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1.
An analysis is made of the effects of topography on the summer atmospheric energetics of the Northern Hemisphere in a low-resolution global spectral model. The numerical model is a global, spectral, primitive equation model with five equally spaced sigma levels in the vertical and triangular truncation at wavenumber 10 in the horizontal. The model includes comparatively full physical processes.Each term of the energy budget equations is calculated in four specific latitudinal belts (81.11°S-11.53°S; 11.53°S-11.53°N; 11.53°N-46.24°N; 46.24°N-81.11°N) from a five-year simulation with mountains and a one-year simulation without mountains, respectively. Differences between them are compared and statistically tested. The results show that synoptical scale waves transport available potential energy and kinetic energy to long waves and increase conversion from available potential energy of the zonal flow to eddy’s and from the eddy kinetic energy to the zonal kinetic energy in region 3 (11.53°N-46.24°N) due to mountains; topography intensifies the atmospheric baroclinity in region 3, consequently the baroclinic conversion of atmosphere energy is increased. The seasonal characteristics associated with the summer atmospheric energy source in region 3 are caused by seasonal variation of the solar radiation and the land-ocean contrasts and independent of topographic effects. The mechanism of topographic effects on the increase of long wave kinetic energy is also discussed. 相似文献
2.
Based on calculations of data from FGGE Level III b, a discussion is made of the energy balance in the 40-50 day periodic oscillation over the Asian monsoon region during the 1979 summer. It is found that the main source of 40-50 day periodic perturbation is the monsoon region extending from central South Asia to Southeast Asia. In the upper layer over the North Pacific subtropical area (10-20oN, 150oE-150oW) pres-sure work turns into kinetic energy that maintains 40-50 day periodic perturbation associated with the variation in position and intensity of the mid-Pacific trough. The mean energy budget in the three-dimensional space (0-30oE, 30oE-150oW, 100-1000 hPa) indicates that the 40-50 day periodic perturbation transports kinetic energy to a seasonal mean and a transient perturbation wind field. 相似文献
3.
C. V. Singh 《Theoretical and Applied Climatology》2006,84(4):207-211
Summary In this study, Principal Component Analysis (PCA) has been used to identify the major modes of the outgoing long-wave radiation
data for the period (1979–2002) during the Indian monsoon period (June–September), using seasonal mean values over the Indian
region covering 143 grid points (5° N–35° N and 70° E–95° E at 2.5° Longitude–Latitude intervals. The five principal components
explain up to 98.0% of the total variance. The first principal component explains 60% of the total variance with a pronounced
variation in the outgoing long-wave radiation over the region 10° N to 25° N. It appears that the major reason for the monsoon
variability is the intensity and associated fluctuations in the two major semi-permanent seasonal systems. This is largely
indicative of strong seasonal shift of the major area of cloudiness associated with convergence zone. The second principal
component explaining 20% of the total variance exhibits higher positive component loadings along 25° N and east of 80° E.
The possible reason for this could be the synoptic systems such as monsoon depression/lows over the north bay and trough/vortices
off the west-coast in the Arabian sea. 相似文献
4.
本文利用1980—1988年30°S—30°N的风场资料,计算了逐日的平均动能,涡动动能及相互转换和波数域动能;并分析了南、北半球热带对流层中层动能的演变特征,季节调整规律,指出了热带与中高纬动能的差异。 相似文献
5.
The horizontal and vertical structure of the 3–5-day and 6–9-day easterly waves over West Africa and tropical Atlantic are
investigated. NCEP/NCAR reanalyses are used for the period 1979–1995 to produce a 17-year climatology of both 3–5-day and
6–9-day easterly waves. Composite patterns of convection, wind, temperature and vertical velocity are analysed with respect
to the following: the modulation by 3–5-day and 6–9-day wave regimes; the contrasts between the ITCZ (5°N–10°N) and the Sahelo-Saharan
band (15°N–20°N); the difference between land and ocean, and seasonal variations. Similarities and differences in the characteristics
of the two wave regimes are identified.
Received: 18 August 1999 / Accepted: 14 March 2001 相似文献
6.
