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1.
J. C. González Hidalgo M. De Luís J. Raventós J. R. Sánchez 《Theoretical and Applied Climatology》2003,75(1-2):117-130
Summary ?We have analyzed daily rainfall trends throughout the second half of the 20th century in the western Mediterranean basin (Valencia Region, E of Spain). The area is characterized by high torrentiality,
and during the second half of the 20th century some of the highest daily rainfall values in the Mediterranean basin have been recorded. In this area, mean annual
rainfall varies between 500 and 300 mm and is overwhelmingly dependent on just a few days of rain. Daily maximum rainfall
varies on average from 120 mm day−1 to 50 mm day−1, and represents a mean of 17% (coastland) to 9% (inland) of annual rainfall. The 10 days in each year with the heaviest rainfall
(called “higher events”) provide over 50% of the annual rainfall and can reach more than 400 mm on average. We compared the
annual rainfall trend and the trend of higher and minor events defined by percentiles, both in volume and variability. We,
therefore, tested whether annual rainfall changes depend on the trend of the higher (rainfall) events.
To overlap spatial distribution of trends (i.e.: positive, no significant and negative trends) we have used cross-tab analysis.
The results confirm the hypothesis that annual rainfall changes depend on changes found in just a few rainy events. Furthermore,
in spite of their negative trend, higher events have increased their contribution to annual rainfall.
As a consequence, although torrential events may have diminished in magnitude, future scenarios seem to be controlled by a
limited number of rainy events which will become more and more variable year on year. The high spatial density of data used
in this work, (97 observatories per 24.000 km2, overall mean 1 observatory per 200 km2), suggests to us that extreme caution should be applied when analyzing regional and sub-regional changes in rainfall using
GCM output, especially in areas of high torrentiality.
Received August 1, 2002; revised November 11, 2002; accepted December 1, 2002
Published online May 19, 2003 相似文献
2.
Summary The aim of the paper lies in the identification of possible significant linear trends at monthly, seasonal and annual timescales
in the Mediterranean during the second half of the 20th century. Monthly and daily records of 63 stations have been used to
elaborate several precipitation indices: sum of daily precipitation (SDP) for rainfall >0.1 mm, >10 mm and >95th percentile, of number of rainy days (RD) >0.1 mm and >10 mm and of mean daily precipitation (MDP) >0.1 mm and >10 mm. For
each index the stations have been gathered together by Rotated Principal Component Analyses to determine 8 sub-areas which
can be considered as identical for all the timescales at the spatial scale of the research. Trends have been estimated from
the scores of each eigenvector retained in all RPCAs. They are mainly non existant or non significant decreasing, even if
a few monthly trends appear to be significantly diminishing, primarily during winter months, March in the Atlantic region,
October in the Mediterranean Spain, December in the Lions and Genoa Gulfs, January, winter and the year in Greece, winter
and the year in Italy and winter in the Near East and increasing in April in the two gulfs. Correlation coefficients between
SDP>0.1 mm and other indices have been computed: the significant trends seem mainly related to RD>10 mm, which represents
a high percentage of the total rainfall amount. Greece is remarkable: SDP>0.1 mm and >10 mm decrease significantly during
January, winter, the rainy season and the entire year whereas SDP>95th percentile increases significantly, in accordance with the climatic change scenarios for the end of this century as does
the decreasing of the total monthly and seasonal rainfall. 相似文献
3.
Summary During the summer season, typhoons form in the western north Pacific Ocean and travel westward towards China. Some recurve
northward off the coast, whereas others continue in over land. These typhoons bring heavy rainfall to the Huai river basin
in eastern central China. In August 1975, the remnant of typhoon Nina caused exceptionally heavy rainfall in the Hongru river
basin, in the mountainous upper reaches of the Huai river. The rainfall lasted five days from 4 to 8 August. This type of
nearly stationary typhoon can cause rainfall of large intensity for a long duration, and is suitable for maximization to derive
probable maximum precipitation (PMP) estimates. The PMP is transformed into a probable maximum flood hydrograph that is subsequently
used to design spillways etc. In this study the PMP values have been estimated using a hydrometeorological method involving
depth-area-duration analysis, moisture maximization, and altitude adjustment for typhoon Nina, for 1, 2, and 3 days duration.
