Analysis on the formation process of high dose rate zone in the northwest direction of the Fukushima Daiichi nuclear power plant

Similar documents
Assessment of atmospheric dispersion and radiological consequences for the Fukushima Dai-ichi Nuclear Power Plant accident

Fukushima-Daiichi Accident: Main contamination events

Assessment of atmospheric dispersion and radiological consequences for the Fukushima Dai-ichi Nuclear Power Plant accident

Numerical Simulation System for Environmental Studies: SPEEDI-MP

ABSTRACT 1. INTRODUCTION

Table D-1-2. ATDM-Meteorology simulations completed (C) by each participating ATDM model (rows) with different meteorological data (columns) and also

European Fallout from Chernobyl

Modeling Radiological Consequences of Sever Accidents in BWRs: Review of Models Development, Verification and Validation

I) Simulations by Japan Atomic Energy Agency (JAEA) using nuclear dispersion models on the global ocean analysis systems, Multivariate Ocean

Dr. Ryohji Ohba (Nuclear Safety Research Association )

17th International Conference on Harmonisation within Atmospheric Dispersion Modelling for Regulatory Purposes 9-12 May 2016, Budapest, Hungary

Environmental radiation measurements immediately after the accident and dose evaluations based on soil deposition

Numerical simulation of dispersion and deposition of radioactive materials from the Fukushima Daiichi nuclear power plant in March of 2011

Results of the (i) Fifth Airborne Monitoring Survey and (ii) Airborne Monitoring Survey Outside 80km from the Fukushima Dai-ichi NPP

USING METEOROLOGICAL ENSEMBLES FOR ATMOSPHERIC DISPERSION MODELLING OF THE FUKUSHIMA NUCLEAR ACCIDENT

Naka-Gun, Ibaraki, , Japan

Intercomparison of Regional Chemical Transport Models for the Fukushima Daiichi Nuclear Power Plant Accident

Simulation of Radioactivity Concentrations in the Sea Area (the 5th report

Institute for Science and International Security

Modeling the Physical Processes that Impact the Fate and Fallout of Radioactive Materials

FINNISH EXPERIMENTS ON LEVEL 3 PRA. VTT Technical Research Centre of Finland Ltd.: P.O. Box 1000, Espoo, Finland, 02044, and

Results of the Airborne Monitoring in the evacuation-directed zones

Assessment of Atmospheric Dispersion for the Fukushima Dai-ichi Nuclear Power Plant Accident

Information (10:00), July 3, 2018

Kazuaki Yajima, Kazuki Iwaoka, and Hiroshi Yasuda

Information (11:00), February 12, 2019

Information (17:30), January 11, 2019

Accelerator Facility Accident Report

J-Rapid PI: Jun Sasaki 1 T. Suzuki 1 and R. U. A. Wiyono 1. Rapid PI: Changsheng Chen 2 C. Beardsley 3, Z. Lai 2, R., H. Lin 2, J. Lin 3 and R.

Measuring Planet Earth Regents Review. 2. State the altitude of Polaris as seen by an observer at the North Pole.

TEPCO s Activities on the Investigation into Unsolved Issues in the Fukushima Daiichi NPS Accident

Correlation between neutrons detected outside the reactor building and fuel melting

Lessons Learned in Responding to the Accident at the Fukushima Daiichi Nuclear Power Stations: The Way Forward. World Meteorological Organization

Available online at ScienceDirect. Nuclear power plant explosions at Fukushima-Daiichi. Takashi Tsuruda*

Presenting Uncertain Information in Radiological Emergencies. University of Warwick, Public Health England, Met Office

Chapter 3 Analysis of Radioactive Release from the Fukushima Daiichi Nuclear Power Station

High Resolution Modeling of Multi-scale Cloud and Precipitation Systems Using a Cloud-Resolving Model

Lawrence Livermore National Laboratory 2 LLNL-PRES

Five years monitoring activity on radioactive cesium in seawater after the Fukushima Dai-ichi Nuclear Power Plant Accident

