²áµî¤ÎCCSR¥»¥ß¥Ê¡¼ (2007ǯÅÙ)
2007ǯ4·î18Æü(¿å) 13:30 - 15:00
Hua Zhang (National Climate Center, Beijing; Professor)
- ¹Ö±éÂêÌÜ: The study of global radiative forcing due to black carbon aerosol
- ¾ì½ê: Áí¹ç¸¦µæÅï¡¡4¥»¥ó¥¿¡¼¶¦ÍÑ2³¬²ñµÄ¼¼ 270
- Í×»Ý:
Combining the global distributions of black carbon (BC) mass
concentration given by GADS (Global Aerosol Data Set), global
distributions of the direct radiative forcing due to BC have been
calculated with an improved radiative transfer model under clear sky
at both of winter and summer in this work.
The results show that the radiative forcing by BC is
positive at the tropopause and negative at the surface,
which is different from the positive radiative forcing of
greenhouse gases through the whole atmosphere.
The reason is explained theoretically in this work.
The global mean forcing value is 0.42 W/m2 for winter
and 0.23 W/m2 for summer at the tropopause,
while they are -1.45 W/m2 for winter and -0.81 W/m2
for summer at the surface.
Although the radiative forcing due to BC is highly dependent on
the optical properties of itself and its concentration in the atmosphere,
surface albedo and zenith angle also influence the forcing greatly.
It points out by this work that the absolute values of
radiative forcing due to BC at tropopause and at surface both increase
linearly with cosines values of zenith angle and surface albedo.
There is obvious change of the distribution of BC radiative forcing
with the latitude, the maximum value of it located in the north hemisphere
between 30~90¡ë both for winter and summer¡¤which shows that
anthropogenic activities are the main cause of BC radiative forcing.
I will report my work in CCSR on nonspherical ice cloud
parameterization for radiation model too.
2007ǯ4·î25Æü(¿å) 13:30 - 15:00
Qiang Fu (Department of Atmospheric Sciences, University of Washington; Professor)
- ¹Ö±éÂêÌÜ: Global warming seen from satellites
- ¾ì½ê: Áí¹ç¸¦µæÅï¡¡4¥»¥ó¥¿¡¼¶¦ÍÑ2³¬²ñµÄ¼¼ 270
- Í×»Ý:
Climate researchers for years has been struggling with an apparent
discrepancy in the data on global warming: Temperatures in the
troposphere
had apparently been rising far slower than models predicted, given how
fast the Earth's surface is heating (IPCC 2001). This discrepancy
has been central to the arguments of skeptics about global warming.
In this talk I will present recent debate and progresses to solve
this paradox in climate research (Fu et al. 2004, Nature) (this
subject has been highlighted in IPCC 2007 report). I will focus on
the changes of vertical structure of tropical tropospheric
temperatures (Fu and Johanson 2005, GRL), which has direct
implication to the climate feedback and changes of hydrological
cycle. I will also discuss the implications of tropospheric
temperature trends and their spatial patterns to the changes of
atmospheric circulations including the pole-ward shift of Hadley
circulations (Fu et al. 2006, Science) and the changes of Antarctic
climate (Johanson and Fu 2007, GRL).
2007ǯ5·î8Æü(²Ð) 13:30 - 15:00
ÂçÅç ·Ä°ìϺ (Ë̳¤Æ»Âç³ØÄã²¹²Ê³Ø¸¦µæ½ê; ½Ú¶µ¼ø)
- ¹Ö±éÂêÌÜ: ³¤É¹À¸»ºÎ̤Υ°¥í¡¼¥Ð¥ë¥Þ¥Ã¥Ô¥ó¥°
- ¾ì½ê: Áí¹ç¸¦µæÅï¡¡4¥»¥ó¥¿¡¼¶¦ÍÑ3³¬²ñµÄ¼¼ 320
- Í×»Ý:
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2007ǯ5·î17Æü(ÌÚ) 15:00 - 17:00
¸þ°æ ¿¿ÌÚ»Ò (ÅìµþÂç³Øµ¤¸õ¥·¥¹¥Æ¥à¸¦µæ¥»¥ó¥¿¡¼)
- ¹Ö±éÂêÌÜ: ¿ôÃÍÂç½Û´Ä¥â¥Ç¥ë¤òÍѤ¤¤¿¿Í°Ùµ¯¸»µ¤¸õÊÑÆ°Í×°ø¤¬µÚ¤Ü¤¹Å쥢¥¸¥¢°è¤ÎÊü¼Í¾ì¤È±À¾ì¤ËÂФ¹¤ë±Æ¶Áɾ²Á
- ¾ì½ê: Áí¹ç¸¦µæÅï¡¡4¥»¥ó¥¿¡¼¶¦ÍÑ2³¬²ñµÄ¼¼ 270
- Í×»Ý:
The economic growth due to the industrial revolution may influence the
climate change. In order to estimate the anthropogenic impact on the
climate, we investigated variations of radiation budget. Because
scattering and absorption of solar radiation by gases and aerosol
particles can change the amount of sunlight that reaches the ground,
the analysis of solar radiation at the surface has great importance for
the study of climate change. We would like to understand the relation
between human activity and climate change by investigating the change
of the radiation budget using surface observation data and model
simulations.
In this study, we used the aerosol transport model SPRINTARS [Takemura
et al., 2000, 2002, 2005]. This model is coupled with CCSR/NIES/FRCGC
Atmospheric General Circulation model and considers carbonaceous,
sulfate, mineral dust and sea salt aerosols from various emission
sources. Aerosol particles can influence the radiation budget, not only
directly by scattering and absorbing radiation but also indirectly by
changing the properties of cloud.
Observed data and model simulations show that the anthropogenic
aerosol increase caused a solar radiation decrease in the industrial
regions of Asia where economic is rapidly developing. Furthermore we
analyzed details of change in the dynamical cycle in this region using
model simulation and found that the surface temperature change caused
by aerosol affected clouds and precipitation. The aerosol impact is as
important as greenhouse gases impact. So, we should consider both
effects when estimating the anthropogenic impact on climate.