The climatological summer monsoon onset displays a distinct step wise northeastward movement over the South China Sea and
the western North Pacific (WNP) (110°–160°E, 10°–20°N). Monsoon rain commences over the South China Sea-Philippines region
in mid-May, extends abruptly to the southwestern Philippine Sea in early to mid-June, and finally penetrates to the northeastern
part of the domain around mid-July. In association, three abrupt changes are identified in the atmospheric circulation. Specifically,
the WNP subtropical high displays a sudden eastward retreat or quick northward displacement and the monsoon trough pushes
abruptly eastward or northeastward at the onset of the three stages. The step wise movement of the onset results from the
slow northeastward seasonal evolution of large-scale circulation and the phase-locked intraseasonal oscillation (ISO). The
seasonal evolution establishes a large-scale background for the development of convection and the ISO triggers deep convection.
The ISO over the WNP has a dominant period of about 20–30 days. This determines up the time interval between the consecutive
stages of the monsoon onset. From the atmospheric perspective, the seasonal sea surface temperature (SST) change in the WNP
plays a critical role in the northeastward advance of the onset. The seasonal northeastward march of the warmest SST tongue
(SST exceeding 29.5 °C) favors the northeastward movement of the monsoon trough and the high convective instability region.
The seasonal SST change, in turn, is affected by the monsoon through cloud-radiation and wind-evaporation feedbacks.
Received: 19 October 1999 / Accepted: 5 June 2000 相似文献
7.
Tropical cyclone genesis frequency over the western North Pacific simulated in medium-resolution coupled general circulation models 总被引:4,自引:0,他引:4
This study examines the tropical cyclone (TC) genesis frequency over the western North Pacific simulated in atmosphere–ocean
coupled general circulation models from the World Climate Research Programme’s Coupled Model Intercomparison Project phase
3. We first evaluate performances of eight models with atmospheric horizontal resolution of T63 or T106 by analyzing their
daily-mean atmospheric outputs of twentieth-century climate simulations available from the Program for Climate Model Diagnosis
and Intercomparison database. The genesis frequency is validated against the best-track data issued by the Japan Meteorological
Agency. Five of the eight models reproduce realistic horizontal distribution of the TC genesis with a large fraction over
the 10°–20°N, 120°–150°E area. These five high-performance models also realistically simulate the summer–winter contrast of
the frequency. However, detailed seasonal march is slightly unrealistic; four of the models overestimate the frequency in
the early season (May–June) while all of them underestimate the frequency in the mature season (July–September). Reasons for
these biases in the seasonal march for the five high-performance models are discussed using the TC genesis potential (GP)
index proposed by Emanuel and Nolan (in Am Meteor Soc, pp 240–241, 2004). The simulated GP has seasonal biases consistent with those of the TC genesis frequency. For all five models, the seasonal
biases in GP are consistent with those in environmental lower-tropospheric vorticity, vertical wind shear, and relative humidity,
which can be attributed to the simulated behavior of monsoon trough. The observed trough migrates northward from the equatorial
region to reach the 10°–20°N latitudinal band during the mature season and contributes to the TC frequency maximum, whereas
the simulated trough migrates northward too rapidly and reaches this latitude band in the early season, leading to the overestimation
of the TC genesis frequency. In the mature season, the simulated trough reaches as far as 15°–25°N, accompanied by a strong
vertical shear south of the trough, providing an unfavorable condition for TC genesis. It is concluded that an adequate simulation
of the monsoon trough behavior is essential for a better reproduction of the TC frequency seasonal march. 相似文献
8.
Summary Latitude-altitude structure of ozone QBO over the tropical-subtropical stratosphere (40° S–40° N) has been explored by analyzing
Microwave Limb Sounder (MLS) aboard Upper Atmospheric Research Satellite (UARS) data for the period 1992–1999 using the multifunctional
regression model. The inferred ozone QBO shows two maxima located at 22 hPa and 10 hPa with coefficient of 2–3% per 10 m/s
centered at the equator. The equatorial maxima are out of phase with each other. Subtropics exhibit two peak structure near
14 hPa but of opposite sign to that of equatorial maximum near 10 hPa. Over the equatorial region, positive (zonal winds westerly)
coefficients overlay negative (zonal winds easterlies) coefficients which descend with time. A pattern of equatorial maximum
and two subtropical minima appears in the months December to February near 10 hpa and it propagates upward with progression
of seasons. Equatorial QBO is seasonally asynchronous while subtropical QBO is seasonally synchronous.
Correspondence: Suvarna Fadnavis, Physical Meteorology and Aerology Division, Indian Institute of Tropical Meteorology, Dr.
Homi Bhabha Road, Pashan, Pune 411008, India 相似文献
9.