RADIATION MEASUREMENTS AT THE CAMPUS OF FUKUSHIMA MEDICAL UNIVERSITY THROUGH THE 2011 OFF THE PACIFIC COAST OF TOHOKU EARTHQUAKE AND

Lessons learned in responding to the accident at the Fukushima Daiichi nuclear power stations: THE WAY FORWARD

Results of Airborne Monitoring Survey by MEXT in the Chugoku Region

EXTRACTION OF FLOODED AREAS DUE THE 2015 KANTO-TOHOKU HEAVY RAINFALL IN JAPAN USING PALSAR-2 IMAGES

Detection in Muncie, Indiana, of the Fukushima Nuclear Reactor Releases Following the Japanese Earthquake"

Name: Climate Date: EI Niño Conditions

Journal of Nuclear Science and Technology. ISSN: (Print) (Online) Journal homepage:

Inverse estimation of the emission of radioactive materials from Fukushima

samples before and after the Fukushima Daiichi Nuclear Power Plant accident

Weather Practice Test

L.O Students will learn about factors that influences the environment

Radio Acoustic Sounding in Urban Meteorological Observations

3. This room is located in a building in New York State. On which side of the building is the window located? (1) north (3) east (2) south (4) west

Atmospheric behavior, deposition, and budget of radioactive materials from the. Yu Morino, Toshimasa Ohara, * and Masato Nishizawa

A Prepared Marylander Creates a Resilient Maryland

Page 1. Name: 1) The graph below shows air temperature for an area near the Earth's surface during a 12-hour period.

Analysis of meteorological measurements made over three rainy seasons in Sinazongwe District, Zambia.

MAPS OF RATIOS OF DIFFERENT GROUND DEPOSITION DATASETS

Role of the Met Office in the UK Response to Nuclear Emergencies

River Water Circulation Model on the Natural Environment

Page 1. Name:

HISTORY OF HEAVY RAINFALL DISASTER INFORMATION IN JAPAN

UPDATE OF REGIONAL WEATHER AND SMOKE HAZE April 2016

Unit Three Worksheet Meteorology/Oceanography 2 WS GE U3 2

Fukushima nuclear power plant damaged by M9 Earthquake with some focus on ocean

Unseasonable weather conditions in Japan in August 2014

1. Which weather map symbol is associated with extremely low air pressure? A) B) C) D) 2. The diagram below represents a weather instrument.

Global Wind Patterns

FP release behavior at Unit-2 estimated from CAMS readings on March 14 th and 15 th

Which rock unit is youngest in age? A) A B) B C) C D) D

Pressure System Circulation

M. Liste 1, M. Grifoll 2, I. Keupers 1, J. Fernández 3, H. Ortega 1, J. Monbaliu 1

SUPPLEMENTARY INFORMATION

Midterm Review #4 -FR

Chiang Rai Province CC Threat overview AAS1109 Mekong ARCC

UPDATE OF REGIONAL WEATHER AND SMOKE HAZE (May 2017)

Unit 1 Test. Version A

Arizona Climate Summary March 2013

Features of the wind fields associated with Typhoon 0418 (Songda) compared with those of Typhoon 9119 (Mireille)

Preparation of Distribution Map of Radiation Doses, etc. (Maps of. Concentration of Tellurium 129m and Silver 110m in Soil) by MEXT

Initial substantial reduction in air dose rates of Cs origin and personal doses for residents owing to the Fukushima nuclear accident

DEPARTMENT OF EARTH & CLIMATE SCIENCES Name SAN FRANCISCO STATE UNIVERSITY Nov 29, ERTH 360 Test #2 200 pts

UPDATE OF REGIONAL WEATHER AND SMOKE HAZE November 2016

CFD calculations of the test 2-4 experiments. Author: G. de With

Aiguo Dai * and Kevin E. Trenberth National Center for Atmospheric Research (NCAR) $, Boulder, CO. Abstract

2016 Meteorology Summary

Prevention Tsunami wall 10m high (breached by the tsunami due to land level falling by 3m)

Page 1. Name: 4) State the actual air pressure, in millibars, shown at Miami, Florida on the given weather map.