2007ǯ5·î25Æü(¶â) 13:30 - 15:00
Jong-Seong Kug (Seoul National Universiy)
- ¹Ö±éÂêÌÜ: Seasonal climate prediction with Ensemble Kalman Filte
- ¾ì½ê: Áí¹ç¸¦µæÅï¡¡4¥»¥ó¥¿¡¼¶¦ÍÑ2³¬²ñµÄ¼¼ 270
- Í×»Ý:
Ensemble Kalman Filter (EnKF) is a highly competent method to make
accurate and well-balanced initial condition for ensemble seasonal
climate prediction. In this study, new method is suggested how to
select ensemble perturbation in seasonal climate prediction with
Ensemble Kalman Filter (EnKF). A concept of the breeding method is
introduced to the EnKF procedure to make fast-growing initial
perturbation. That is, fast growing members and their mirror images
with opposite sign are selected as initial conditions in the ensemble
prediction. To test this idea, a hybrid coupled model is developed and
applied to El Nino prediction with EnKF initialization. With 12-month
lead forecast, forecast skills are compared between ensemble
predictions with random member selection (RM) and fast-growing member
selection (FM). It is demonstrated that the FM has significantly
higher predictive skill than the RM with most lead times. In
particular, the improvement is distinctive at 6-month lead time,
possibly related to a saturation time scale of the fast-growing error
growth. Also, it is demonstrated that the improvement of the FM is
larger where the signal to noise ration of the ensemble prediction is
smaller, indicating that the fast-growing initial perturbation is
effective where the prediction is sensitive to so-called the initial
uncertainty.
2007ǯ6·î1Æü(¶â) 13:30 - 15:00
Hugo Bellenger (Center for Climate System Research, The University of Tokyo)
- ¹Ö±éÂêÌÜ: The role of oceanic mixed layer and diurnal warm-layers in the atmospheric intraseasonal variability
- ¾ì½ê: Áí¹ç¸¦µæÅï¡¡4¥»¥ó¥¿¡¼¶¦ÍÑ2³¬²ñµÄ¼¼ 270
- Í×»Ý:
The air-sea interaction appears as a potentially important process for
the triggering and the evolution of intraseasonal variability (ISV) in
the tropics. In this context, the depth of the mixed layer is a basic
property that determines the reactivity of the surface temperature and
the amount of energy available for the atmosphere. Theoretical and
modelling studies showed that the ISV amplitude tends to maximize for
an optimal mixed layer depth of 20-30 meters (Sobel and Gildor, 2003;
Maloney and Sobel, 2004). This provides possible explanations for the
observed features of the seasonal evolution of 20-90 day intraseasonal
variability of the convection in the Indo-Pacific region: (i) a sharp
ISV maxima in May for the southern Bay of Bengal and in June for the
Eastern Arabian sea; (ii) maximum ISV over the West Pacific in
July-September when the ISV over northern Indian Ocean is weaker;
(iii) persistent ISV north of Australia from December to March; (iv)
weak ISV over continental regions. The source of these behaviors is
investigated from time series of satellite observations,
meteorological re-analysis and from an ocean mixed layer depth (MLD)
climatology. For the northern Indian Ocean regions, the ISV maximum
near the monsoon onset corresponds to shallow (20-30m) MLD and is
followed by the setting of strong low-level monsoon jet that cools and
deepens the MLD. The convective ISV is then smaller during the core of
the monsoon as the MLD attains 60-70m. The other regions do neither
experience such a low-level wind increase nor a MLD deepening and
there is a more uniformly strong ISV throughout the rainy season. The
seasonal variability of MLD, which is partly linked with the monsoon
low-level jet variability gives thus a link between the seasonal march
of the monsoon and the seasonal evolution of the ISV. This has
implications for a better understanding of the origin of the ISV and
for the predictability of its amplitude, especially near the monsoon
onset date.
In addition to this basic process, the SST may also be strongly
modulated at the diurnal time scale because of the absorption of solar
radiation by the upper ocean levels under light surface wind
conditions. These diurnal warm-layers may form during the convectively
suppressed phase of an intraseasonal event and increase even the
diurnal average surface temperature. This is because the nighttimes
SST is close to the mixed layer temperature while the noon SST can be
increased by up to 5K. This higher SST will modify the air-sea
exchanges and the boundary layer instability. These warm-layers
disappear as soon as the wind increases in association with a
large-scale convective perturbation. Warm-layers organised at
large-scale thus increase the amplitude of the intraseasonal SST
modulation and may even trigger ISV events. To address the role of
warm-layers in ISV, a daily dataset of SST diurnal amplitude in the
tropics is produced using COARE 3 (Fairall et al, 1996) algorithm
forced by ERA-40 reanalysis. The results are validated using the
global SVP drifter dataset and empiric relations from earlier
studies. An important result is that warm layers tend to develop in
region where the ISV is strong, confirming their potential role in the
ISV amplitude. For moderate to strong warm layers (diurnal amplitude >
1K), the horizontal extension is between 1000 and 4000 km during
periods of several days in agreement with the typical size of ISV
perturbations. These results finally validate the use of the COARE 3
algorithm forced with surface fluxes at a horizontal scale typical of
atmospheric general circulation model. In addition, this method gives
an estimate of the warm layer depth and temperature at each physical
time scale, making it usable as a parameterization. The implementation
of this warm layer parameterization in the LMD GCM is further tested
and its impact on the representation of the ISV in the model will be
presented.
Fairall C. W., E. F. Bradley, J. S. Godfrey, G. A. Wick, J. B. Edson, and G. S. Young, 1996: Cool-skin and warm-layer effects on sea surface temperature. J. Geophys. Res, 101, 1295?1308.
Maloney, E. D., and A. H. Sobel, 2004: Surface fluxes and ocean coupling in the tropical intraseasonal oscillation, J. Clim., 17, 4368-4386.
Sobel, A. H., and H. Gildor, 2003: A simple time-dependent model of SST hot spots. J. Clim., 16, 3978-3992.
2007ǯ6·î8Æü(¶â) 13:30 - 15:00
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- ¹Ö±éÂêÌÜ: É÷±þÎϤˤè¤Ã¤Æ³¤ÍÎÃæ¤ËÎ嵯¤µ¤ì¤ëÍðήº®¹ç¤Ë´Ø¤¹¤ë¥¨¥Í¥ë¥®¡¼ÏÀŪ¹Í»¡
- ¾ì½ê: Áí¹ç¸¦µæÅï¡¡4¥»¥ó¥¿¡¼¶¦ÍÑ2³¬²ñµÄ¼¼ 270
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2007ǯ6·î15Æü(¶â) 13:30 - 15:00
°æ¾å Ë»ÖϺ (ÅìµþÂç³Øµ¤¸õ¥·¥¹¥Æ¥à¸¦µæ¥»¥ó¥¿¡¼; ÆÃǤ¶µ°÷)
- ¹Ö±éÂêÌÜ: Application of split window data
- ¾ì½ê: Áí¹ç¸¦µæÅï¡¡4¥»¥ó¥¿¡¼¶¦ÍÑ2³¬²ñµÄ¼¼ 270
- Í×»Ý:
The 11mm and 12mm channels on board meteorological satellite are
called as ¡Æsplit window¡Ç. The absorption by water vapor is slightly
different between the two wavelengths. An algorithm to retrieve sea
surface temperature (SST) was proposed in early 70s, utilizing this
differential absorption. The split window channel was just constructed
for the purpose of retrieving accurate SST, and was on board NOAA-7
polar orbiting satellite.