Areal PMP values were obtained for the entire Hongru river catchment, as well as for the subcatchments upstream the dams at
Banqiao (762 km2), Shimantan (230 km2), Boshan (580 km2), and Suyahu (4 498 km2). For point values, the PMP was estimated to 1 200 mm/day, 1 460 mm/2 days, and 1 910 mm/3 days at altitudes about 100 m,
which agrees well with previous studies.
Received February 21, 1997 Revised May 27, 1997 相似文献
4.
Rainfall characteristics during the annual rainy season are explored for the Mzingwane catchment of south-western Zimbabwe, for both historic period (1886–1906) and more recent times (1950–2015), based on available daily and monthly precipitation series. Annual and seasonal rainfall trends are determined using the modified Mann-Kendall test, magnitude of trends test and Sen’s slope estimator. Rainfall variability is quantified using the coefficient of variation (CV), precipitation concentration index (PCI) and standard precipitation index (SPI). Results suggest that contemporary mean annual rainfall may not have changed from that measured during the historic period of 1886–1906. However, the number of rainy days (≥ 1 mm) has decreased by 34%, thus suggesting much more concentrated and increased rainfall intensity. A notable shift in both the onset and cessation dates of the rainy season is recorded, particularly during the twenty-first century, which has resulted in a significantly reduced (p < 0.05) length of the rainy season. The combination of a reduced number of rainy days (≥ 1 mm) and a shortened rainy season suggests that long intra-season dry spells have become more common through time and have considerable negative consequences for agriculture and wetland ecosystem in the region. In addition, high spatio-temporal rainfall variability and seasonal PCI values indicate strong seasonality in the rainy season. Based on the SPI results, the El Niño Southern Oscillation (ENSO) strongly influences rainfall variability. The results further suggest high uncertainty in rain season characteristics, which requires effective planning for water needs. 相似文献
5.
The study evaluated CORDEX RCMs’ ability to project future rainfall and extreme events in the Mzingwane catchment using an ensemble average of three RCMs (RCA4, REMO2009 and CRCM5). Model validation employed the statistical mean and Pearson correlation, while trends in projected rainfall and number of rainy days were computed using the Mann-Kendall trend test and the magnitudes of trends were determined by Sen’s slope estimator. Temporal and spatial distribution of future extreme dryness and wetness was established by using the Standard Precipitation Index (SPI). The results show that RCMs adequately represented annual and inter-annual rainfall variability and the ensemble average outperformed individual models. Trend results for the projected rainfall suggest a significant decreasing trend in future rainfall (2016–2100) for all stations at p < 0.05. In addition, a general decreasing trend in the number of rainy days is projected for future climate, although the significance and magnitude varied with station location. Model results suggest an increased occurrence of future extreme events, particularly towards the end of the century. The findings are important for developing proactive sustainable strategies for future climate change adaption and mitigation. 相似文献
6.
R. García-Herrera D. Barriopedro E. Hernández D. Paredes J. F. Correoso L. Prieto 《Meteorology and Atmospheric Physics》2005,90(3-4):225-243
Summary This paper characterizes Mesoscale Convective Systems (MCSs) during 2001 over Iberia and the Balearic Islands and their meteorological
settings. Enhanced infrared Meteosat imagery has been used to detect their occurrence over the Western Mediterranean region
between June and December 2001 according to satellite-defined criteria based on the MCS physical characteristics.
Twelve MCSs have been identified. The results show that the occurrence of 2001 MCSs is limited to the August–October period,
with September being the most active period. They tend to develop during the late afternoon or early night, with preferred
eastern Iberian coast locations and eastward migrations. A cloud shield area of 50.000 km2 is rarely exceeded. When our results are compared with previous studies, it is possible to assert that though 2001 MCS activity
was moderate, the convective season was substantially less prolonged than usual, with shorter MCS life cycles and higher average
speeds. The average MCS precipitation rate was 3.3 mm·h−1 but a wide range of values varying from scarce precipitation to intense events of 130 mm·24 h−1 (6 September) were collected. The results suggest that, during 2001, MCS rainfall was the principal source of precipitation
in the Mediterranean region during the convective season, but its impact varied according to the location.