UPDATE OF REGIONAL WEATHER AND SMOKE HAZE (February 2018)

Heavy Rain/Flooding September 8-10 Associated with Tropical Storm Etau

An Analysis of Typhoon 9807 (Vicki) Based on Surface Meteorological Records Obtained from Fire Stations

RR#5 - Free Response

IMPACT OF WEATHER CHANGES ON TVA NUCLEAR PLANT CHI/Q (χ/q) Kenneth G. Wastrack Doyle E. Pittman Jennifer M. Call Tennessee Valley Authority

What is one-month forecast guidance?

Kalimantan realistically (Figs. 8.23a-d). Also, the wind speeds of the westerly

3. As warm, moist air moves into a region, barometric pressure readings in the region will generally 1. decrease 2. increase 3.

Dose Reconstruction Methods and Source Term Assessment using Data from Monitoring Networks and Mobile Teams A German Approach

Tohoku Earthquake and Tsunami Japan March 11, 2011 Information updated 4/19/2011

Monitoring Regional Rice Development and Cool-Summer Damage

Radioactive Inventory at the Fukushima NPP

Analysis for Progression of Accident at Fukushima Dai-ichi Nuclear Power Station with THALES2 code

Transcription:

Analysis on the formation process of high dose rate zone in the northwest direction of the Fukushima Daiichi nuclear power plant Jun. 13, 2011 Research group of Japan Atomic Energy Agency (JAEA) has analyzed the formation process of high dose rate zone in the northwest direction of the Fukushima Daiichi nuclear power plant and the middle part of Fukushima Prefecture by using numerical simulations of the atmospheric dispersion of radioactive materials discharged from the plant during the period from 15 to 16 March, 2011. The numerical simulation reproduced the atmospheric dispersion of radioactive materials as follows. The radioactive plume discharged in the morning of 15 March flowed toward the south to southwest direction from the plant, then moved westward around noon and encountered a rain band at the middle part of Fukushima Prefecture from 14 to 15 JST (Japan Standard Time). The deposited radionuclides by rainfall caused the increase of air dose rates at the monitoring posts in Shirakawa and Koriyama cities. On the other hand, the radioactive plume discharged in the afternoon of 15 March flowed toward the west to northwest direction from the plant. It was washed out by a rain band moved from the northwest direction and deposited on the ground over the northwest area of the plant during the period from the evening to midnight of 15 March. The simulation shows that the deposition by rainfall at the middle part of Fukushima Prefecture occurred earlier than that around the northwest direction from the plant, and this result agreed with the monitoring data by Fukushima Prefecture. While the radioactive plume flowed toward the Pacific Ocean after the morning of 16 March, dose rates around the northwest region of the plant and the middle of Fukushima Prefecture continued to be high in both simulation results and monitoring data. It indicates that the current high dose rates monitored in Fukushima prefecture are caused by radionuclides deposited on the ground due to the rainfall on 15 March. In order to best reproduce the spatial and temporal distributions of air dose rates in monitoring data, the release rates of radionuclides were assumed to increase substantially during separate 3-hour periods before and afternoon of 15 March. These significant increases of release rates of radionuclides are also indicated by the increase of air dose rate monitored at the main gate of the plant during 7:00 to 10:30 in the morning and the rapid decreases of pressure in Unit 2 in the morning and afternoon. This simulation was carried out by using the nuclear emergency response system of JAEA, WSPEEDI: World-wide version of System for Prediction of Environmental Emergency Dose Information. Although the simulation has some discrepancies with measurements, such as overestimations around northern part of Fukushima city and southeastern part of Koriyama city, spatial and temporal distributions of air dose rates agree mostly with those derived from monitoring data on the ground and by airplane. 1