Inoue (1985) found the differential absorption by ice for the split
window. He developed a method to classify cloud type objectively
including cirrus cloud which had been hard to classify objectively
from single infrared data. Further, total precipitable water (TPW) can
be retrieved from the split window over cloud free ocean area. Thus,
we can retrieve SST and TPW over the clear ocean area and can retrieve
cloud parameters over cloudy area, with the use of the split
window. Using this split window, some results on cloud type
classification, lifecycle of deep convection, monsoon etc will be
introduced in my talk.
2007ǯ6·î29Æü(¶â) 13:30 - 15:00
°ÂÃæ ¤µ¤ä¤« (ÅìµþÂç³Øµ¤¸õ¥·¥¹¥Æ¥à¸¦µæ¥»¥ó¥¿¡¼)
- ¹Ö±éÂêÌÜ: Á´µå³¤ÌÌ¿å²¹¾ì¤Ë¸«¤é¤ì¤ë¥ì¥¸¡¼¥à¥·¥Õ¥È
- ¾ì½ê: Áí¹ç¸¦µæÅï¡¡4¥»¥ó¥¿¡¼¶¦ÍÑ2³¬²ñµÄ¼¼ 270
- Í×»Ý:
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2007ǯ7·î27Æü(¶â) 10:15 - 12:00
Par Nyberg (Cray Inc.; Director, Marketing and Business Development¡¡Earth Sciences Segment)
- ¹Ö±éÂêÌÜ: Update on Cray Earth Sciences Segment Activities
- ¾ì½ê: Áí¹ç¸¦µæÅï¡¡4¥»¥ó¥¿¡¼¶¦ÍÑ3³¬²ñµÄ¼¼ 320
- Í×»Ý:
[Topics]
¡¦Situation Analysis
¡¦Petascale Ambitions:
National/Regional Projects;
CCSM Petascale Experiment
¡¦Cray Corporate Update
¡¦Cray Product Update
¡¦Cray Earth Sciences Segment Update:
General Overview;
Porting to an MPP System;
Application Performance;
[Profile]
Per Nyberg is the Marketing and Business Development Director for the
Earth Sciences Segment at Cray Inc. Since joining the company in
2002, Mr. Nyberg has been responsible for Cray's worldwide strategic
planning, business development and marketing for the earth sciences
segment working extensively with many weather and climate centers
worldwide. Prior to joining Cray, he worked for 12 years in NEC
Corp's high performance computing business in Canada, United States
and Australia, in roles ranging from software engineering to business
development.
2007ǯ7·î27Æü(¶â) 13:30 - 15:00
Yongxiang Hu (NASA Langley Research Center)
- ¹Ö±éÂêÌÜ: Ocean studies using CALIPSO surface and sub-surface lidar return
- ¾ì½ê: Áí¹ç¸¦µæÅï¡¡4¥»¥ó¥¿¡¼¶¦ÍÑ2³¬²ñµÄ¼¼ 270
- Í×»Ý:
At 532nm wavelength, CALIPSO's lidar has the potential to receive photons
backscattered from ocean sub-surface.
1. Can the lidar separate photo-multiplier-detector-delayed surface
returns from the true ocean sub-surface returns?
2. How deep can we profile the ocean sub-surface backscatter?
3. How well are the CALIPSO sub-surface return correlated with Aqua/MODIS ocean color?
4. Can we derive ocean surface wind from the lidar surface return?
5. Any chance of figuring out ocean mixed-layer depth?
6. Can we use CALIPSO for Bathymetry studies?
This talk will summarize our recent studies regarding these topics, as well
as initial results on ocean-ecosystem, aerosol and climate feedbacks.
2007ǯ8·î2Æü(ÌÚ) 14:00 - 15:30
Richard Wood (Hadley Center, UK)
- ¹Ö±éÂêÌÜ: Towards a traceable model hierarchy to assess the stability of the Atlantic thermohaline circulation
- ¾ì½ê: Áí¹ç¸¦µæÅï¡¡4¥»¥ó¥¿¡¼¶¦ÍÑ2³¬²ñµÄ¼¼ 270
2007ǯ8·î9Æü(ÌÚ) 16:00 - 17:30
Byung-Ju Sohn (Seoul National University; Professor)
- ¹Ö±éÂêÌÜ: Variation of upper tropospheric humidity and its relations to convective activities over the tropics.
- ¾ì½ê: Áí¹ç¸¦µæÅï¡¡4¥»¥ó¥¿¡¼¶¦ÍÑ2³¬²ñµÄ¼¼ 320
- Í×»Ý:
In this seminar, I like first to introduce recent studies on the
diurnal diurnal variations of upper tropospheric humidity (UTH) as
well as middle tropospheric humidity (MTH) in conjunction with the
diurnal cycle of convection over tropical Africa using European
Meteosat-8 measurements. Diurnal variations of humidity and clouds
were examined in both the convectional Eulerian framework as well as
the Lagrangian framework.
Some of interesting findings are as follow:
* The diurnal variation of UTH tends to reach a maximum during
nighttime over land, lagging deep convection and high cloud whose
maxima occurred in the late afternoon and evening, respectively.
* Diurnal variations over the African continent are likely associated
with continental-scale daytime solar heating and topography.
* Topographically-induced signals develop earlier around the
mid-afternoon and merge into stronger and broader continental-scale
convection clusters later, forming a precipitation maximum in the
late afternoon.
* Advection effect on the diurnal variation appears to be insignificant.
In addition I like to discuss physical properties of the "warm water
vapor" pixels shown in the geostationary satellite, and their possible
use for a better understanding of the atmospheric phenomena in the TTL
altitudes.