Synoptic analysis based on NCEP/NCAR reanalysis show that several common precursors could be identified over the Western Mediterranean
Sea when the 2001 MCSs occurred: a low-level tongue of moist air and precipitable water (PW) exceeding 25 mm through the southern
portion of the Western Mediterranean area, low-level zonal warm advection over 2 °C·24 h−1 towards eastern Iberia, a modest 1000–850 hPa equivalent potential temperature (θe) difference over 20 °C located close to the eastern Iberian coast, a mid level trough (sometimes a cut-off low) over Northern
Africa or Southern Spain and high levels geostrophic vorticity advection exceeding 12·10−10 s−2 over eastern Iberia and Northern Africa. Finally, the results suggest that synoptic, orographic and a warm-air advection
were the most relevant forcing mechanisms during 2001. 相似文献
7.
C. Svensson 《Theoretical and Applied Climatology》1999,62(3-4):147-161
Summary The design and operation of hydro-structures for flood control and water conservation bring a need for improved characterization
of precipitation patterns. A 73 000 km2 study area in East Central China is situated in the East Asian monsoon region and experiences a strong seasonality in the
rainfall regime. The characteristics of daily rainfall from 230 gauges during 1967–1986 were investigated for four periods
in the summer monsoon season using empirical orthogonal function analysis (EOF) and extended empirical orthogonal function
analysis (EEOF). The EOF analysis showed that for all four periods most of the variance was explained by an elongated spatial
rainfall pattern. The pattern varied in direction, from roughly west-east to southwest-northeast, in the different periods.
The zonally oriented patterns were interpreted as being caused by the stationary Mei-Yu front and the southwest-northeast
patterns interpreted as cold fronts in cyclones that were developing over the study area. The latitude of the rain belt described
by the first mode moved slightly northward with the advance of the East Asian monsoon from the first period, 9–22 June, to
the third period, 23 July–5 August, and then withdrew southward again in accordance with the known seasonal movement of the
Mei-Yu front. The EEOF analysis was used to show the development of the rainfall area over sequences of three days. During
all four periods rainfall intensified on the second day, compared to the first and third days. During the first and last periods,
9–22 June and 5 August–30 September, respectively, there appeared to be little movement in the rainfall. During the second
and third periods, the patterns were interpreted as a cold front in a developing cyclone. The results show the connection
between the temporal variation in rainfall intensity and the temporal succession of spatial patterns over three day periods
and should be used in the construction of design rainfalls for the study area.
Received February 10, 1998 Revised June 23, 1998 相似文献
8.
M. Jury H. Rautenbach M. Tadross A. Philipp 《Theoretical and Applied Climatology》2007,88(3-4):169-177
Summary Spatial scales of variability in seasonal rainfall over Africa are investigated by means of statistical and numerical techniques.
In the statistical analysis spatial structure is studied using gridded 0.5° resolution monthly data in the period 1948–1998.
The de-seasonalized time series are subjected to successive principal component (PC) analysis, allowing the number of modes
to vary from 10 to 24, producing cells of varying dimension. Then the original rainfall data within each cell are cross-correlated
(internal), then averaged and compared with the adjacent cells (external) for each PC solution. By considering the ratio of
internal to external correlation, the spatial scales of rainfall variability are evaluated and an optimum solution is found
whose cell dimensions are approximately 106 km2. The aspect of scale is further studied for southern Africa by consideration of numerical model ensemble simulations over
the period 1985–1999 forced with observed sea surface temperatures (SSTs). The hindcast products are compared with observed
January to March (JFM) rainfall, based on a station-satellite merged analysis of precipitation (CMAP) data at 2.5° resolution.
Validations for different sized areas indicate that cumulative standardized errors are greatest at the scale of a single grid
cell (104 km2) and decrease 20–30% by averaging over successively larger areas (106 km2). 相似文献
9.
