Temporal variation of the estimated volume transport through the Korea and Tsugaru Straits Hanna Na and Kuh Kim SEES, Seoul National University, E-mail:

Slides:

Advertisements

Similar presentations

TWO STEP EQUATIONS 1. SOLVE FOR X 2. DO THE ADDITION STEP FIRST

Advertisements

LEUCEMIA MIELOIDE AGUDA TIPO 0

Copyright © 2003 Pearson Education, Inc. Slide 1 Computer Systems Organization & Architecture Chapters 8-12 John D. Carpinelli.

Chapter 1 The Study of Body Function Image PowerPoint

1 Copyright © 2010, Elsevier Inc. All rights Reserved Fig 2.1 Chapter 2.

1 Chapter 40 - Physiology and Pathophysiology of Diuretic Action Copyright © 2013 Elsevier Inc. All rights reserved.

By D. Fisher Geometric Transformations. Reflection, Rotation, or Translation 1.

Business Transaction Management Software for Application Coordination 1 Business Processes and Coordination.

Chapter 3: Top-Down Design with Functions Problem Solving & Program Design in C Sixth Edition By Jeri R. Hanly & Elliot B. Koffman.

Forecasting winter wheat yield in Ukraine using 3 different approaches

THOR Annual Meeting - Bergen 9-11 November /25 On the impact of initial conditions relative to external forcing on the skill of decadal predictions:

Jeopardy Q 1 Q 6 Q 11 Q 16 Q 21 Q 2 Q 7 Q 12 Q 17 Q 22 Q 3 Q 8 Q 13

Jeopardy Q 1 Q 6 Q 11 Q 16 Q 21 Q 2 Q 7 Q 12 Q 17 Q 22 Q 3 Q 8 Q 13

Title Subtitle.

ALGEBRAIC EXPRESSIONS

DIVIDING INTEGERS 1. IF THE SIGNS ARE THE SAME THE ANSWER IS POSITIVE 2. IF THE SIGNS ARE DIFFERENT THE ANSWER IS NEGATIVE.

MULTIPLYING MONOMIALS TIMES POLYNOMIALS (DISTRIBUTIVE PROPERTY)

ADDING INTEGERS 1. POS. + POS. = POS. 2. NEG. + NEG. = NEG. 3. POS. + NEG. OR NEG. + POS. SUBTRACT TAKE SIGN OF BIGGER ABSOLUTE VALUE.

MULTIPLICATION EQUATIONS 1. SOLVE FOR X 3. WHAT EVER YOU DO TO ONE SIDE YOU HAVE TO DO TO THE OTHER 2. DIVIDE BY THE NUMBER IN FRONT OF THE VARIABLE.

SUBTRACTING INTEGERS 1. CHANGE THE SUBTRACTION SIGN TO ADDITION

MULT. INTEGERS 1. IF THE SIGNS ARE THE SAME THE ANSWER IS POSITIVE 2. IF THE SIGNS ARE DIFFERENT THE ANSWER IS NEGATIVE.

FACTORING ax2 + bx + c Think “unfoil” Work down, Show all steps.

Impacts of systematic model biases on intraseasonal variability of the Asian summer monsoon and the intraseasonal-interannual relationship A. G. Turner.

Duration CONSTRUCTION Opening Date EQUIP INSTALL. & TEST Incheon International Airport Control Tower Outcome Progress DESIGN & AWARD : AOR 36 MONTHS.

Solve Multi-step Equations

Richmond House, Liverpool (1) 26 th January 2004.

REVIEW: Arthropod ID. 1. Name the subphylum. 2. Name the subphylum. 3. Name the order.

BT Wholesale October Creating your own telephone network WHOLESALE CALLS LINE ASSOCIATED.