2007ǯ10·î1Æü(·î) 10:30 - 12:00
²ÃÆ£ À¿»Ê (NASA Langley Research Center)
- ¹Ö±éÂêÌÜ: Clouds and the Earth Radiant Energy System (CERES) ¤Î¥Ç¡¼¥¿¤Ë¤è¤Ã¤Æ¸«ÀѤâ¤é¤ì¤¿Á´µåÊü¼Í¼ý»Ù
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2007ǯ10·î5Æü(¶â) 13:30 - 15:00
Johnny Chan (City University of Hong Kong)
- ¹Ö±éÂêÌÜ: (1) Brief introduction of atmospheric research at City University of Hong Kong
- ¾ì½ê: Áí¹ç¸¦µæÅï¡¡4¥»¥ó¥¿¡¼¶¦ÍÑ2³¬²ñµÄ¼¼ 270
- Í×»Ý:
This seminar will be divided into two parts.
The first part gives an introduction of the research in meteorology
and climate we are conducting at City University of Hong Kong that
may be of interest to CCSR.
The second part is some recent work examining the question of whether
global warming will lead to more intense typhoons. The frequency of
intense typhoon (Category 4 and 5 in the Saffir-Simpson scale)
occurrence for the period 1960-2005 in the western North Pacific
(WNP) at decadal time scales is analyzed. It is found that in the
southeastern part of the WNP, during periods with above-normal
frequency of intense typhoon occurrences, the thermodynamic
conditions are more conducive to the development of tropical
cyclones. As these cyclones move northwestward, the favorable
dynamic conditions continue to be present so that they can intensify
further. The steering flow ensures many of these typhoons will stay
over water for an extended period of time through low-latitude
recurvature. As a result, they can intensify to become Category 4 or
5 typhoons. The conditions during the below-normal periods are
generally opposite.
A major conclusion from the results of this study is that the
frequency of intense typhoon occurrence does not exhibit a linear
increasing trend. Rather, it undergoes a strong multi-decadal
variability due to similar variations in the planetary-scale
oceanographic and atmospheric conditions that govern the formation,
intensification and movement of tropical cyclones.
2007ǯ10·î5Æü(¶â) 15:30 - 17:00
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- ¾ì½ê: Áí¹ç¸¦µæÅï¡¡4¥»¥ó¥¿¡¼¶¦ÍÑ2³¬²ñµÄ¼¼ 270
2007ǯ10·î29Æü(·î) 16:30 - 18:00
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2007ǯ11·î9Æü(¶â) 13:30 - 15:00
Akira Kasahara (NCAR)
- ¹Ö±éÂêÌÜ: Dynamical formulation of the next-generation earth system model for climate and weather predictio
- ¾ì½ê: Áí¹ç¸¦µæÅï¡¡4¥»¥ó¥¿¡¼¶¦ÍÑ2³¬²ñµÄ¼¼ 270
- Í×»Ý:
A recent achievement of climate modelers in contributing to convince
the public that human activities are affecting climate is well-known,
but only few know that current climate models adopt the hydrostatic
primitive equations which have two major dynamical simplifications,
called the ¡Èshallowness¡É and ¡Ètraditional¡É approximations. These
approximations may produce more than few-percent errors in the
dynamics. In light of our interest in finding the change in climate
due to such minute effects of increasing greenhouse gases in the
atmosphere, for the design of next-generation earth system model, it
is desirable to eliminate these dynamical approximations. This talk
will focus on understanding the nature of the traditional
approximation (TA) that neglects the Coriolis terms proportional to
Cosine of the latitude.
I will first give a historical review on the justification of TA which
has been ¡Èrather confusing¡É as Norman Phillips wrote in 1966. A
renewed interest in questioning the wisdom of TA has revived in the
last ten years or so due to an effort to improve the fidelity of the
models for weather and climate. I will then summarize recent findings
on the role of Cos-Coriolis terms. Without the TA, the axis of
rotation is no longer parallel with the gravity, except at the
poles. This reality together with the influence of vertical boundary
creates little-known inertio-gravity modes in addition to the
traditional ones. In other words, with the TA the accuracy of
inertio-gravity motions is compromised. Lastly, I will propose a
dynamical framework of future earth system model using unified radial
coordinates for the atmosphere and hydrosphere with only one minor
assumption that the geopotential of the earth is a sphere.
2007ǯ11·î13Æü(²Ð) 13:30 - 15:00
Simon Alexander (µþÅÔÂç³ØÀ¸Â¸·÷¸¦µæ½ê)
- ¹Ö±éÂêÌÜ: Global and Regional scale studies of Stratospheric Gravity Waves using COSMIC GPS Radio Occultation
- ¾ì½ê: Áí¹ç¸¦µæÅï¡¡4¥»¥ó¥¿¡¼¶¦ÍÑ2³¬²ñµÄ¼¼ 270
- Í×»Ý:
Gravity waves are mainly generated in the lower atmosphere and
propagate upwards, transporting energy and momentum. They must be
characterized and parameterized in models because their cumulative
effect on the atmosphere is important. GPS Radio Occultation
satellites are able to measure the temporal and spatial evolution of
gravity waves with global coverage. The new COSMIC GPS-RO satellites
enable study of gravity waves at much higher resolution than was
previously possible. Results showing wave sources and propagation
will be discussed. The large winter-time Japanese stratospheric
gravity wave energy will be quantified and compared with previous
observations. Tropical convectively generated waves and their
interaction with the changing background wind conditions will also be
discussed.
2007ǯ11·î16Æü(¶â) 13:30 - 15:00
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- ¾ì½ê: Áí¹ç¸¦µæÅï¡¡4¥»¥ó¥¿¡¼¶¦ÍÑ2³¬²ñµÄ¼¼ 270
- Í×»Ý:
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2007ǯ11·î26Æü(·î) 13:30 - 15:00
Adam H. Sobel (Columbia University)
- ¹Ö±éÂêÌÜ: Surface fluxes and intraseasonal variability
- ¾ì½ê: Áí¹ç¸¦µæÅï¡¡4¥»¥ó¥¿¡¼¶¦ÍÑ2³¬²ñµÄ¼¼ 270
- Í×»Ý:
The observed spatial distribution of intraseasonal variance in
precipitation and outgoing longwave radiation is highly structured,
with large variance over the tropical oceans and substantially smaller
variance over land. The land-ocean difference is manifest in both
Northern and Southern hemispheres and all seasons, and is apparent
even at small scales, with substantial gradients in variance across
coastlines. Dynamically, the primary difference between land and ocean
is that there can be no variations in total surface energy flux over
land, while there can be substantial variations over ocean. The
authors thus argue that the observed distribution of intraseasonal
variance is evidence that interactive variations in the total surface
energy flux play an important role in the dynamics of tropical
intraseasonal variability.