Summary ?The LITFASS project (‘Lindenberg Inhomogeneous Terrain – Fluxes between Atmosphere and Surface: a Long-term Study’) of the Deutscher Wetterdienst (DWD, German Meteorological Service) aims to develop and to test a strategy for the determination
and parameterisation of the area-averaged turbulent fluxes of heat, momentum, and water vapour over a heterogeneous land surface.
These fluxes will be representative for an area of about 10 * 10 km2 (while the typical patch size is between 10−1 to 100 km2) corresponding to the size of a grid cell in the present operational numerical weather prediction model of the DWD.
LITFASS consists of three components:
– the development of a non-hydrostatic micro-α-scale model (the LITFASS local model – LLM) with a grid-size of about 100 * 100 m2,
– experimental investigations of land surface – atmosphere exchange processes and boundary layer structure within a 20 * 20 km2 area around the Meteorological Observatory Lindenberg,
– the assimilation of a data base as an interface between measurements and modelling activities.
The overall project strategy was tested over a three-week period in June 1998 during the LITFASS-98 field experiment. This
paper gives an overview on the LITFASS project, on the design and measurement program of the LITFASS-98 experiment, and on
the weather conditions during the period of the experiment. Conclusions are formulated for the operational realisation of
the LITFASS measurement concept and for future field experiments aimed at studying the land surface – atmosphere interaction
in the Lindenberg area. Selected results from both experimental and modelling activities are presented in a series of companion
papers completing this special issue of the journal.
Received June 18, 2001; revised March 18, 2002; accepted April 2, 2002 相似文献
10.
This is the first attempt to merge highly accurate precipitation estimates from Global Precipitation Measurement (GPM) with gap free satellite observations from Meteosat to develop a regional rainfall monitoring algorithm to estimate heavy rainfall over India and nearby oceanic regions. Rainfall signature is derived from Meteosat observations and is co-located against rainfall from GPM to establish a relationship between rainfall and signature for various rainy seasons. This relationship can be used to monitor rainfall over India and nearby oceanic regions. Performance of this technique was tested by applying it to monitor heavy precipitation over India. It is reported that our algorithm is able to detect heavy rainfall. It is also reported that present algorithm overestimates rainfall areal spread as compared to rain gauge based rainfall product. This deficiency may arise from various factors including uncertainty caused by use of different sensors from different platforms (difference in viewing geometry from MFG and GPM), poor relationship between warm rain (light rain) and IR brightness temperature, and weak characterization of orographic rain from IR signature. We validated hourly rainfall estimated from the present approach with independent observations from GPM. We also validated daily rainfall from this approach with rain gauge based product from India Meteorological Department (IMD). Present technique shows a Correlation Coefficient (CC) of 0.76, a bias of −2.72 mm, a Root Mean Square Error (RMSE) of 10.82 mm, Probability of Detection (POD) of 0.74, False Alarm Ratio (FAR) of 0.34 and a Skill score of 0.36 with daily rainfall from rain gauge based product of IMD at 0.25° resolution. However, FAR reduces to 0.24 for heavy rainfall events. Validation results with rain gauge observations reveal that present technique outperforms available satellite based rainfall estimates for monitoring heavy rainfall over Indian region. 相似文献
11.
Recent trends in observed temperature and precipitation extremes in the Yangtze River basin,China 总被引:14,自引:1,他引:14
Summary The present study is an analysis of the observed extreme temperature and precipitation trends over Yangtze from 1960 to 2002
on the basis of the daily data from 108 meteorological stations. The intention is to identify whether or not the frequency
or intensity of extreme events has increased with climate warming over Yangtze River basin in the last 40 years. Both the
Mann-Kendall (MK) trend test and simple linear regression were utilized to detect monotonic trends in annual and seasonal
extremes.