ABC Technology Project

Understanding Florida Bay Hypersalinity and Water Exchange Tom Lee-RSMAS; Nelson Melo-CIMAS; Libby Johns, Ryan Smith and Peter Ortner-AOML; DeWitt Smith-ENP;

Deep Ocean Monitoring : the East Sea (Sea of Japan) the East Sea (Sea of Japan) Kuh Kim 1, Kyung-Il Chang 1, Yun-Bae Kim 2 Jae-Hak Lee 3, Sang-Chul Hwang.

© S Haughton more than 3?

© Charles van Marrewijk, An Introduction to Geographical Economics Brakman, Garretsen, and Van Marrewijk.

© Charles van Marrewijk, An Introduction to Geographical Economics Brakman, Garretsen, and Van Marrewijk.

© Charles van Marrewijk, An Introduction to Geographical Economics Brakman, Garretsen, and Van Marrewijk.

Twenty Questions Subject: Twenty Questions

Page 1 ASAR Validatoin Review - ESRIN – 9-13 December 2002 Ocean geophysical results from ASAR  Geophysical overview  ocean spectra : the isidore case.

Squares and Square Root WALK. Solve each problem REVIEW:

Energy & Green Urbanism Markku Lappalainen Aalto University.

© 2012 National Heart Foundation of Australia. Slide 2.

Lets play bingo!!. Calculate: MEAN Calculate: MEDIAN

Past Tense Probe. Past Tense Probe Past Tense Probe – Practice 1.

Sets Sets © 2005 Richard A. Medeiros next Patterns.

Understanding Generalist Practice, 5e, Kirst-Ashman/Hull

1 Verification of wave forecast models Martin Holt Jim Gunson Damian Holmes-Bell.

GG Consulting, LLC I-SUITE. Source: TEA SHARS Frequently asked questions 2.

Addition 1’s to 20.

Model and Relationships 6 M 1 M M M M M M M M M M M M M M M M

25 seconds left…...

Test B, 100 Subtraction Facts

Januar MDMDFSSMDMDFSSS

We will resume in: 25 Minutes.

©Brooks/Cole, 2001 Chapter 12 Derived Types-- Enumerated, Structure and Union.

Atlantic Water temperature and climate in the Barents Sea in Vladimir Boitsov, Alexey Karsakov, Alexander Trofimov Polar Research Institute of.

Magdalena Andres 1, Jae-Hun Park 1, Mark Wimbush 1, Kyung Il Chang 2, Hiroshi Ichikawa 3 1 Graduate School of Oceanography, University of Rhode Island.

Bottoms Up Factoring. Start with the X-box 3-9 Product Sum

1 Unit 1 Kinematics Chapter 1 Day

PSSA Preparation.

1 PART 1 ILLUSTRATION OF DOCUMENTS  Brief introduction to the documents contained in the envelope  Detailed clarification of the documents content.

How Cells Obtain Energy from Food

The speaker took this picture on 11 December, 2012 over the ocean near Japan. 2014/07/29 AOGS 11th Annual Meeting in Sapporo.

Presentation transcript:

Temporal variation of the estimated volume transport through the Korea and Tsugaru Straits Hanna Na and Kuh Kim SEES, Seoul National University, PICES 14 th Annual Meeting Sep. 29-Oct. 9, 2005, Vladivostok, Russia [ 1] Ito, T., O. Togawa, M. Ohnishi, Y. Isoda, T. Nakayama, S. Shima, H. Kuroda, M. Iwahashi, and C. Sato, Variation of velocity and volume transport of the Tsugaru Warm Current in the winter of , Geophysical Research Letters, 30(13), 1678, [2] Lyu, S. J., and K. Kim, Absolute transport from the sea level difference across the Korea Strait, Geophysical Research Letters, 30(6), 1285, [3] Takikawa, Tetsutaro, and J. H. Yoon, Volume transport through the Tsushima Straits estimated from sea level difference, Journal of Oceanography, Vol. 61 (No. 4), pp , 2005 References 2. Data and Methods 6. Discussion 1. Introduction Study Objectives 1.Estimation of the VT through the Korea and Tsugaru Straits for longer than decadal time scale 2. Comparison of the temporal variation of the VT through the Korea and Tsugaru Straits 3. Understanding of the inflow and outflow system of the East Sea Tide gauge Sea Level Difference (SLD) and Volume Transport (VT) The VT through the strait is linearly related to the cross-strait SLD according to the geostrophic balance. The correlation between temporal variation of the SLD and the VT has been studied through several researches. Through the regression analysis the conversion factor from the SLD to the VT can be calculated. By applying the conversion factor to the SLD, the VT is obtained for the longer period the sea level data have been measured. Fig.2. Sea level stations near the Korea Strait. Fig.3. Sea level stations near the Tsugaru Strait. 4. VT through the Tsugaru Strait 3. VT through the Korea Strait 5. Inflow and Outflow system of the East Sea Sea level data from the KODC and JODC Inverse Barometric Correction Using ECMWF Reanalysis sea level pressure Fig.4. Station map of the Korea Strait and estimation of the baroclinic part of SLD (Lyu and Kim, 2003). Fig.5. Baroclinic part of the SLD calculated from KODC hydrography data. Fig.6. Regression analysis between corrected SLD and VT. Triangle: observed VT using submarine cable, circle: estimated VT from corrected SLD. Fig.7. Monthly means of the VT for 43 years and their variance conserved spectra. Fig.8. Mean seasonal variation of the VT. Fig.9. Annual means of the VT. Fig.10. Interannual variation of the VT. 13 month moving average of [Monthly means-mean seasonal variation]. Fig.11. Regression Analysis between SLD (Tappi-Yoshioka) and VT (Ito et al., 2003). Solid line is the estimated VT and dotted line is the observed VT. Fig.12. Monthly means of the VT for 21 years and their variance conserved spectra. Fig.13. Mean seasonal variation of the VT. Fig.14. Annual means of the VT. Fig.15. Interannual variation of the VT. 13 month moving average of [Monthly means-mean seasonal variation]. Fig.16. The ratio of the VT through the Tsugaru Strait to the Korea Strait. Light solid line shows the monthly mean and cross symbols indicate the annual mean. Right side of the bottom panel indicates the climatology of the ratio for 20 years. Fig.17. The difference of the VT between the Tsugaru Strait and the Korea Strait. Light solid line shows the monthly mean and cross symbols indicate the annual mean. Right side of the bottom panel indicates the climatology of the ratio for 20 years. Fig.18. Coherency between VT through the Korea and Tsugaru Straits. Dot represents the phase difference between them. Fig.19. Tide gauge station can be used to estimate the VT through the East of Taiwan, Taiwan Strait, Tokara Strait, Korea Strait, and Tsugaru Strait Fig.20. Monthly means of (top to bottom) VT through the Korea Strait, VT through the Tsugaru Strait, SLD across the Tokara Strait, SLD across the Taiwan Strait, and SLD of the east of Taiwan. East Sea Inflow Korea Strait Outflow Tsugaru Strait Outflow Soya Strait Lack of continuous observation on transport through the straits Korea Strait Lyu & Kim, 2003: monitoring since 1998 using submarine cable Takikawa & Yoon, 2005: monitoring since 1997 using vessel mounted ADCP Tsugaru Strait Ito et al., 2003: Oct., 1999 ~ Mar., 2000 using vessel mounted ADCP Fig.1. Major Straits in the East Sea. The ratio of the VT through the Tsugaru Strait to the Korea Strait shows maximum on December. The difference of the VT between the Tsugaru Strait and the Korea Strait shows minimum on December. VT through the Korea and Tsugaru Straits show higher correlation and lower phase difference according to the period increase. Coherency between VT through the two straits has the peak on the period of about 200days and 1 year. The index of the VT variation through the East of Taiwan, Taiwan Strait, Tokara Strait also can be estimated. The correlation between them and the VT through the straits in the East Sea can be understood on the long-term time scale.