This work including technical details is presented in the special session Fukushima Crisis: Air/Sea Transport Modeling of 15th Annual George Mason University Conference on Atmospheric Transport and Dispersion Modeling held at Fairfax, Virginia, U.S.A. on 12 to 14 July, 2011. Calculation Conditions Calculation domain: 190 km square around the plant, 1 km resolution Calculation period: 17 JST 14 to 00 JST 17 March, 2011 Meteorological data: GPV (Grid Point Value) data by Japan Meteorological Agency, AMeDAS (Automated Meteorological Data Acquisition System) data Topographical data: 1 km grid surface elevation and land-use data Radionuclides: 131 I, 132 Te + 132 I, 134 Cs, 137 Cs Release rate: Based on the preliminary estimated source term reported by Nuclear Safety Commission of Japan, temporal changes of release rates are determined to reproduce the monitoring data. Supplementary figures Fig. 1 Simulated atmospheric dispersion process on 15 to 16 March, 2011 As shown in the upper panels, the simulation reproduced temporal changes in air dose rate measured at the middle part of Fukushima Prefecture (Koriyama city), where the radioactive plume discharged in the morning was passed, and the northwest part of the plant (Iitate mura), where the radiation plume discharged in the afternoon was passed. In the middle panel, the distribution of simulated air dose rate at 21 JST on 16 March is shown together with arrows schematically representing plume paths during the period from 15 to 16 March. The clockwise rotation in plume flow direction is shown. In the bottom panel, time series of air dose rate at the main gate and the periods of rapid decrease of pressure data* in Unit 2 are shown. While the increase of air dose rate and the decrease of pressure in the morning occurred almost concurrently, no clear peak in air dose rate detected corresponding to the decrease of pressure in the afternoon due to about 90-degree turn in wind direction. *Pressure data: NISA (http://www.nisa.meti.go.jp/oshirase/2011/files/230411-1-3.pdf) Fig. 2 The movement of radioactive plume and rain bands: left panels show calculated (shaded area) and measured (plot with values) air dose rate, and right panels show calculated rain intensity (shaded area) and concentration accumulated in vertical air column (red contours). The plume discharged in the morning flowed toward the southwest direction. While the plume did not encounter rain bands during the morning and air dose rates decrease down to a low level after its passage, it encountered a rain band at the middle part of Fukushima Prefecture around 15 JST causing high dose rate zone. 2

The plume discharged in the afternoon flowed toward west to northwest direction and encountered a rain band after evening, causing a large amount of wet deposition around the northwest region. The plume flowed out to the Pacific Ocean after the morning of 16 March. Since dose rates around the northwest region of the plant and the middle of Fukushima Prefecture continued to be high, these high dose rates are caused by radionuclides deposited on the ground due to rainfalls. The simulation has some discrepancies with measurements, such as overestimations around northern part of Fukushima city and southeastern part of Koriyama city. It is caused mainly by temporal and/or spatial discrepancies in rain area between the actual condition and simulation during plume passage, and overestimation of upper wind speed. 3

Temporal changes of air dose rate (μsv/h), : monitoring, : calculation Koriyama city Iitate mura Distribution of air dose rate at 21 JST on 16 March and movements of plumes (arrows) Marks ( ) and values represent monitoring values at this time. 15 Mar PM 16 Mar 15 Mar AM Rapid pressure decrease in Unit 2 Period A: 7 to 11 JST on 15 March Period B: 13 to 15 JST on 15 March Air dose rate at the main gate of Fukushima Daiich nuclear power plant 3 月 15 日 00:02 A B : near main gate 2 号機ベント : near west gate Air dose rate (μsv/h) : near gym. Fig. 1 Simulated atmospheric dispersion process on 15 to 16 March, 2011 4

09 JST on 15 March, 2011 12 JST on 15 March, 2011 15 JST on 15 March, 2011 Fig. 2 Left panel: calculated (shaded area) and measured (plot with values) air dose rate, and right panel: calculated rain intensity (shaded area) and concentration accumulated in vertical air column (red contours) 5

18 JST on 15 March, 2011 21 JST on 15 March, 2011 09 JST on 16 March, 2011 Fig. 2 continued 6

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback