1/10Worshop Applied Antineutrino Physics, APC Lab, Dec 13-14 2007 International Monitoring of Nuclear Test Technologies In Use Legal basis of the international.

Slides:

Advertisements

Similar presentations

LLNL-PRES This work was performed under the auspices of the U.S. Department of Energy by Lawrence Livermore National Laboratory under Contract DE-AC52-07NA27344.

Advertisements

THE AUSTRALIAN NATIONAL UNIVERSITY Infrasound Technology Workshop, November 2007, Tokyo, Japan OPTIMUM ARRAY DESIGN FOR THE DETECTION OF DISTANT.

The eathquake What are earthquakes ? Why do they occur ? and Why can't we predict them ? Although we still can't predict when an earthquake will happen,

Rethinking Array Seismology in Nuclear-Test-Ban Treaty Monitoring Steven J. Gibbons Workshop on Arrays in Global Seismology, Raleigh, North Carolina, May.

Global Distribution of Crustal Material Inferred by Seismology Nozomu Takeuchi (ERI, Univ of Tokyo) (1)Importance of Directional Measurements from geophysicists’

 Major nuclear powers have honored a voluntary moratorium since early 1990s.  The U.S. hasn’t conducted a nuclear test since Time Lapse of.

19 February 2008 IDC/SQT/STPage 1 Building Capacity to Sustain a Geophysical Monitoring Network Presented at: IRIS/NSF Out of Africa Workshop Boston, MA,

Tsunamis Detection The Mission  Tsunamis Detection can help to minimize loss of life and property from future tsunamis. Mission Introduction Mechanism.

Coupled with the DART 4G system, PMEL is working on the next generation Tsunami Forecast System. New modeling capability will use NOAA supercomputers to.

Existing Infrastructure for International Exchange of Seismic Data Raymond J. Willemann GEM Technology, Washington, D.C. IASPEI:Includes commissions for.

SUPERSITES COORDINATION WORKSHOP Monday 10 June 2013

Observations and Modeling of Infrasound Produced by Ocean Waves By Mark Willis Masters Student/Dept of Meteorology Acknowledgements: Milton Garces (HIGP/ISLA),

Recent developments in the UNFCCC process in relation to global observations 4 th GTOS Steering Committee Paris, 1-2 December 2009 Rocio Lichte Programme.

EPA’s Response to Fukushima Japan Nuclear Emergency Mike Boyd, Senior Health Physicist EPA/Office of Radiation & Indoor Air Presented at 2011 OAS Annual.

LIMITED TEST BAN TREATY Peter Gray, Lexi Herlt, Connie Marshall.

Articulating long-term monitoring at Icelandic volcanoes: Links between FUTUREVOLC and EPOS Kristín S. Vogfjörd, Freysteinn Sigmundsson, Benedikt G. Ófeigsson,

The Quality Management System

-for saving innocent lives

Tsunami Warning System Elements IOC Assessment Mission to Indonesia 29 August-1 September 2005.

Utilizing Large Databases for Nuclear Explosion Monitoring: the Knowledge Base (KB) Aaron A. Velasco University of Texas at El Paso.

Bob Woodward, Bob Busby, Katrin Hafner, and David Simpson

A U.S. Sponsored Observing System of the Global Earth Observing System of Systems  Focus on the Network –Data Management –Products Global Seismographic.

Origin of an earthquake. Epicenter: It is the point on the (free) surface of the earth vertically above the place of origin (hypocenter/focus) of an earthquake.

8-13 January 2012, Bangkok, Thailand Institute of Seismology, National Academy of Sciences, Kyrgyz Republic.

IASPEI 2009 The Comprehensive Nuclear-Test-Ban Treaty Development of the Seismic Networks of the International Monitoring System Lassina Zerbo Director,

The Australian National Seismic Network (ANSN)

D McCormack, CTBT Infvrasound, KNMI Netherlands 29 October 2002 Towards Characterization of Infrasound Signals David A McCormack CTBT Verification Office.

GLOSS Global Sea Level Observing System Bernie Kilonsky University of Hawaii (GLOSS Group of Experts) Thorkild Aarup Intergovernmental Oceanographic Commission.

NEAREST PROJECT PARTICIPANT N° 10 Institut National de Géophysique Centre National pour la Recherche Scientifique et Technique (CNRST) (CNRST) in collaboration.

Automated Weather Observations from Ships and Buoys: A Future Resource for Climatologists Shawn R. Smith Center for Ocean-Atmospheric Prediction Studies.

Managing Waveform Data and Related Metadata for Seismic Networks OBSERVATIONAL NETWORK OF THE KAZAKHSTAN NATIONAL NUCLEAR CENTER (KAZNET) 8-13 January.

IRIS-PMG Station, its Significance to Papua New Guinea Mathew Moihoi Geophysical Observatory Geological Survey of Papua New Guinea Managing Waveform Data.

November 2008Infrasound Technology Workshop, BermudaPage 1 Presented to: Infrasound Technology Workshop Bermuda PTS Portable Infrasound Array John Coyne,

Infrasound Workshop De Bilt, Netherlands October 2002 Current Status of Infrasound Processing at the IDC Nicolas Brachet International Data Centre/Waveform.

Pacific Northwest National Laboratory U.S. Department of Energy National Security Issues Underground Harry Miley National Security Directorate Pacific.

ITW2008: P. Campus, R. Oldfield Bermuda, 3-7 November 2008 The recently installed IMS Infrasound Station IS51, Bermuda Paola Campus Comprehensive Nuclear-Test-Ban.

THE ANALYSIS OF THE INFRASOUND SIGNALS FROM MAY 12 EARTHQUAKE WENCHUAN CHINA Wang Xiaohang Signal Processing Department North China Institute of Computing.

Large Earthquake Rapid Finite Rupture Model Products Thorne Lay (UCSC) USGS/IRIS/NSF International Workshop on the Utilization of Seismographic Networks.

ITW2007: P. Campus Tokyo, November 2007 The IMS Infrasound Network: detection of a large variety of events, including volcanic eruptions Dr. Paola.

Tsunami warning agreements with the CTBTO Presented at the Eighth meeting of the Working Group on Tsunamis and Other Hazards Related to Sea-Level Warning.

Acoustic-gravity wave monitoring for global atmospheric studies Elisabeth Blanc 1 Alexis Le Pichon 1 Lars Ceranna 2 Thomas Farges 1 2- BGR / B3.11, Hannover,

Infrasound Workshop San Diego, USA October 2003 Infrasound Processing at the IDC and its Near-term Development P. Firbas, N. Brachet International.

Infrasound Technical Workshop 2008 Session 1 Summary – Sensors and Calibration.

1 Location and Characterization of Infrasonic Events Roger Bowman 1, Greg Beall 1, Doug Drob 2, Milton Garces 3, Claus Hetzer 3, Michael O’Brien 1, Gordon.

STATUS of the International Data Center and International Monitoring System Network of the PTS Florian Haslinger IMS Seismic Monitoring Section Preparatory.

Welcome back HA03 - IMS Hydroacoustic station installation Robinson Crusoe Island, Juan Fernadez Archipelago, Chile, March 2014 Georgios Haralabus, Jerry.

TSUNAMI WARNING SYSTEM.  INTRODUCTION  WHAT IS TSUNAMI  ABOUT TSUNAMI WARNING SYSTEM  TYPES OF TSUNAMI WARNING SYSTEM  TSUNAMIMETER  TSUNAMI DETECTION.

Analysis of regional infrasound signals at IMS infrasound array in Mongolia a RCAG/MAS P.O.B-152, Ulaanbaatar-51Mongolia b CEA/DASE BP12, Bruyeres-le-Chatel,

A Device for Detection of Acoustic Signals from Super High Energy Neutrinos Presenter: Presenter: G.L.Pan'kov Applied Physics Institute of Irkutsk State.

November 2007Infrasound Technology Workshop, Tokyo, JapanPage 1 Presented to: Infrasound Technology Workshop Tokyo, Japan PTS Experimental Infrasound Array.

NEMO-O DE NEMO First results from the NEMO Test Site G. Riccobene, for the NEMO Collaboration The NEMO Collaboration is performing the Phase 1 of the project,

BY K.MOUNIKA CSE 4 TH YEAR. What is a Tsunami? A tsunami is a wave in the ocean or in a lake that is created by a geologic event characterized by a series.

UNDERWATER WIRELESS COMMUNICATION

ARENA08 Roma June 2008 Francesco Simeone (Francesco Simeone INFN Roma) Beam-forming and matched filter techniques.

MR. BruCE MUTEGI SEISMOLOGIST Mr. Daniel Mutua ICT Technologist

What is required for nuclear disarmament?

The International Monitoring System:

Institute of seismology, National Academy of sciences, Kyrgyz Republic

The devastating impact of seismic sea waves

The devastating impact of seismic sea waves

Conclusions and Further Work

The Nuclear Test Ban: Technical Opportunities for the Trump Administration Stephen Herzog, Yale University United States Strategic.

EGU István Bondár1, Ronan Le Bras2, Nimar Arora3, Noriyuki Kushida2

Worldwide Nuclear Testing

Washington and the Test-Ban:

History of Earth.

Earthquakes & Seismic Waves

Earthquakes & Seismic Waves

Summary of 2003 Infrasound Technology Workshop

Presentation transcript:

1/10Worshop Applied Antineutrino Physics, APC Lab, Dec International Monitoring of Nuclear Test Technologies In Use Legal basis of the international monitoring of nuclear test Technologies used illustrated with some recent observations Present status of the international network

2/10Worshop Applied Antineutrino Physics, APC Lab, Dec Breakdown of energy released during a nuclear test Mecanical signature (Pressure wave : Seismic, Infrasound and Hydroacoustic) Thermal signature (Heat flow) Radioactive signature (Aerosols, Gaz) NUCLEAR TEST IMMEDIATE SIGNATURES Wave choc 55% N, γ, β, neutrino 10% X Ray 70% Thermal production 35% debris 20%

3/10Worshop Applied Antineutrino Physics, APC Lab, Dec THE LEGAL BASIS OF THE INTERNATIONAL TREATY On 10 September 1996, adoption by the United Nations General Assembly in New York of the Comprehensive Nuclear-Test-Ban Treaty (CTBT) which prohibits all nuclear test explosions. The treaty is intended to implement a global verification regime to monitor compliance with its provisions. The regime comprise a global network of monitoring stations (the International Monitoring System), an International Data Centre in Vienna, a consultation and clarification process, On-site Inspections, and confidence-building measures. It will enter into force when among others, the 44 states with nuclear capacity will have ratified.To date 34 states have ratified but China, North Korea, India, Pakistan and USA have still to do so. The States Parties establish an Organization (CTBTO) to achieve the object and purpose of the Treaty. A Provisional Technical Secretariat is responsible for supervising and coordinating the operation of the International Monitoring System (IMS); Operating the International Data Centre (IDC); Routinely receiving, processing, analysing and reporting on IMS data; Providing technical assistance for the installation and operation of monitoring stations

4/10Worshop Applied Antineutrino Physics, APC Lab, Dec INTERNATIONAL MONITORING SYSTEM A network of globally-distributed sensors will be installed in 321 monitoring stations located at 260 facilities in over 80 countries worldwide that will provide monitoring coverage of all the continent, oceans and atmosphere. It utilizes four technologies: –Seismic (underground seismic waves) –Infrasound (atmospheric sound waves) –Hydroacoustic (underwater seismic waves) –Radionuclide (radioactive isotopes) The data from the stations flow via a global communications network into the International Data Center in Vienna where analysts receive, analyze, and archive the data. Data can be provided electronically to States Signatories.

5/10Worshop Applied Antineutrino Physics, APC Lab, Dec SEISMIC MONITORING STATION Sensor type: Seismometer Station type :Three component and mininetwork Three component passband: Hz and Hz. 50 primary seismic stations will send continuous data and 120 auxiliary seismic stations sending waveform segments. 35 primary and 99 auxillary seismic stations are installed and 74% and 59% are already certified. The seismic technology consists in measuring the movement of ground surface and allows the detection of underground and underwater explosion as well as atmospheric ones close to the ground surface.

6/10Worshop Applied Antineutrino Physics, APC Lab, Dec SEISMIC MONITORING STATION Source: CTBTO-R. Pearce/L. Zerbo IDC Reviewed Event Bulletin: 1 January to 31 July 2007: 17,987 events

7/10Worshop Applied Antineutrino Physics, APC Lab, Dec SEISMIC MONITORING STATION Nuclear test Earthquake Seismograms recorded at Station PS31 (Wonju, Republic of Korea)

8/10Worshop Applied Antineutrino Physics, APC Lab, Dec detector Noise Filtering System 60 infrasound arrays will send continuous data, 38 stations are installed and 62% are already certified. INFRASOUND MONITORING STATION The infrasound technology consists in measuring the variation of atmospheric pressure and allows the detection of low frequency signals such as those of atmospheric explosion as well as underground and underwater ones close to the surface.