Maintenance and oscillation mechanisms of summer tropical upper-tropospheric easterlies 总被引:1,自引:0,他引:1
The mechanisms of the maintenance and oscillation of 1982 summer tropical 200-hPa mean easterly flow and extra-long waves
are investigated in terms of the energy equations in wavenumber-frequency space. Calculation results show that the difference
in heating between land and sea and the boundary effect serve as the main source of energy; frictional dissipation as the
sink; the conversion of available potential energy into kinetic takes place dominantly in the waves of number 1–2 such transformation
is accomplished in just a small amount in zonal mean flow and therefore can be ignored because of the value.
In the interaction between wave and zonal mean flow, the latter loses its available potential and gains kinetic energy. The
tropical easterly belt over 20°N-5°S is found barotropically stable and that over 10°-5°S, unstable. The waves of number 2
and 1 manifest themselves a primary source and sink of kinetic energy, respectively, in the interplay between waves and between
zonal mean flow and wave.
It is found that zonal mean flow and the waves of number 1-2 have a roughly 40-and 20-day oscillational period of kinetic
energy, respectively, whose primary mechanism is the transfer of barotropic energy, the conversion of baroclinic energy, and
the boundary effect. 相似文献
10.
Summary Seasonal variations of gravity wave characteristics are investigated using rawinsonde data observed at Pohang observatory,
Korea (36°2′N, 129°23′E) during the one-year period of 1998. Analysis is carried out for two atmospheric layers representing
the troposphere (2–9 km) and stratosphere (17–30 km). There exist clear seasonal variations in amplitudes of temperature and
wind perturbations and wave energy in the stratosphere, with their maxima in wintertime and minima in summertime. A strong
correlation is found between the wave activity and the strength of the jet stream, but there is no clear correlation between
the wave activity and the vertical gradient of static stability. The intrinsic frequency and vertical and horizontal wavelengths
of gravity waves in the stratosphere are 2f–3f, where f is the Coriolis parameter, and 2–3 km and 300–500 km, respectively. The intrinsic phase velocity directs westward in January
and northeastward in July. The vertical flux of the stratospheric zonal momentum is mostly negative except in summertime with
a maximum magnitude in January. Topography seems to be a major source of stratospheric gravity waves in wintertime. Convection
can be a source of gravity waves in summertime, but it is required to know convective sources at nearby stations, due to their
intermittency and locations relative to floating balloons. 相似文献
11.
In this paper, we first apply the assumption h = εh′ of topographic variation (h is the nondimensional topographic height and is a small parameter) to obtain nonlinear equations describing three-wave quasi-resonant
and non-resonant interactions among Rossby waves for zonal wavenumbers 1—3 over a wavenumber-two bottom topography (WTBT).
Some numerical calculations are made with the fourt-order Rung-Kutta Scheme. It is found that for the case without topographic
forcing, the period of three-wave quasi-resonance (TWQR) is found to be independent of the zonal basic westerly wind, but
dependent on the meridional wavenumber and the initial amplitudes. For the fixed initial data, when the frequency mismatch
is smaller and the meridional wavelength is moderate, its period will belong to the 30–60-day period band. However, when the
wavenumber-two topography is included, the periods of the forced quasi-resonant Rossby waves are also found to be strongly
dependent on the setting of the zonal basic westerly wind. Under the same conditions, only when the zonal basic westerly wind
reaches a moderate extent, intraseasonal oscillations in the 30–60-day period band can be found for zonal wavenumbers 1–3.
On the other hand, if three Rossby waves considered have the same meridional wavenumber, three-wave non-resonant interaction
over a WTBT can occur in this case. When the WTBT vanishes, the amplitudes of these Rossby waves are conserved. But in the
presence of a WTBT, the three Rossby waves oscillate with the identical period. The period, over a moderate range of the zonal
basic westerly wind, is in the intraseasonal, 30–60-Day range. 相似文献
12.
The predictability of atmospheric responses to global sea surface temperature (SST) anomalies is evaluated using ensemble
simulations of two general circulation models (GCMs): the GENESIS version 1.5 (GEN) and the ECMWF cycle 36 (ECM). The integrations
incorporate observed SST variations but start from different initial land and atmospheric states. Five GEN 1980–1992 and six
ECM 1980–1988 realizations are compared with observations to distinguish predictable SST forced climate signals from internal
variability. To facilitate the study, correlation analysis and significance evaluation techniques are developed on the basis
of time series permutations. It is found that the annual mean global area with realistic signals is variable dependent and
ranges from 3 to 20% in GEN and 6 to 28% in ECM. More than 95% of these signal areas occur between 35 °S–35 °N. Due to the
existence of model biases, robust responses, which are independent of initial condition, are identified over broader areas.