Trend tests reveal that the annual and seasonal mean maximum and minimum temperature trend is characterized by a positive
trend and that the strongest trend is found in the winter mean minimum in the Yangtze. However, the observed significant trend
on the upper Yangtze reaches is less than that found on the middle and lower Yangtze reaches and for the mean maximum is much
less than that of the mean minimum. From the basin-wide point of view, significant increasing trends are observed in 1-day
extreme temperature in summer and winter minimum, but there is no significant trend for 1-day maximum temperature. Moreover,
the number of cold days ≤0 °C and ≤10 °C shows significant decrease, while the number of hot days (daily value ≥35 °C) shows
only a minor decrease. The upward trends found in the winter minimum temperature in both the mean and the extreme value provide
evidence of the warming-up of winter and of the weakening of temperature extremes in the Yangtze in last few decades.
The monsoon climate implies that precipitation amount peaks in summer as does the occurrence of heavy rainfall events. While
the trend test has revealed a significant trend in summer rainfall, no statistically significant change was observed in heavy
rain intensity. The 1-day, 3-day and 7-day extremes show only a minor increase from a basin-wide point of view. However, a
significant positive trend was found for the number of rainstorm days (daily rainfall ≥50 mm). The increase of rainstorm frequency,
rather than intensity, on the middle and lower reaches contributes most to the positive trend in summer precipitation in the
Yangtze. 相似文献
12.
B. Sow A. Viltard P. de Félice A. Deme G. Adamou 《Meteorology and Atmospheric Physics》2005,90(3-4):209-214
Summary The aim of the paper is to show that NCEP-NCAR reanalyses do display modifications in the atmosphere at the occurrence of
squall lines (SLs). 135 SLs were detected at Dakar (Senegal) during the summers of 1981–95. A compositing method was applied
to temperature, specific humidity and zonal wind component at grid-point 15° N; 17.5° W close to Dakar, for the 135 SLs’ occurrences.
The slight modifications of these three parameters as computed here proved to be statistically significant. 相似文献
13.
Summary. Mesoscale convective precipitation systems in the Alpine region are studied by analyzing radar and rain gauge data. The data
from weather radars in Austria, France, Germany, and Switzerland are combined into a composite. Availability of radar data
restricts the study mainly to the northern part of the Alpine region. Mesoscale convective systems (MCS) occur often in this
region and are comparable to large systems observed in the USA. Seven precipitation events lasting one to six days from the
years 1992–1996 are examined in detail. They all moved west to east and showed no diurnal preference in formation or dissipation.
They reach sizes of 2 − 6 · 104 km2. MCS with leading-line trailing-stratiform structure tended to be larger and more intense. A 25-year set of rain gauge data
indicates that a giant MCS (covering more than 4 · 104 km2 with more than 30 mm/day) occurs every 6 years in the northern Alpine region. MCS occur more frequently in the southern Alpine
region.
Received February 25, 1999/Revised June 29, 1999 相似文献
14.
Summary This paper assesses recent changes in extremes of seasonal rainfall in Ethiopia based on daily rainfall data for 11 key stations
over the period 1965–2002. The seasons considered are Kiremt (‘main rains’, June–September) and Belg (‘small rains’, February/March–May). The Mann-Kendall and linear regression trend tests show decreasing trends in the Kiremt and the Belg extreme intensity and maximum consecutive 5-day rains over eastern, southwestern and southern parts of Ethiopia whereas no
trends are found in the remaining part of Ethiopia. In general, no trends are found in the yearly maximum length of Kiremt and Belg dry spells (days with rainfall below 1 mm) over Ethiopia. 相似文献
15.
Summary The present paper investigates the potential of combining image processing techniques based on cluster analysis of infrared
(IR) Meteosat images with dynamic meteorological theory on synoptic systems. From this last point of view the highest probability
of deep convective development is favoured where the overlapping of four mechanisms acting at synoptic scale is produced:
upward quasi-geostrophic forcing, convergence of water vapour at low levels, convective instability in the lower troposphere
and great convective available potential energy. Cloud tracking is performed over sequences of Meteosat IR images by using
a shape parameterisation approach after appropriate filtering for non-significant clouds and automated identification of convective
systems. The integrated methodology is applied to the case study of the heavy rainfall event which produced floods in the
South of France and the North of Italy on September 27–28th, 1992. The analysis focuses on the monitoring and explanation of the zones most affected by heavy rainfall with the aim of
investigating possible improvements of the predictive potential of cloud tracking and allowing identification of the areas
which most lend themselves to flash floods for use in operational flood forecasting applications.