Interactive surface fluxes are essential to the dynamics of
intraseasonal variability in some idealized models, both of the
eastward-propagating MJO and the northward propagating variations of the
Asian monsoon. By no means do all idealized models exhibit such
behavior, however. In general circulation models, it is straightforward
to estimate the importance of interactive surface fluxes. Such
sensitivity tests have been done in only a small number of models, with
inconsistent results. The authors suggest that it would be useful to
know the importance of surface fluxes to intraseasonal variability in a
larger number of models. This knowledge might provide some insight into
the relevance of interactive surface fluxes to intraseasonal variability
in nature, thus making it possible to rule out some theoretical
explanations of intraseasonal variability (either those in which surface
fluxes are crucial, or those in which they are not).
2007ǯ11·î27Æü(²Ð) 13:00 - 14:00
Adam H. Sobel (Columbia University)
- ¹Ö±éÂêÌÜ: Some tests of our understanding of what controls tropical cyclone statistics
- ¾ì½ê: Áí¹ç¸¦µæÅï¡¡4¥»¥ó¥¿¡¼¶¦ÍÑ2³¬²ñµÄ¼¼ 270
- Í×»Ý:
What controls the statistics of tropical cyclones? We know that
variations in the large-scale environment influence the number of storms
in a season, their tracks, and their intensities. Our understanding of
these different aspects varies. For intensity, we have at least a
partial physical theory, potential intensity theory. For the probability
of genesis, which influences storm number, we have no such theory, but
we do have empiricial indices which capture at least some understanding
of the process.
I will present a couple of different pieces of work which use
observations to test some aspects of our current understanding of what
controls TC statistics. I will show that interannual variations in the
maximum intensities reached by TCs in the north Atlantic and western
north Pacific are, within the uncertainties imposed by the best track
data, consistent with potential intensity theory. I will also show that
a genesis potential index recently developed by Emanuel and Nolan gives
a good prediction of interannual TC number variations in most basins
associated with ENSO. This is a real test of the index, as it was
trained only on climatology, with no knowledge of interannual
variations. The index then allows the variations to be attributed to
particular physical factors, e.g. there are fewer storms in the Atlantic
during El Nino years because of increased vertical shear.
2007ǯ11·î28Æü(¿å) 10:30 - 12:00
Yuqing Wang (International Pacific Research Center, University of Hawaii)
- ¹Ö±éÂêÌÜ: The IPRC Regional Coupled Ocean Atmospheric Model (iROAM) and Its Application to Eastern Pacific Climate Process Studies
- ¾ì½ê: Áí¹ç¸¦µæÅï¡¡4¥»¥ó¥¿¡¼¶¦ÍÑ2³¬²ñµÄ¼¼ 270
- Í×»Ý:
A regional coupled ocean-atmospheric model (iROAM) has been developed
at the International Pacific Research Center, University of Hawaii,
and now is running on Earth Simulator at the Earth Simulator Center,
Japan. The iROAM has its atmospheric component of the IPRC regional
climate model (IPRC-RegCM) and its ocean component of MOM2. The
IPRC-RegCM has its strength in simulating stratocumulus clouds over
the Southeast Pacific and the active cloud-radiation feedback
processes. The coupled model IROAM therefore is an ideal to the study
of cloud-ocean-atmospheric interaction over the eastern Pacific and
other tropical oceans. In this talk, we will first introduce the
coupled model followed by some preliminary results from the model
simulation of the mean eastern Pacific climate and the seasonal cycle,
together with a briefing of our current research project using the
iROAM at IPRC.
2007ǯ11·î29Æü(ÌÚ) 14:30-17:30
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2007ǯ11·î30Æü(¶â) 13:30 - 15:00
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- ¾ì½ê: Áí¹ç¸¦µæÅï¡¡4¥»¥ó¥¿¡¼¶¦ÍÑ2³¬²ñµÄ¼¼ 270
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2007ǯ12·î7Æü(¶â) 10:00-12:00 (270¹æ¼¼) CCSR Symposium on the Climate Modeling
- 10:00-10:40 David Randall (Department of Atmospheric Science, Colorado State University)
Analysis of the Madden-Julian Oscillation Simulated by the MMF
- 10:40-11:20 Herve Le Treut (Laboratoire de Meteorologie Dynamique du CNRS)
Analysis of physical, dynamical or biochemical feedbacks in the IPSL simulations of future climate change
- 11:20-12:00 William K. M. Lau (Laboratory for Atmospheres, NASA/Goddard Space Flight Center)
Aerosol-monsoon water cycle interaction: A new challenge to climate change research
2007ǯ12·î7Æü(¶â) 13:00 - 15:00
Shian-Jiann Lin (NOAA/Geophysical Fluid Dynamics Laboratory)
- ¹Ö±éÂêÌÜ: Yin and Yang of global modeling
- ¾ì½ê: Áí¹ç¸¦µæÅï¡¡4¥»¥ó¥¿¡¼¶¦ÍÑ2³¬²ñµÄ¼¼ 270
- Í×»Ý:
A philosophical and introductory overview of issues and challenges of
global ultra high-resolution weather-climate modeling will be
given. These issues include the choice of griding system on the whole
sphere, staggering of prognostic variables, discretization of the
physical conservation laws, and (controversial) choices of physical
parameterizations for various horizontal resolutions. From
convectional approach to bold and innovative new methodologies, what
is the best compromise between the "Yin" and "Yang" extremes?
2007ǯ12·î7Æü(¶â) 13:00 - 15:00
Jin-Luen Lee (NOAA)
- ¹Ö±éÂêÌÜ: A finite-volume icosahedral SWM on local coordinate
- ¾ì½ê: Áí¹ç¸¦µæÅï¡¡4¥»¥ó¥¿¡¼¶¦ÍÑ2³¬²ñµÄ¼¼ 270
- Í×»Ý:
In recent years, a new type of icosahedral geodesic spherical grid
consists of hexagon grid points with 12 pentagons is used for
discretization of geophysical fluid dynamic equations for grid-point
global models. We develop an icosahedral shallow water model (SWM)
formulated on a local coordinate and solved with a finite-volume
conservation scheme. Each Icosahedral cell is treated as a control
volume projected onto a local general stereographic coordinate. The
local projection, unique for each Icosahedral cell, provides
orthogonal Cartesian coordinate that greatly simplifies the
formulation of spherical operators such as the vorticity, divergence
and pressure gradient solvers. Model variables are defined at a
non-staggered Icosahedral grid and Vandermonde interpolation is used
to estimate variables at cellular edges for fluxes computation. The
prognostic momentum and continuity equations are solved with the
explicit 3rd order Adam-Bashforth time differencing scheme. The
monotonicity of the advection scheme is achieved by extending the
original Zalesak (1979) flux correction transportation (FCT) scheme
into multiple time level for the 3rd order Adam-Bashforth scheme. The
local icosahedral SWM is evaluated with the standard tests of
Williamson et. al.(1992) for shallow water models on the sphere.