Both GCMs demonstrate that the sensitivity to initial conditions decreases and the predictability of SST forced responses
increases, in order, from 850 hPa zonal wind, outgoing longwave radiation, 200 hPa zonal wind, sea-level pressure to 500 hPa
height. The predictable signals are concentrated in the tropical and subtropical Pacific Ocean and are identified with typical
El Ni?o/ Southern Oscillation phenomena that occur in response to SST and diabatic heating anomalies over the equatorial central
Pacific. ECM is less sensitive to initial conditions and better predicts SST forced climate changes. This results from (1)
a more realistic basic climatology, especially of the upper-level wind circulation, that produces more realistic interactions
between the mean flow, stationary waves and tropical forcing; (2) a more vigorous hydrologic cycle that amplifies the tropical
forcing signals, which can exceed internal variability and be more efficiently transported from the forcing region. Differences
between the models and observations are identified. For GEN during El Ni?o, the convection does not carry energy to a sufficiently
high altitude, while the spread of the tropospheric warming along the equator is slower and the anomaly magnitude smaller
than observed. This impacts model ability to simulate realistic responses over Eurasia and the Indian Ocean. Similar biases
exist in the ECM responses. In addition, the relationships between upper and lower tropospheric wind responses to SST forcing
are not well reproduced by either model. The identification of these model biases leads to the conclusion that improvements
in convective heat and momentum transport parametrizations and basic climate simulations could substantially increase predictive
skill.
Received: 25 April 1996 / Accepted: 9 December 1996 相似文献
13.
Forecasting the equatorial Pacific sea surface temperatures by neural network models 总被引:2,自引:0,他引:2
We used neural network models to seasonally forecast the tropical Pacific sea surface temperature anomalies (SSTA) in the
Ni?o 3.4 region (6 °S–6 °N, 120 °W–170 °W). The inputs to the neural networks (i.e., the predictors) were the first seven wind stress empirical orthogonal function
(EOF) modes of the tropical Pacific (20 °S–20 °N, 120 °E–70 °W) for four seasons and the Ni?o 3.4 SSTA itself for the final season. The period of 1952–1981 was used for training the neural
network models, and the period 1982–1992 for forecast validation. At 6-month lead time, neural networks attained forecast
skills comparable to the other El Ni?o-Southern Oscillation (ENSO) models. Our results suggested that neural network models
were viable for ENSO forecasting even at longer lead times of 9 to 12 months. We hypothesized that at these longer leads,
the underlying relationship between the wind stress and Ni?o 3.4 SSTA became increasingly nonlinear. The neural network results
were interpreted in light of current theories, e.g., the role of the “off-equatorial” Rossby waves in triggering the onset
of an ENSO event and the delayed-oscillator theory in the development and termination of an ENSO event.
Received: 31 October 1995 / Accepted: 25 July 1996 相似文献
14.
本文对北半球多年月平均500毫巴图上60°N和30°N纬圈的高度和纬圈平均的经向运动动能进行了波谱分析,探讨了前3个波幅和位相角的季节变化,以及在高低纬度之间的差异。主要结果如下:1位势场的高度主要贡献,集中在准静止长波范围内,并具有明显的季节变化。2波数为1的波在高低纬度性质有显著的不同,其分界线大约在50°-60°N之间。此外,准静止的长波愈向低纬度去逐渐有向西偏移的现象。例如,在30°N上准静止的长波比60°N上要偏西(1/4)-(1/2)波长。360°N纬圈平均的经向运动动能主要部分亦集中在准静止长波范围内。虽然峰值有明显的季节变化,但最大的极值都出现在波数n=2-4之间。30°N纬圈平均的经向运动动能谱有着明显的季节变化,大致可分成如下3个类型:(1)冬季型:纬圈平均的经向运动动能谱存在着两个极值,最大的极值稳定于准静止长波范围内(n=3附近),次极植位于移动性行星波范围内(n=5-8)。(2)夏季型:纬圈平均的经向运动动能谱只有一个极值,稳定于波数为6-7的波内。(3)过渡型:纬圈平均的经向运动动能谱分布较平坦,没有稳定的极值存在。 相似文献
15.
