
Received June 11, 1998 Revised April 16, 1999 相似文献
19.
U. Corsmeier M. Kossmann N. Kalthoff A. Sturman 《Meteorology and Atmospheric Physics》2006,91(1-4):129-148
Summary In July 2000 (South Hemisphere winter), the Christchurch Air Pollution Study (CAPS2000) was performed in order to establish a comprehensive data set for documentation and analysis of nocturnal winter
smog conditions in the Christchurch area. Field activities included meteorological surface measurements, tethersonde ascents,
radiosoundings and sodar measurements. Air pollutant monitoring included CO, NO, NOx, O3, PM10, PM2.5, and black carbon measurements near the surface, and for the first time vertical CO-profile measurements in the nocturnal
boundary layer up to 100 m height.
A prerequisite for nocturnal winter smog conditions is the evolution of stable stratification before the evening traffic and
domestic heating reach a maximum. When stable stratification persists during domestic heating and road traffic in the morning,
a second pronounced maximum of air pollutants evolves at around 0800 NZST. The meteorological measurements also revealed a
complex nocturnal surface wind field, dominated by drainage winds from the Port Hills to the south and from the Canterbury
Plains to the west of the Christchurch city area. A resulting convergence zone forms over the central parts of the city and
is accompanied by low wind speeds. The position of the convergence zone varies during the night. These low winds over the
city centre, in conjunction with stable stratification, favour the accumulation of air pollutants in the lowest tens of metres.
The nocturnal winter smog situation ends with the erosion of the surface inversion at about 1100 NZST. It is shown from analysis
of the vertical CO profiles that the level of air pollution in the Christchurch area depends on the height of the stable nocturnal
boundary layer, which itself is governed by variations in the local wind systems. 相似文献
20.
S. Khodayar N. Kalthoff M. Fiebig-Wittmaack M. Kohler 《Meteorology and Atmospheric Physics》2008,99(3-4):181-198
Summary The boundary-layer structure of the Elqui Valley is investigated, which is situated in the arid north of Chile and extends
from the Pacific Ocean in the west to the Andes in the east. The climate is dominated by the south-eastern Pacific subtropical
anticyclone and the cold Humboldt Current. This combination leads to considerable temperature and moisture gradients between
the coast and the valley and results in the evolution of sea and valley wind systems. The contribution of these mesoscale
wind systems to the heat and moisture budget of the valley atmosphere is estimated, based on radiosoundings performed near
the coast and in the valley.
Near the coast, a well-mixed cloud-topped boundary layer exists. Both, the temperature and the specific humidity do not change
considerably during the day. In the stratus layer the potential temperature increases, while the specific humidity decreases
slightly with height. The top of the thin stratus layer, about 300 m in depth, is marked by an inversion. Moderate sea breeze
winds of 3–4 m s−1 prevail in the sub-cloud and cloud layer during daytime, but no land breeze develops during the night.
The nocturnal valley atmosphere is characterized by a strong and 900 m deep stably stratified boundary layer. During the day,
no pronounced well-mixed layer with a capping inversion develops in the valley. Above a super-adiabatic surface layer of about
150 m depth, a stably stratified layer prevails throughout the day. However, heating can be observed within a layer above
the surface 800 m deep. Heat and moisture budget estimations show that sensible heat flux convergence exceeds cold air advection
in the morning, while both processes compensate each other around noon, such that the temperature evolution stagnates. In
the afternoon, cold air advection predominates and leads to net cooling of the boundary layer. Furthermore, the advection
of moist air results in the accumulation of moisture during the noon and afternoon period, while latent heat flux convergence
is of minor relevance to the moisture budget of the boundary layer.
Correspondence: Norbert Kalthoff, Institut für Meteorologie und Klimaforschung, Universit?t Karlsruhe/Forschungszentrum Karlsruhe,
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