2007ǯ12·î14Æü(¶â) 13:30 - 15:30
Ronghui Huang (Institute of Atmospheric Physics, Chinese Academy of Sciences; Prof.)
- ¹Ö±éÂêÌÜ: Characteristics of the Interannual Variability of East Asian Summer Monsoon System and Their Relation to the Thermal State of Tropical Western Pacific
- ¾ì½ê: Áí¹ç¸¦µæÅï¡¡4¥»¥ó¥¿¡¼¶¦ÍÑ2³¬²ñµÄ¼¼ 270
- Í×»Ý:
The observed data of precipitation in 160 observational stations of
China, the NCEP/NCAR and ERA-40 reanalysis data and the Empirical
Orthogonal Founction (EOF) and the Entropy spectral analysis methods
are applied to analyze the interannual variations of summer
(June-August) rainfall in China and water vapor transport fluxes over
East Asia. The results show that there is an obvious oscillation with
a period of two or three years, i.e., the quasi-biennial oscillation,
in the interannual variations of summer monsoon rainfall in China,
especially in the eastern and southern parts of China including South
China, the Yangtze River valley and the Huaihe River valley and North
China. Additionally, the spatial distributions of EOF1 of summer
monsoon rainfall in China and water vapor transports over East and
Northeast Asia are similar in exhibiting a meridional tripole
pattern. And it is also shown that this oscillation is closely
associated with the quasi-biennial oscillation in the interannual
variations of the water vapor transport fluxes by summer monsoon flow
over East Asia. Furthermore, the interannual variations of sea
temperature in the surface and subsurface of tropical western Pacific
are analyzed by using the sea surface temperature (SST) data of the
NCEP/NCAR reanalysis dataset and the sea temperature in the subsurface
of the West Pacific along 137¡ëE, JMA, respectively. And it is
revealed that there is also an significant quasi-biennial oscillation
in the interannual variations of thermal state of the tropical western
Pacific. In this paper, the correlative and composite analysis methods
are applied to discuss the influence of the quasi-biennial oscillation
of thermal state of the tropical western Pacific on the East Asian
summer monsoon and water vapor transports over East Asia, and it is
shown that the quasi-biennial oscillation in the interannual
variations of thermal state of the tropical western Pacific has a
great impact on the East Asian summer monsoon system and the water
vapor transport driven by the monsoon flow. Besides, the influence of
the quasi-biennial oscillation with a meridional tripole pattern
distribution in the interannual variations of thermal state of the
tropical western Pacific on the quasi-biennual oscillation in the
interannual variations of the East Asian summer monsoon is simply
discussed by using the teleconnection theory of the East Asia/Pacific
pattern suggested by Nitta (1987), and Huang and Li (1987,1988).
2007¥Ì¥Ã12¥4¥Ë¥« 13:30 - 15:30
Wen Chen (Institute of Atmospheric Physics, Chinese Academy of Sciences; Prof.)
- ¥±¥è¥¢òÄôÎ¥ï: Relationship between Stationary Planetary Wave Activity and the East Asian Winter Monsoon
- ¥»ø¿ ¥Áú»îº¥ò¥ªìÇþ£¡£4¡¦¥µ¡¦¿¡¼¶¦Í³¬²ñµÄ¼¼ 270
- Í×»Ý:
The variability of both the stationary planetary wave activity and the
East Asian winter monsoon is strongly associated with the thermal
contrast between oceans and land masses. In this talk, we explore the
relationship between the wave activity and the monsoon, with a focus
on interannaul timescales. It is found that, compared to the winters
of low wave activity, the equatorward propagation of planetary waves
in the middle and upper troposphere is stronger in the high wave
activity winters. During these high activity winters, the upward wave
propagation from the troposphere into the stratosphere becomes
weaker. This is accompanied by a smaller perturbation in the polar
vortex, which tends to be colder and stronger. In the meantime, the
East Asian westerly jet stream, the East Asian trough, the Siberian
high, and the Aleutian low all become weaker apparently. In
particular, the weakening of the Siberian high and the Aleutian low
decreases the northeasterly wind over East Asia, leading to a warming
condition in the region especially in northeastern Asia. A further
analysis reveals that the zonal wavenumber-2 pattern of planetary
waves contributes dominantly to the variability of the East Asian
winter monsoon.
We will also show that above-mentioned relationship is modulated by
the tropical quasi-biennial oscillation (QBO) wind in the
stratosphere. In the QBO easterly phase, a significant warming appears
in northeastern Asia in the presence of high wave activities. This
corresponds to a weakened East Asian trough at 500-hPa, which
determines the extent to which cold waves penetrate into East
Asia. However, in the QBO westerly phase, both the surface warming and
the weakening of the East Asian trough become insignificant in
response to high wave activities. The possible mechanism for this QBO
modulation on the tropospheric wave activities may be attributed to
the indirect influence of the QBO induced polar and extratropical
stratospheric circulation changes. Under the QBO easterly phase
conditions, the tropospheric wave activity flux divergence in the
higher-latitude region is enhanced due to enhanced upward EP flux into
the stratosphere, while the wave flux convergence in the subtropical
troposphere is increased due to the decrease in the equatorward
flux. This leads to an enhanced wave activity difference and thus the
associated East Asian climate anomalies become larger and robust. An
opposite effect (i.e., reduced wave activity difference) appears in
the QBO westerly phase. Further analyses reveal that the QBO
significantly modulates both the zonal wavenumber 1 and 2 in the sea
level pressure field but not for wavenumber 3. The combination of
wavenumber 1 and 2 patterns leads to the strongest surface temperature
anomalies in northern Asia.