9/10Worshop Applied Antineutrino Physics, APC Lab, Dec station = 4 elements sensor + noise filtering system Infrasound Station Air input detector Pressure Captor Air inlet 30 cm Distance (km) Wave Front Direction Velocity INFRASOUND MONITORING STATION Sensor type: Microbarometer with passband: Hz 4 element arrays Triangle with a component at the centre.

10/10Worshop Applied Antineutrino Physics, APC Lab, Dec INFRASOUND MONITORING STATION Source: CTBTO-F. Guendel

11/10Worshop Applied Antineutrino Physics, APC Lab, Dec HYDROACOUSTIC MONITORING STATION Hydrophone with passband of 1 – 100 Hz 6 hydroacoustic arrays will send continuous data and 5 "T-Phase" stations which are seismic stations on coasts which are used to detect hydroacoustic signals 11 hydroacoustic and T phase stations are installed and 91% are already certified. The hydroacoustic technology consists in measuring the variation of pressure wave and allows the detection of underwater explosion as well as atmospheric and underground ones close to the surface.

12/10Worshop Applied Antineutrino Physics, APC Lab, Dec HYDROACOUSTIC MONITORING STATION The hydroacoustic station at Diego Garcia recorded the Tsunami Waveform at frequencies of about to 0.01 Hz even though the site was not significantly impacted by the Tsunami. Water depth is 1500 m. Source: CTBTO-F. Guendel

13/10Worshop Applied Antineutrino Physics, APC Lab, Dec HYDROACOUSTIC MONITORING STATION Source: W.A. Watkins et al., 2004, Deep Sea Research

14/10Worshop Applied Antineutrino Physics, APC Lab, Dec RADIONUCLIDE STATIONS (PARTICULATES) Credit photo: CTBTO Filter : collection efficiency 80% for particulates below diameter of 2 µm Station type : 500 m 3 /hour during 24 hours 80 radionuclide stations 58 stations are installed and 58% are already certified. The radionuclide technology consists in collecting aerosols and gaz samples for measuring the variation of their radioactivity. This technology is the only one that can prove that the explosion detected by the others technologies is nuclear.

15/10Worshop Applied Antineutrino Physics, APC Lab, Dec RADIONUCLIDE STATIONS (PARTICULATES) Gamma spectrometry Detector: HP Ge relative efficiency above 40 % Baseline sensitivity 30 µBq.m -3 for 40 Ba 9 of 16 radionuclide measurement laboratories are already certified. Credit photo: Dase & CTBTO

16/10Worshop Applied Antineutrino Physics, APC Lab, Dec RADIONUCLIDE STATIONS (PARTICULATES)

17/10Worshop Applied Antineutrino Physics, APC Lab, Dec RADIONUCLIDE STATIONS (GAZ – XENON) MNX45 CNX20 ARX01 CAX05 CAX16 FRX27 RUX61 DEX33 CNX22 SEX63 NOX49 PAX50 AUX09 JPX38 CAX17 USX75 ARIX SAUNA SPALAX NZX46 Station type : 0.4 m 3 /h over 24 hours max Measurement type: Beta-gamma coincidence or HR Gamma spectrometry 133 Xe (and 135 Xe) activity concentration above 1 mBq.m -3 for a 10 m 3 sample. 40 noble gaz stations 14 stations are already installed.

18/10Worshop Applied Antineutrino Physics, APC Lab, Dec RADIONUCLIDE STATIONS (GAZ – XENON) Source: CTBTO-Saey

19/10Worshop Applied Antineutrino Physics, APC Lab, Dec SUMMARY The Comprehensive Test Ban Treaty Organization (CTBTO) is putting into place an International Monitoring System (IMS) of 321 stations of which 248 are already installed. A private network composed of frame relay and satellite links called the Global Communications Infrastructure (GCI) conveys the data measurement to a center in Vienna-Austria. Once the IMS is completed, the International Data Centre (IDC) will collect and archive over 1,500 channels of data from the IMS stations, comprising a daily volume of up to 10 Gbytes. The IDC will serve as the primary central repository of all data from the IMS sensors. Although the implementation rate of the network now stands at 80%, it’s efficiency was demonstrated by the detection of the nuclear test in North Korea and as for seismic data, countries are already using them for their national early warning tsunami centers.