Sim-SEQ: A Model Comparison Study

Using Results from CO2 Field Tests

Sumit Mukhopadhyay

Jens Birkholzer

Lawrence Berkeley National Laboratory

IEA GHG 1st Combined Network Meeting on Modeling and Wellbore Integrity

April 27, 2010

• Vastly differing time scales for multiphase flow and

geomechanical versus chemical effects

• Processes are coupled and highly nonlinear

• Heterogeneities on different scales

• Sparsity of data in field situations

• Difficult-to-measure and uncertain parameters

Wide range of predictions because of different modeling

techniques, coupling methods, approaches for

multiphase behavior, interpretations of site data

Uncertainty about risk assessment predictions

Challenges in Modeling CO2 Storage

Sim-SEQ

Encourage development of new approaches

and model improvement

Provide a forum for discussion, interaction,

cooperation, and learning among modeling groups

Objectively evaluate model-to-model and model-to-

data, using well defined performance metrics

Demonstrate in an objective manner that the system

behavior of GCS sites can be predicted with confidence

Evaluate model uncertainties and

assess their impacts

A New DOE Initiative on Model

Comparison for CO2 Geologic Storage

Sim-SEQ Is About ….

• Model Evaluation and Comparison Against Measured Data

Examples from Frio test (tomography from

Daley, et al, Env. Geol. 2007)

• NOT Code Comparison and Verification Against Benchmark

Tests

Single-Site Multi-Model Approach

Site AModel

Team 1

Model

Team 2

Model

Team 3

Model

Team 6

Model

Team 7

Model

Team 4

Model

Team 5

• Model teams each develop

individual model for ONE

“selected” site

• Using the same set of

data, teams will use

different codes and model

approaches

• Allows direct comparison

of models and approaches

• Requires additional effort

by model teams, as well as

“host” team and

coordinator

Sim-SEQ: Background and History

• The idea of Sim-SEQ was first floated in 2008

• A full-day workshop was organized at LBNL on

December 16, 2008.

• A short candidate list of suitable sites was developed

• Attempts were made to rank candidate sites based on

certain criteria

• Initiated discussion on performance metrics and

acceptance criteria

Proposed Candidate Sites

RCSP Site Phase Type Injection VolumeExpected Drill

Date

Expected

Injection Start

Data Avail. Before

Injection

MGSC Decatur 3 saline1 Million tons over

3 yearsOngoing Dec-09

Sparse (based on

seismic, few wells)

SECARB Cranfield 3saline near

EOR

1.5 Million tons per

year over 1.5

years

Early 2009 Summer 2009 (?)Moderate to good from

neaby EOR

MRCSP Greenville (TAME) 3 saline1 Million tons over

4 yearsJul-09 2010

Sparse (based on

seismic, few wells)

WESTCARB Kimberlina 3 saline1 Million tons over

4 year2009 2012

Sparse (based on

seismic, few wells)

Big Sky Riley Ridge 3 saline

1 to 3 Million tons

per year for 3

years

Summer 2010 2011Moderate (existing

nearby wells, outcrop)

SWP Farnham Dome 3 saline

Up to 1 Million

tons per year for 4

years

Begins in April

2009Late 2009

Moderate (twelve

existing and 6 new

wells, seismic)

SECARB Cranfield 2 EOR0.5 Million tons per

yearDone Started in 2008

Very good data from

EOR operations

MRCSP Gaylord, Mich. 2 saline 50000 tons over

500 daysDone Ongoing

Sparse (based on

seismic, few wells)

SWP SACROC 2 EOR

0.3 Million tons per

year for 3 to 5

years

Done Started in 2008Very good from 30

years of EOR

Site Ranking Criteria

• Injection volume needed to be in line with industrial-scale

storage projects

• The selected site needed to provide good monitoring data

for plume tracking, pressure changes, and ideally also

geomechanical/geochemical impacts.

• A definite conclusion could not be made about saline

formations versus EOR. However, DOE later expressed a

preference for saline formations, because these would be

more representative of the modeling challenges for the

majority of future carbon storage projects

Sim-SEQ Site Selection

•The workshop ended with the selection of two alternative

sites for Sim-SEQ: the Decatur project (in Illinois) and the

Farnham Dome project (in Utah).

•Both sites became unavailable over the course of the

summer in 2009.

•Sim-SEQ started focusing on SECARB’s Cranfield Phase III

project for model comparison

•Cranfield Phase III was selected for Sim-SEQ in November

2009 during the RCSP meeting at Pittsburg, PA.

•For proprietary reasons, this site would be referred to as

the S-3 Site (Sim-SEQ Study Site)

Louisiana

Arkansas

Alabama

Florida

Tennessee

Mississippi

Texas

OklahomaGeorgia

INTERIOR SALT

BASIN PROVINCE

Sabine

Uplift

Wells shown only in

Tuscaloosa-Woodbine

Cranfield

CO2

The Sim-SEQ Site

Southern

Company Sites

Acknowledgment: JP Nicot, BEG

Acknowledgment: JP Nicot, BEG

Phase II

Phase III

•The Sim-SEQ site is

patterned from

Cranfield, site but

with simplified data

set

• It is an EOR site but

Phase III is in the

brine leg down dip of

the reservoir

• Phase II was in the

reservoir

Sim-SEQ: Current Status

•In December 2010, BEG delivered the first part of the Sim-

SEQ data set.

•Scientists from PNNL and LBNL worked together to develop

a web portal for Sim-SEQ based on the GS-3 platform

developed by PNNL.

•The purpose of the Sim-SEQ web portal is to

-provide modeling teams with relevant input and

monitoring data

-help modeling teams in information dissemination

-assist in model evaluation and comparison

-promote exchange of information and ideas

Sim-SEQ Kick-Off Meeeting

•A kick-off meeting for Sim-SEQ took place on April 20 at

LBNL.

•The Sim-SEQ web portal was launched

(https://gs3.pnl.gov/simseq/wiki) - this is a password

protected site, with access given to Sim-SEQ participants

only

•Five modeling teams (University of Utah, Sandia National

Labs, PNNL, LBNL, and BEG University of Texas, Austin)

have joined in the Sim-SEQ model comparison studies

•It is expected that few more modeling teams will join soon

•Input data evaluation is in progress – actual modeling

work to commence in few weeks’ time

Iterative Model Improvement

• Simulation Model

• Observations from Field Tests

Predictive

SimulationsData Feedback and

Iterative Model Improvement

“Sufficient” Agreement

A Collaborative Effort: YES

Sim-SEQ

Simulation Model

Observations

LBNL

Simulation Model

Observations

PNNLSimulation Model

Observations

Utah

Simulation Model

Observations

BEG

Simulation Model

Observations

Sandia

Simulation Model

Observations

????

Sim-SEQ Organization

LBNL-Team:

Manages and coordinates

model evaluation effort

Sumit Mukhopadhyay

Jens Birkholzer, Support Staff

Sim-SEQ Technical Team:

Comprises modeling team members

Convenes regularly via video-

conferences and workshops

Provides main venue for presentation,

discussion, and evaluation of models

and results External Scientific

Advisor: TBA

Multi-Year Effort During Phase III

Integrated in and coordinated with National Risk Assessment Program

and Simulation and Risk Assessment Working Group

LBNL RoleLBNL-Team:

Manages and coordinates model evaluation effort

– Establish Sim-SEQ Technical Team

– Organize and facilitate Technical Team videoconferences and workshops, host a web site for sharing of data and presentations

– Perform status review of Phase III model plans, including model approaches, schedules, and code capabilities

– Develop modeling performance metrics for comparison of predictions and measurements

– Conduct timely review and evaluation of model results

– Mediate discussion about model improvement and develop list of lessons learned

– Summarize model comparison results in annual reportsTechnical Team will be involved in all activities listed above

•International GCS programs may benefit from a

demonstration that system behavior can be reliably predicted

•The Sim-SEQ initiative may help convince stakeholders that

the subsurface processes expected in response to CO2

storage are sufficiently well understood with a knowable

degree of confidence.

•As a byproduct, insights into the complex behavior of saline

formations used for CO2 sequestration will be gained

•Development of new modeling approaches will be fostered.

•Participating teams will benefit from the open and

cooperative environment, which ensures that lessons learned

and improvements made will be shared among researchers.

International Participation?

International Interest?

Please contact: Sumit Mukhopadhyay

SMukhopadhyay@lbl.gov

https://gs3.pnl.gov/simseq/wiki

http://esd.lbl.gov/research/projects/sim-seq

Sim-SEQ: Summary

Forum for discussion, interaction, cooperation, and

learning among modeling groups

Facilitated by LBNL

Emphasizing the common goal of improving model

predictions and objectively demonstrating to

stakeholders that GCS can be safe

Open to international participation