R. Nieto L. Gimeno L. De la Torre P. Ribera D. Barriopedro R. García-Herrera A. Serrano A. Gordillo A. Redaño J. Lorente 《Meteorology and Atmospheric Physics》2007,96(1-2):85-101
Summary An earlier developed multidecadal database of Northern Hemisphere cut-off low systems (COLs), covering a 41 years period (from
1958 to 1998) is used to study COLs interannual variability in the European sector (25°–47.5° N, 50° W–40° E) and the major
factors controlling it. The study focus on the influence on COLs interannual variability, of larger scale phenomena such as
blocking events and other main circulation modes defined over the Euro-Atlantic region. It is shown that there is a very large
interannual variability in the COLs occurrence at the annual and seasonal scales, although without significant trends. The
influence of larger scale phenomena is seasonal dependent, with the positive phase of the NAO favoring autumn COL development,
while winter COL occurrence is mostly related to blocking events. During summer, the season when more COLs occur, no significant
influences were found. 相似文献
16.
Monthly sea surface temperature anomalies (SSTA) at near-global scale (60 °N–40 °S) and May to October rainfall amounts in
West Africa (16 °N–5 °N; 16 °W–16 °E) are first used to investigate the seasonal and interannual evolutions of their relationship.
It is shown that West African rainfall variability is associated with two types of oceanic changes: (1) a large-scale evolution
involving the two largest SSTA leading eigenmodes (16% of the total variance with stronger loadings in the equatorial and
southern oceans) related to the long-term (multiannual) component of rainfall variability mainly expressed in the Sudan–Sahel
region; and (2) a regional and seasonally coupled evolution of the meridional thermal gradient in the tropical Atlantic due
to the linear combination of the two largest SSTA modes in the Atlantic (11% with strong inverse loadings over the northern
and southern tropics) which is associated with the interannual and quasi-decadal components of regional rainfall in West Africa.
Linear regression and discriminant analyses provide evidence that the main July–September rainfall anomalies in Sudan–Sahel
can be detected with rather good skills using the leading (April–June) or synchronous (July–September) values of the four
main oceanic modes. In particular, the driest conditions over Sahel, more marked since the beginning of the 1970s, are specifically
linked to the warm phases of the two global modes and to cold/warm anomalies in the northern/southern tropical Atlantic. Idealized
but realistic SSTA patterns, obtained from some basic linear combinations of the four main oceanic modes appear sufficient
to generate quickly (from mid-July to the end of August) significant West African rainfall anomalies in model experiments,
consistent with the statistical results. The recent negative impact on West African rainfall exerted by the global oceanic
forcing is primarily due to the generation of subsidence anomalies in the mid-troposphere over West Africa. When an idealized
north to south SSTA gradient is added in the tropical Atlantic, strong north to south height gradients in the middle levels
appear. These limit the northward excursion of the rainbelt in West Africa: the Sahelian area experiences drier conditions
due to the additive effect (subsidence anomalies+latitudinal blocking) while over the Guinea regions wet conditions do not
significantly increase, since the subsidence anomalies and the blocking effect act here in opposite ways.
Received: 26 June 1997 / Accepted: 3 October 1997 相似文献
17.
冬季黑潮延伸体区域海表温度锋对北太平洋风暴轴的影响 总被引:2,自引:0,他引:2
利用NOAA最优插值逐日海表温度资料和NCEP/NCAR的逐日大气再分析资料,分析了冬季黑潮延伸体区域海表温度锋的变化及其对北太平洋风暴轴的影响。结果表明,冬季黑潮延伸体区域海表温度锋强度和纬度位置既存在年际变化,也存在年代际变化,且强度和位置的变化是相互独立的。冬季黑潮延伸体区域海表温度锋强度的年际变化对北太平洋风暴轴没有显著的影响,而其年代际变化则对北太平洋风暴轴具有非常显著的影响,当冬季海表温度锋偏强时,大气斜压性在鄂霍次克海及阿拉斯加附近区域上空增强,而在海表温度锋下游至东太平洋区域上空显著减弱,平均有效位能向涡动有效位能的斜压能量转换在45°N以北的太平洋区域上空有所增多,而在30°-45°N的太平洋区域上空有所减少,涡动有效位能向涡动动能的斜压能量转换在35°N以北的西太平洋区域以及45°N以北的东太平洋区域都显著增加,而仅在其南部边缘存在东西带状的减弱区域,导致40°N以北海区北太平洋风暴轴增强,40°N以南海区北太平洋风暴轴减弱,冬季海表温度锋偏弱时则有与之相反的结果。冬季黑潮延伸体区域海表温度锋纬度位置的变化对北太平洋风暴轴也存在较显著的影响,当海表温度锋位置偏北时,在其下游45°N以南的太平洋区域上空大气斜压性减弱,45°N以南的中东太平洋区域上空区域平均有效位能向涡动有效位能、以及涡动有效位能向涡动动能的斜压能量转换都减少;而在45°N以北的太平洋区域上空大气斜压性增强,在阿拉斯加湾附近上空尤其显著,在黑潮延伸体区域附近以及45°N以北的中东太平洋上空平均有效位能向涡动有效位能、以及涡动有效位能向涡动动能的斜压能量转换都显著增加,导致北太平洋风暴轴在其气候平均态轴线两侧呈现北正南负的偶极子形态;海表温度锋位置偏南时则有与之相反的结果。冬季黑潮延伸体区域海表温度锋强度和位置的变化均对北太平洋风暴轴具有显著的影响,其具体的物理机制还需要进一步的研究。 相似文献
18.