Received July 20, 1998/Revised June 21, 1999 相似文献
16.
R. R. Reddy K. Rama Gopal L. Siva Sankara Reddy K. Narasimhulu K. Raghavendra Kumar Y. Nazeer Ahammed C. V. Krishna Reddy 《Journal of Atmospheric Chemistry》2008,59(1):47-59
In the present study, an attempt has been made to examine the governing photochemical processes of surface ozone (O3) formation in rural site. For this purpose, measurements of surface ozone and selected meteorological parameters have been
made at Anantapur (14.62°N, 77.65°E, 331 m asl), a semi-arid zone in India from January 2002 to December 2003. The annual
average diurnal variation of O3 shows maximum concentration 46 ppbv at noon and minimum 25 ppbv in the morning with 1σ standard deviation. The average seasonal
variation of ozone mixing ratios are observed to be maximum (about 60 ppbv) during summer and minimum (about 22 ppbv) in the
monsoon period. The monthly daytime and nighttime average surface ozone concentration shows a maximum (55 ± 7 ppbv; 37 ± 7.3 ppbv)
in March and minimum (28 ± 3.4 ppbv; 22 ± 2.3 ppbv) in August during the study period. The monthly average high (low) O3 48.9 ± 7.7 ppbv (26.2 ± 3.5 ppbv) observed at noon in March (August) is due to the possible increase in precursor gas concentration
by anthropogenic activity and the influence of meteorological parameters. The rate of increase of surface ozone is high (1.52 ppbv/h)
in March and lower (0.40 ppbv/h) in July. The average rate of increase of O3 from midnight to midday is 1 ppbv/h. Surface temperature is highest (43–44°C) during March and April months leading to higher
photochemical production. On the other hand, relative humidity, which is higher during the rainy season, shows negative correlation
with temperature and ozone mixing ratio. It can be seen that among the two parameters are measured, correlation of surface
ozone with wind speed is better (R
2=0.84) in compare with relative humidity (R
2=0.66). 相似文献
17.
Summary Monthly rainfall conditions in Israel were determined, using data from 12 stations, during 30 years (1961–90). The definition
of a month to be dry, normal or wet, was done using standardized rainfall totals. Pressure departures for each of the three rainfall categories for each month
of the rainy season, were calculated and mapped. Correlation between rainfall totals at each of the 12 stations and monthly
mean sea level pressure at 72 grid points in the area delimited by the 20° W and 50° E meridians and the 20° N and 60° N parallels,
was performed. For each month, 12 correlation maps were prepared (one of each station). Similar maps were averaged together
to form coherent rainfall regions. At the beginning of the rainy season (October) the rainfall in Israel is sporadic and spotty
without a distinctable coherent region. At the end of the rainy season (April) the rainfall is more widespread, forming a
large coherent region covering most of the country.
Dry rainfall conditions in Israel, were found to be characterized by positive pressure departures in the eastern Mediterranean
and over Israel and/or by easterly or southerly circulation over the eastern Mediterranean. Wet rainfall conditions in Israel,
were found to be characterized by negative pressure departures in the eastern Mediterranean and over Israel and/or by westerly
or northerly circulation over the eastern Mediterranean. Moreover, in many cases dry conditions in Israel, were associated
with below normal pressure conditions over central or western Europe, while wet conditions in Israel, with above normal conditions
over the same region, thus, reflecting the so-called Mediterranean Oscillation. Finally, normal rainfall conditions are characterized by very slight to negligible pressure departures over the entire Mediterranean
and Europe.
Received November 18, 1997 Revised March 3, 1998 相似文献
18.
Summary A mesoscale convective system (MCS) case that developed over the Yellow Sea (12–13 July 1993) is studied by using a 23-level,
30 km-mesh Penn State/NCAR mesoscale model MM5. This MCS was generated in northern China, south of the Changma front, in a
convectively unstable environment, under the influence of a short-wave trough accompanied by a marked cold vortex aloft.
The model with all model physics (refereed to as CNTL) captured the major features of this MCS. A mesoscale low-level jet
(mLLJ), with a horizontal scale of a few hundred km, developed within the MCS. Available wind data support the realism of
this mLLJ. This mLLJ not only transports convectively unstable air directly toward the MCS but is also responsible for a strong
low-level convergence in the MCS. At 200 hPa, an anticyclonic northwesterly flow with a relatively high wind speed core on
the east of MCS was simulated. This relatively high-speed flow can be regarded as a mesoscale upper level jet (mULJ), acted
as an upper outflow over the MCS. Low-level convergence on the left-front of the mLLJ and upper divergence in the right-rear
of the mULJ creates a strong upward motion (≅ 40 cm s−1) in the MCS.
Heavy precipitation up to 45 mm between 1800–2100 UTC was observed after this MCS landed on the southern Korean Peninsula.
The CNTL run captured this heavy rainfall event. A maximum rainfall of 50 mm 3 h−1 was simulated. In another experiment, with surface sensible and moisture fluxes withheld (NOSF), the 3-h simulated rainfall
was decreased to 30 mm. Less latent heat released in the NOSF led to a weaker MCS and mLLJ. The concurrent surface fluxes
sustained a high low-level moisture field over the Yellow Sea, which helped the development of the MCS and enhanced its precipitation
in this case.
Received January 8, 1999 相似文献
19.
The climatic characteristics of the precipitation in Guangdong province over the past 50 years were analyzed based on the daily rainfall datasets of 86 stations from 1961 to 2010. The rainfall was divided into five categories according to its intensity, and their spatiotemporal characteristics and variation trends were investigated. The annual rainfall amount was within 1,500 to 2,000 mm over most parts of Guangdong, but substantial differences of rainfall amount and rainy days were found among different parts of the province. There were many rainy days in the dry seasons (October to March), but the daily rainfall amounts are small. The rainy seasons (April to September) have not only many rainy days but also heavy daily rainfall amounts. The spatial distributions of light rainy days (1 mm 100 mm) are generally concentrated in three regions, Qingyuan, Yangjiang, and Haifeng/Lufeng. The average rainfall amount for rainy days increases form the north to the south of Guangdong, while decreasing as the rainfall intensity increases. The contributions from light, moderate and heavy rain to the total rainfall decreases form the north to the south. The annual rainy days show a decreasing trend in the past 50 years. The light rainy days decreased significantly while the heavy, rainstorm and downpour rainy days increased slightly. The annual total rainfall amount increased over the past 50 years, which was contributed by heavy, rainstorm and downpour rains, while the contribution from light and moderate rains decreased. 相似文献
20.
Summary The west coast of the Indian peninsula receives very heavy rainfall during the summer Monsoon (June–September) season with
average rainfall over some parts exceeding 250 cm. Heavy rainfall events with rainfall more than 15 cm day−1 at one or more stations along the west coast of India occur frequently and cause considerable damage. A special observational
programme, Arabian Sea Monsoon Experiment, was carried out during the monsoon season of 2002 to study these events. The spatial
and temporal distributions of intense rainfall events, presented here, were used for the planning of this observational campaign.
The present study using daily rainfall data for summer monsoon season of 37 years (1951–1987) shows that the probability of
getting intense rainfall is the maximum between 14° N–16° N and near 19° N. The probability of occurrence of these intense
rainfall events is high from mid June to mid August, with a dip in early July. It has been believed for a long time that offshore
troughs and vortices are responsible for these intense rainfall events. However, analysis of the characteristics of cloud
systems associated with the intense rainfall events during 1985–1988 using very high resolution brightness temperature data
from INSAT-IB satellite shows that the cloud systems during these events are characterized by large spatial scales and high cloud tops.
Further study using daily satellite derived outgoing longwave radiation (OLR) data over a longer period (1975–1998) shows
that, most of these events (about 62%) are associated with systems organized on synoptic and larger scales. We find that most
of the offshore convective systems responsible for intense rainfall along the west coast of India are linked to the atmospheric
conditions over equatorial Indian Ocean. 相似文献