2007ǯ12·î19Æü(¿å) 10:00 - 11:30
Meiyun Lin (ÅìµþÂç³Øµ¤¸õ¥·¥¹¥Æ¥à¸¦µæ¥»¥ó¥¿¡¼)
- ¹Ö±éÂêÌÜ: Long-range Transport and Source-receptor Relationships of Acidifying Substances in East Asia
- ¾ì½ê: Áí¹ç¸¦µæÅï¡¡4¥»¥ó¥¿¡¼¶¦ÍÑ2³¬²ñµÄ¼¼ 270
- Í×»Ý:
This study examines and quantifies long-range transport of acidifying
substances in East Asia. The three-dimensional (3-D) Community
Multiscale Air Quality (CMAQ) model is applied for this purpose with a
coarse-grid and a nested finegrid. The global Model for Ozone and
Related Chemical Tracers (MOZART) is coupled to provide boundary
conditions for the regional simulation with CMAQ. A comprehensive
evaluation for CMAQ annual predictions is conducted with surface and
satellite measurements. Comparison with the EANET surface monitoring
network shows that the model successfully reproduces the magnitudes,
daily, and diurnal variations of SO2 mixing ratios at most sites. With
tropospheric NO2 columns from the GOME satellite instrument, the model
is shown to be able to capture major spatial and seasonal variations
of NO2 observed from space over large area of East Asia. The
magnitudes of GOME NO2 retrieval in winter, however, are
underpredicted by a factor of 2 over industrial area of eastern
China. Our sensitivity studies found that emission estimates from
anthropogenic sources should be increased by 50% over central east
China and 20-30% over central Japan to reconcile the model results for
NO2 with the observations during the spring and winter of
2001. Analysis of seasonal cycle of surface suggests that the
implementation of boundary conditions derived from the MOZART global
atmospheric chemistry model, largely improves O3 predictions. The
summer-time O3 prediction in central east China and central Japan is
highly sensitive to the photochemical mechanisms applied in CMAQ. The
CBIV mechanism with 27-km and 81-km grid spacing well reproduces the
observed surface O3 at most EANET sites. The SAPRC99 mechanism tends
to overpredict summer O3 especially on low O3 days near central Japan.
The complex 3-D Eulerian model CMAQ and related components newly
developed in this study are applied, for the first time, to quantify
region-to-region source-receptor relationships (SRRs) for both sulfur
and reactive nitrogen in East Asia. We proposed a source region
attribution methodology by analyzing the non-linear responses of the
Eulerian model to emission changes. The transboundary influence
exhibits strong seasonal variation and is generally peak during the
dry seasons, reflecting the Asian monsoon circulation. Long-range
transport from central eastern China contributes a significant
percentage (>20%) of anthropogenic sulfur deposition as well as
reactive nitrogen deposition throughout East Asia. At the same time,
northwestern China receives approximately 35% of its sulfur load and
45% of its nitrogen load from foreign emissions, mainly from the
Indian subcontinent. Volcanic sources, including emissions from
Miyakejima volcano in 2001, contribute approximately 50% of the total
sulfur deposition in Japan. Sulfur inflows from regions outside the
study domain, which is attributed by using boundary conditions derived
from the MOZART global atmospheric chemistry model, are pronounced
(10-40%) over most parts of Asia. Compared with previous studies using
simple Lagrangian models, the results derived in this study indicate
higher influence from long-range transport. The estimated
source-receptor relationships are believed to be more realistic since
they include global influence as well as internal interactions among
different parts of China.
2007ǯ12·î26Æü(¿å)¸á¸å ½¤»ÎÏÀʸ Äó½ÐľÁ°È¯É½²ñ
2007ǯ12·î27Æü(ÌÚ)¸á¸å ½¤»ÎÏÀʸ Äó½ÐľÁ°È¯É½²ñ
2008ǯ1·î15Æü(²Ð) 13:30 - 15:00
Toshiaki Shinoda (Naval Research Laboratory)
- ¹Ö±éÂêÌÜ: Upper ocean response to the Madden-Julian oscillation
- ¾ì½ê: Áí¹ç¸¦µæÅï¡¡4¥»¥ó¥¿¡¼¶¦ÍÑ2³¬²ñµÄ¼¼ 270
- Í×»Ý:
The Madden-Julian Oscillation (MJO) is the dominant component of
atmospheric intraseasonal (30-90 days) variability in the tropics. In
the tropical Indian and western Pacific warm pool region, convection
and wind anomalies associated with the MJO propagate eastward at ~5
m/s, which produces significant anomalies of surface fluxes on the
intraseasonal time scale. In recent years, the upper ocean response to
the MJO has been intensively studied because of its importance for
air-sea feedback processes associated with the MJO and its possible
influence on longer time-scale variability. The first part of this
seminar provides an overview of oceanic response to the MJO that
includes observations and modeling of intraseasonal SST variability in
the warm pool and rectified response which could affect interannual
variability such as ENSO.
The second part of this seminar focuses on our recent work related to
intraseasonal Kelvin waves produced by the MJO using ocean general
circulation model (OGCM) experiments. Previous observational work has
demonstrated that the phase speed of oceanic equatorial Kelvin waves
forced by the Madden-Julian oscillation (MJO) appears to vary
substantially. Processes that are responsible for systematic changes
in the phase speed of these waves are examined using an OGCM. The
model is able to reproduce observed systematic changes of Kelvin wave
phase speed reasonably well, providing a tool for the analysis of
their dynamics. The relative importance of the upper ocean background
state and atmospheric forcing for phase speed changes is determined
based on a series of additional model experiments with various surface
forcings.
2008ǯ2·î4Æü(·î) 16:30 - 18:00
ËöµÈ ůͺ (ËÌÂçÄã²¹¸¦)
- ¹Ö±éÂêÌÜ: ÅàÅÚÃÏÂӤؤβ¹ÃȲ½±Æ¶Á¤È¤½¤Î¥â¥Ç¥ê¥ó¥°¤Ë¤Ä¤¤¤Æ
- ¾ì½ê: Áí¹ç¸¦µæÅï¡¡4¥»¥ó¥¿¡¼¶¦ÍÑ2³¬²ñµÄ¼¼ 270
- Í×»Ý:
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¤È¤Ï½ÅÍפǤ¢¤ë¡£Ëֱܹé¤Ç¤Ï¡¢ÅàÅڤˤĤ¤¤Æ¥ì¥Ó¥å¡¼¤ò¤·¤Ä¤Ä¡¢(1) ²«²Ï¸»Î®
°è¡ÊÅì¥Á¥Ù¥Ã¥È¡Ë¤Ë¤ª¤±¤ë±Êµ×ÅàÅÚÍ»²ò¤Î¿Ê¹Ô¤òÃæ¿´¤Ë¡¢¤µ¤é¤Ë¡¢(2) ¥¢¥é¥¹
¥«ÃÏ°è¤Ë¤ª¤±¤ë±Êµ×ÅàÅÚÂӤˤª¤±¤ë¿¹ÎӲкҤˤè¤ë³èÆ°ÁظüÊѲ½¡¢(3) ¥¹¥¤¥¹¡¦
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2008ǯ2·î15Æü(¶â) 10:30 - 12:00
Il-Ju Moon (Cheju National University, Korea; Professor)
- ¹Ö±éÂêÌÜ: Air-Sea Momentum Flux under Hurricanes and a Coupled Hurricane-Wave-Ocean Model
- ¾ì½ê: Áí¹ç¸¦µæÅï¡¡4¥»¥ó¥¿¡¼¶¦ÍÑ2³¬²ñµÄ¼¼ 270
- Í×»Ý:
This study aims to improve hurricane forecasts of the operational
GFDL/URI model by introducing a new coupled hurricane-ocean-wave
system. The coupled system consists of the 2005 high-resolution GFDL
hurricane model, the Princeton Ocean Model (POM), the WAVEWATCH III
model (WW3), the URI wave boundary layer (WBL) model, and the URI
equilibrium spectrum model. We will describe the main features of the
coupled system and show preliminary results of real hurricane
forecasts.