AMIP model simulations of the east China (5–50°N; 105–122°E) monsoon system are analyzed to study coherent relationships
between rainfall and wind annual cycle biases. A comparison with observed interannual variability patterns is carried out
to identify the physical processes that explain the biases. The analyses show that poleward displacement of the simulated
east Asian jet stream causes the ascending branch of the jet-induced transverse circulation to move north and, as a consequence,
produces negative (positive) rainfall biases occur in central (northeast) China. The model simulations show decreased southwesterly
flow and ITCZ rainfall over the South China Sea when weaker (versus observations) summer Hadley and Walker circulations are
present. This results from diminished model tropical disturbance activity, and highlights the importance of air-sea interactions.
In addition, during October–January, intensified model low-level easterlies enhance moisture transport and produce positive
local rainfall biases over central and northeast China. Biases in the east China monsoon system are concurrently reflected
in the planetary circulation. Enhanced northeast China rainfall results from increased surface pressure over the North Pacific
and an amplified zonal pressure gradient along the east China coast. This bias pattern is associated with differences in model
representations of topography. On the other hand, the South China Sea experiences an extensive elongated meridional rainfall
bias dipole structure that straddles the equator. This is accompanied by a baroclinic vertical pattern over the tropics as
well as a barotropic wave train that extends from Australia to the Antarctic, where the teleconnection is likely a direct
atmospheric response to tropical convective heating.
Received: 20 June 2000 / Accepted: 17 September 2000 相似文献
19.
ANALYSIS ON THE SOURCE AND SINK OF KINETIC ENERGY OF ATMOSPHERIC 30-60 DAY PERIOD OSCILLATION AND THE PROBABLE CAUSES* 
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下载免费PDF全文 Based on ECMWF daily grid point data in summer(May-August),1981,the distribution features of the source and sink of kinetic energy of atmosphere 30-60 day oscillation,including its horizontal distribution characteristics and its vertical structure characteristics,are investigated systematically with diagnostic analysis methods over a latitude belt between 80°N and 60°S.Also,the probable reasons for the existence of the source and sink of low frequency kinetic energy(LFKE) are discussed preliminarily.Results show that the horizontal distribution of the sources and sinks of kinetic energy of atmospheric 30-60 day oscillation is extremely different.The significant sources and sinks of LFKE mainly exist in the oceans and the coastal regions of continents or islands in the mid-high latitudes.It is also found that,in the vertical direction,the sources and sinks of kinetic energy of 30-60 day oscillation display barotropic structure in the mid-high latitudes of both hemispheres,but dispaly baroclinic structure in the equtorial region,and in the horizontal direction,the sources and sinks mainly display zonal wave-like distribution.The source and sink of LFKE are determinded by ageostrophic wind effect,frictional effect,interaction between sub-grid-scale systems,nonlinear interaction,and the flux-divergence of LFKE transported by transient wind.There are some regional reasons for the generation of sources and sinks which are not completely identical in different areas. 相似文献
20.
根据热带西太平洋(130°-160°E,10°-20°N)上空对流的年际变化,对表面温度、向外长波幅射、850 hPa纬向风进行了合成分析。合成分析结果表明,热带西太平洋上空的弱(强)对流对应着前冬和春季厄尔尼诺(拉尼娜)型的海温异常。与以前的研究结果进行了比较,说明上述海温异常的时空分布也与热带西太平洋和南海季风的爆发早晚相关联。合成分析结果还表明,热带西太平洋上空的弱(强)对流对应着从热带西太平洋向西伸展到盂加拉湾的东风(西风)异常。数值模拟也得到类似的结果。此外,在对流弱(强)的夏季,热带西太平洋上空的对流和南海低层纬向风均表现出弱(强)的季节演变特征。 相似文献