ACT

An analysis of the South Australian Nuclear Fuel Cycle Royal Commission report

Tuesday 11 April 2017, 8.30am – 6:30pm

Springbank Room, Crawford School, ANU

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The results of the SA Nuclear Fuel Cycle Royal Commission were released in May 2016 and this will be the first wide-ranging national discussion of the implications.

The symposium will offer a critique of the different dimensions of the nuclear fuel cycle including mining and fuel processing, nuclear power, waste storage, the international context, economic impact and human capacity, and social licence to operate.

It has been designed so that policy makers, industry and other informed stakeholders contribute to the discussion.

Pre-registration is essential via: https://www.eventbrite.com.au/e/the-nuclear-fuel-cycle-in-australia-tick...

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 ASEG ACT Branch members,

You are invited to the ACT Branch’s Annual General Meeting with a special presentation from guest speaker Ron Hackney (details below). Drinks and snacks are provided.

Date: Thursday, 30 March 2017
Time: Drinks and snacks from 4pm followed by the AGM at 4:30pm.
Location: Sir Harold Raggatt Theatre, Geoscience Australia

AGENDA:

1.    Opening of meeting 4:30 pm 

2.    Guest speaker presentation (Ron Hackney) – 4:35 pm

3.    Minutes of the 2016 Annual General Meeting

4.    Report on the activities of the Society during the last year: 
       i.    President

5.    To receive and consider the financial accounts:
       i.    Treasurer

6.    The Annual General Meeting for 2017 - nominated in accordance with the Society's Constitution and are unopposed:
       i.    President                            
       ii.    Secretary                             
       iii.    Treasurer                            

7.    Appointment of Committee members:

8.    Thank  you to outgoing Executive

Meeting Close.

Guest Speaker Presentation by Ron Hackney - Title: From geophysics to deep stratigraphic drilling for tectonics, climate and ancient life in northern Zealandia
 
Abstract: The Lord Howe Rise, a submerged and extended continental ribbon that separated from Australia in the Late Cretaceous, is the key to understanding one of Earth’s last remaining scientific frontiers – the continent of Zealandia. Geoscience Australia and the Japan Agency for Marine-Earth Science and Technology are now leading an international effort through the International Ocean Discovery Program (IODP) to realise deep stratigraphic drilling of a sedimentary basin in northern Zealandia. If funded, this drilling will provide insight into Cretaceous tectonics, paleoclimate and paleoceanography at the eastern margin of Gondwana and help define the limits to deep microbial life in extreme environments. This presentation will provide a brief overview of the geophysics involved in selecting the ideal drill site and defining the crustal framework of the region to be drilled.

Biography: Dr Ron Hackney is a Senior Geoscientist in Geoscience Australia's Resources Division. He completed a BSc (Honours) degree at the Australian National University in 1993, before undertaking a MSc in Geophysics at Victoria University of Wellington in New Zealand. Ron's PhD at the University of Western Australia (2001) examining the crustal structure related to the iron-ore bearing Hamersley Ranges was followed by a post-doc at the Free University of Berlin and a Junior Professorship in Solid Earth Geophysics at the University of Kiel. He returned to Canberra in 2008 to work at Geoscience Australia, where he has since contributed to a range of studies in Australia's offshore sedimentary basins.

I hope to see you there!

James Goodwin  |  Secretary
ACT Branch |  Australian Society of Exploration Geophysicists
 
t +61 2 6249 9705
 

You are invited to listen to Geoscience Australia’s newest Geomagnetic team member Garrick Paskos give his end of 2016 graduate rotation summary.

The talk will be held at 3pm on the 23^rd Feb 2017 in the Sir Harold Raggatt Theatre Geoscience Australia

Garrick will talk about his work predicting induced electric fields in Australia using Geoscience Australia’s Earth conductivity model and geomagnetic observatory data for infrastructure and community safety.

Recent advances in the electrical conductivity model of Australia from a 2.5-D thin-sheet to a 3-D model (Geoscience Australia - Wang et al., 2014), makes it possible to model the induced electric field distributions in a wider frequency range relevant to Geomagnetically induced currents (GIC) studies. The modelling provides insight into potential geomagnetic induction hazards across Australia due to oceans and inland conductivity structures from the surface to a depth of over 600 km.

Geoscience Australia operates a network of permanent geomagnetic observatories to continuously monitor magnetic field activity in the Australian region. In this proposal we would like to develop a method to derive the induced electric field in time domain using their frequency domain relationship.  

We hope to see you there.

Date: Thursday, 23 February 2017
Time: Drinks and snacks from 4pm followed by the guest speaker presentation at 4:30pm.
Location: Sir Harold Raggatt Theatre, Geoscience Australia, Symonston, ACT

Title: Accelerating Australian CCS Demonstration Projects Through Focused Research & Development

Abstract:

Since its inception in 2010 ANLEC R&D has deployed a CCS research effort in excess of $100 million dollars. This partnership jointly funded by the Australian Government and Australian Coal Industry will continue. Currently it has completed 55 research projects and 29 current projects with 70 technology reports over both capture and storage research objectives. Early projects focused on cost reduction and adaptation of CO₂ capture processes in Australian conditions with particular focus on the successful Callide Oxy-fuel Demonstration and the environmental implications of post-combustion solvent capture. The Australian research priority has now shifted to sub-surface CO₂ storage in three Australian basins: Gippsland Basin, Perth Basin, and the Surat Basin.

This talk will focus on the imperative of emissions reduction, research management processes and examples of the subsurface research.

Biography:

Kevin Dodds is the General Manager of ANLEC R&D. Prior to his current position Kevin had various research management positions, recently as Lead Geological Integrity and Monitoring BP Alternative Energy (Houston), monitoring manager CO2CRC  Otway and Geophysics research manager CSIRO Petroleum in Perth. He spent 20 years with Schlumberger as a Regional Geophysicist in the Middle East and  Europe and global borehole geophysics coordination at HQ Paris. Kevin is an active  member of the ASEG.

3C Seismic and VSP: Converted Waves and Vector Wavefield Applications 

http://www.seg.org/professional-development/courses/disc

Abstract

3C seismic applications provide enhanced rock property characterization of the reservoir that can complement P-wave methods. The continued interest in converted P- to S-waves (PS-waves) and vertical seismic profiles (VSPs) has resulted in the steady development of advanced vector wavefield techniques. Shear waves are coupled with P-waves, and although they do not respond to fluid properties of the medium they are nevertheless very sensitive to anisotropy and provide direct estimates of shear moduli (rigidities).  When the full elastic response is recorded in a VSP survey, vertical components of the wavefield are obtained to calibrate surface 3C seismic data in depth. PS-wave images along with VSP data can be used to help P-wave interpretation of structure in gas obscured zones, of S-wave impedance and density characterization in unconventional reservoirs for lithology and elastic property discrimination, and of fracture characterization and stress monitoring from S-wave birefringence analysis. The course will give an overview of 3C seismic theory and practical application: from fundamentals of PS-waves and VSPs, through to acquisition and processing including interpretation techniques. The emphasis will be on unique aspects of vector wavefields, anisotropy, and the important relationships that unify S-waves and P-waves. Various applications and case studies will demonstrate image benefits from PS-waves, elastic properties from joint inversion of amplitude variations with offset/angle (AVO/A), and VSP seismic methods for improved reservoir characterization.

Course Objectives

Students will obtain an understanding of theoretical and practical aspects of 3C seismic and VSP, including how to use PS-wave and vector wavefield data to improve rock property applications, as well as:

• Basics of PS-wave registration, velocities and birefringence (S-wave splitting).
• Elastodynamic processes that generate converted waves and how they relate to elastic rock properties
• Issues of PS-wave asymmetry and illumination, and how 3C surface and VSP wavefields are related
• Unique characteristics of PS-wave processing: time registration with P-waves, S-wave splitting,VP/VS analyses, velocities, and conversion-point gathering.
• Identifying and accounting for potential vector infidelity effects
• Interpretation of converted-wave and VSP wavefields
• Applications of 3C seismic and VSP data for migration and elastic impedance inversion, imaging through gas, fracture/stress characterization, and time-lapse.

Who Should Attend

The course is intended for geophysicists, geologists and engineers. The emphasis is on practical understanding and application of vector wavefields, thus a basic prerequisite knowledge of P-waves is assumed. The course would be most relevant to those currently involved with, or considering the use of AVO/A inversion, fracture/stress characterization analyses, or interpretation in gas-obscured reservoirs.

Summary

The following topics will be addressed in the course:

Introduction:

Definitions and wavefield properties of 3C seismic and VSP data are covered, including anisotropy, coordinate systems, vector wavefields, and S-wave applications.  Challenges our industry has faced in the development of S-wave technology are reviewed to obtain a perspective of the current PS-wave emphasis. 

S-waves and VSP in the 20th century:

An overview of the history and development of S-wave and VSP technology in the 20th century is discussed, including S-wave source development, the influence from P-wave AVO, and the emphasis on vertical transverse isotropy (VTI) and azimuthal anisotropy. Also, the early development of PS-wave and VSP technology is reviewed.

Fundamentals:

A tutorial of the elastodynamic theory of PS-wave generation is described, along with reflection and transmission coefficients, coordinate systems, and polarity standards.  Conversion-point illumination, modeling and interpretation of 3C seismic and VSP, NMO velocity in anisotropic media, and the resolution of PS-waves are also reviewed.

Acquisition:

Basic source radiation patterns, free surface and seabed responses to P- and S-wave arrivals are described as well as source, receiver, and VSP systems. Various 3C acquisition configurations are examined in terms of PS-wave illumination, minimal datasets, and common-offset vector (COV) gathers, including VSP geometries.

Processing and Analysis:

Unique 3C processing steps such as rotation, S-wave statics and splitting analyses are emphasized in addition to noise attenuation, vector infidelity corrections, elastic-wavefield decomposition, common conversion-point gathering, and VP/VS analyses.  Essentials of VSP wavefield separation, anisotropic velocity analyses, and conventional processing are described along with interferometry application.

Imaging and Inversion Applications:

Applications of PS-wave seismic demonstrating anisotropic imaging, velocity model building, and tomography are presented in addition to case studies imaging through gas, and imaging with VSP. Also, various inversion applications are presented: layer stripping for fracture/stress properties and joint AVO/A for rock properties, including unconventional reservoir, microseismic imaging, and time-lapse applications. Current research directions of 3C seismic and VSP include investigations using reverse-time migration, AVAz and full-waveform inversion, near surface velocity model building, distributed acoustic sensing, and rotational sensors.  Business model considerations are discussed along with improving the economic viability of 3C seismic and VSP to increase productivity, and to reduce processing costs and turnaround times.