The key component of the coupled system is a newly-developed air-sea
momentum flux parameterization based on the wave fields (Moon et al.,
2004a-c). In the coupled system, the complete wave spectrum is
constructed by merging the WW3 spectrum in the vicinity of the
spectral peak with the spectral tail parameterization. The result is
incorporated into the WBL model to explicitly calculate the wave
induced stress, the mean wind profile, drag coefficient, and the
roughness length. In the coupled system, the estimated wave-field
dependent roughness length is transferred into the GFDL model,
replacing z0 of the current GFDL hurricane model based on the Charnock
relation. For computational efficiency, we introduce a movable grid
mesh configuration for the wave model as well as the MPI parallel
computing system for the coupled model.
We have tested and evaluated the new coupled system for Hurricane
Isabel (2003), Ivan (2004) and Katrina (2005) by comparing the storm
intensity forecasts and the spatial distributions of the surface wind
with and without the wave coupling. The results shows that the wind
structure with the wave coupling is evidently in a better agreement
with the HRD wind analysis and its intensity forecast is significantly
improved. This is accomplished by the use of more realistic
wave-dependent surface momentum fluxes and their spatial
distribution. For surface wave and storm surge simulations, the
introduction of the new momentum fluxes from the coupled model
contributes to improving forecast skill (Moon et al., 2007, 2008).
References
Moon, I.-J., T. Hara, I. Ginis (2004a), Effect of surface waves on
air-sea momentum exchange. Part I: Effect of mature and growing seas,
J. Atmos. Sci., 61, 2321-2333.
Moon, I.-J., I. Ginis, T. Hara (2004b), Effect of surface waves on
air-sea momentum exchange. II: Behavior of drag coefficient under
tropical cyclones, J. Atmos. Sci., 61, 2334-2348.
Moon, I.-J., I. Ginis, and T. Hara (2004c), Effect of surface waves on
Charnock coefficient under tropical cyclones, Geophys. Res. Lett., 31,
L20302..
Moon, I.-J., I. Ginis, T. Hara, B. Thomas, (2007), A Physics-based
parameterization of air-sea momentum flux at high wind speeds and its
impact on hurricane intensity predictions, Mon. Wea.r Rev. 135,
2869-2878.
Moon, I.-J., I. Ginis, T. Hara, B. Thomas, (2008), Impact of reduced
drag coefficient on ocean wave modeling under hurricane conditions ,
Mon. Wea. Rev. In press.
2008ǯ3·î12Æü(¿å) 10:00 - 11:30
ßÀÅÄ ÆÆ (µþÅÔÂç³Ø)
- ¹Ö±éÂêÌÜ: ¶Ëµ°Æ»±ÒÀ±±À¥ì¡¼¥À¡¦¥é¥¤¥À´Ñ¬¤òÍѤ¤¤¿ÀŻ߱ÒÀ±Split-window´Ñ¬¤Ë¤è¤ëÇ®ÂÓ°è¾åÁرÀ¤Î´ö²¿¡¦¸÷³ØÎ̤οäÄê
- ¾ì½ê: Áí¹ç¸¦µæÅï¡¡4¥»¥ó¥¿¡¼¶¦ÍÑ2³¬²ñµÄ¼¼ 270
- Í×»Ý:
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2008ǯ3·î19Æü(¿å) 13:30 - 15:00
Atsumu Ohmura (Institute for Atmospheric and Climate Science, ETH; Professor)
- ¹Ö±éÂêÌÜ: Secular variations of earth's surface irradiances
- ¾ì½ê: Áí¹ç¸¦µæÅï¡¡4¥»¥ó¥¿¡¼¶¦ÍÑ2³¬²ñµÄ¼¼ 270
2008ǯ3·î27Æü(ÌÚ) 13:00 - 15:30
Song-You Hong (Yonsei University, Seoul, Korea; Professor)
- ¹Ö±éÂêÌÜ: Lectures on basics and applications of microphysics and boundary layer issues
- ¾ì½ê: Áí¹ç¸¦µæÅï¡¡4¥»¥ó¥¿¡¼¶¦ÍÑ2³¬²ñµÄ¼¼ 270
- Í×»Ý:
(1) Physical processes in atmospheric models
This lecture introduces the fundamentals of the parameterization of
physical processes in atmosphere. The basic concept of
parameterization of each individual physics forcing such as radiation,
surface layer and boundary layer turbulence, precipitation processes
will be introduced. The existing numerical algorithms for each
physical process will be introduced. An advanced physics package for
numerical weather forecasts and climate prediction will be introduced.
(2) Interaction between the boundary-layer and precipitation processes in
atmospheric models
This talk describes the background of the physics parameterization
scheme development, focusing on the turbulence vertical diffusion and
precipitation algorithms. The hierarchy of the Yonsei University (YSU)
PBL (Hong et al. 2006, Mon. Wea. Rev.) for vertical diffusion, and the
Weather Research Forecasting (WRF) Single-Moment bulk parameterization
scheme (Hong et al. 2004, Mon. Wea. Rev) for microphysics scheme will
be described, together with its further revision strategy. Not only
the validation of the scheme over the theoretical study and
observations, but also the interaction between the boundary-layer and
other physics algorithms will be highlighted to accomplish the
improvement of numerical weather forecasts and climate prediction in
atmospheric models.