Post on 31-Oct-2018
Carbon Sequestration Forum VIII
The State of Geological Storage of CO2
SF 13th & 14th November 2007
Dr John BradshawGeoscience AustraliaChief Scientist CCS
Scaling Up Geological Storage
Australian Government
Geoscience Australia
,
Scale Up Themes• Emissions• Policy & Legal• Geology & Engineering• Animal Kingdom• Rocks & Wells & Things• Conclusions
“ Scaling Up Geological Storage of CO2”
The Scale of the emissions ?
Issue 1: The longer we hesitate, the more the emissions scale
up?
What is the magnitude of the problem
• Australia’s total CO2 eq emissions > 560 Mt/yr ~ 10 TCF/yrper annum
• Large stationary point sources - 50 % - 280Mt /yr ~ 5 TCF /yr{LSPS} (power stations, gas plants, etc)
• Emissions for USA {LSPS} 2000Mt/yr ~ 40 TCF /yr
• World total CO2 eq emissions ~>28 Gt ~ 520 TCF /yr
• That’s a lot of pore space to find ………..• and keep finding ………….. per year
• Australian gas production – 1.3 TCF / yr• USA Gas production – 22.3 TCF / yr• World gas production – 100 TCF / yr
• World reserves & produced gas (total) 6349 TCF
1 TCF Gas field is a “big” gas field
Permeability•1621 to 3252 mD(locally)
•1100 to 8140md regionally
Porosity•36 to 40%
Size26,0002 km 100s yrs emissions
Scaling Up Policy & Legal
Issue 2: This is way bigger than people
anticipate?
Petroleum Leases versus areas of interest for Storage
Injection scenarios?
• Consider how the following scenarios (geo-cartoons to follow) impact on;• technical, regulatory and legal aspects?
• Structural (physical) trapping• Chemical trapping• Migration pathways• Pressure transmission
Conceptual CO2 Storage Scenariodepleted field / structural trap
Trap Structure
(template slide courtesy of Robert Root)
Assigning permits relatively easy – tightly constrained
But what if hydrocarbon discovery already exists, or believed to exist in structure? EOR -Sequenced development?
Or hydrocarbons found later - Which operator? – Who gets priority?
Conceptual CO2 Storage Scenariohydrodynamic / residual gas / solution trap
Trap Structure
(template slide courtesy of Robert Root)
Where do you put permit boundaries ?
How big do you make permits?
What access rights do you employ?
What if there are two storage operators – co-mingling of CO2?
Fault
Injection area
Injection & migration area
But technically we can do it?
Issue 3: We’ve said we can technically do it – so we better
be right?
Note: map excludes industrial point sources
Qld: 896 Mt;16.7 Tcf;2290 MMcf/d.
NSW: 1167 Mt;21.8 Tcf;2986 MMcf/d.
Vic: 1185 Mt;22 Tcf;3014 MMcf/d.
SA: 180 Mt;3.4 Tcf;466 MMcf/d.
WA: 411 Mt;7.7 Tcf;1055 MMcf/d.
NWS: 386 Mt;7.2 Tcf;986 MMcf/d.
NT:9.2 Mt;0.2 Tcf;27 MMcf/d.
Stationary energy point sources
Unproduced large gas fields with high CO2 %
KEY
1 TCF CO2 = 53.65 Mt = 28.3 BCM
Summary of Emissions, Economics & Geological Risk
Viable –but not optimal
reservoirs?
Very good reservoirs? Distant from
major sources
Superb reservoirs. But, require
offshore development?
Large emissions –
“No reservoir”
These types of scenarios will be repeated around the world
20 year emission map
Reservoir/Seal relationship. Proximal to sources?
Poor reservoirs. Source distance?
What about where Storage won’t scale up locally?
• Oil & Gas Resources “uneven distribution”• Long Pipelines• Ship Transport• Right strategy needs implementing based
on reality of local geology• Long Pipelines & Ship• Non-coal energy source
• The value placed on CO2 will influence the above
This is just a technical (science & engineering) challenge .. isn’t it?
... plus getting the economics right to do it …
Let’s look at recent such engineering and science
challenges
Issue 4: The following example left a legacy that will be hard to emulate in our “modern world”
Australia’s Snowy Mountain Hydroelectric Scheme
• Obtaining extra irrigation• Expanded to integrate a hydro-electric
power supply• The project is the single greatest
engineering project Australia has ever known and possibly will ever know.Source : www.australianhistory.org/post-federation.php
• Australian psyché – turned riversaround
Australia’s Snowy Mountain Hydroelectric Scheme
• 1949 – 1974 : 25 years : NSW, VIC, SA, Commonwealth
• 100,000 men and women • 30 countries – 121 killed
• 16 large dams, 7 power stations, 1 pumping station, 31 generators
• 145 km of trans-mountain tunnels & 80km aqueducts
• 7000 G litres water storage – dry??• 5100 GWh of electricity• Rock Bolting invented
• mining industry adopted• International Historic Civil Engineering Landmark
• Eiffel Tower, Panama Canal, Sydney Harbour Bridge
Stationary energy point sources
Unproduced large gas fields with high CO2 %
KEY
Achieve 34% of 2006 emissions avoided
41 Mt/y
26 Mt/y
51 Mt/y
77 Mt/y
25 Mt/y
CCS tomorrow would require• A network handling 3 times existing NG flows• 50% increase in electricity generation (NGCC)• 45% increase in natural gas production (supply)• 22 times Australian pipe line production• Total capital ~ A$ 90 Bn (2005)• Operating cost ~ A$ 7 Bn/yr (2005)
From : Neal, P.R., “The Economics of CCS Networks”, Presented at SPE Applied Technology Workshop (ATW)“Capture and Geological Storage of CO2”,
Perth, Australia, 7-10 October 2007
“ ….. single greatest engineering project Australia has ever known and possibly will ever know ……. “
… till now …
CCS in Australia ~ 2 to 3 times bigger (financially)
Scaling it up in the animal kingdom ?
What contributions do ruminants make to CO2 eq
emissions?
Issue 5: Unexpected flow on effects
Livestock CO2 eq Emissions
Population(millions)
Animal
1350 cattle165 buffaloes1058 sheep720 goats908 pigs
Total CO2 eq emissions ~ 1,680 Mt
Theoretically, by swapping Cattle to Kangaroo meat worldwide could save ~ 1.7 Gt CO2 eq
Australia proportion of world land surface area 5%
Productivity factor of Australian grasslands 1 : 10
Grazing Intake of cows to kangaroos 1 : 16
Kill weight cattle to Kangaroos : 300kg to 15 kg 20 (3 years vs 2 years to maturity)
Number of Kangaroos to replace domestic livestock meat (million)
Multiplier on Australian Kangaroo Population 57
Percentage World land mass access required 28%
“Kanga-Burgers” : Technical CriteriaAustralia kangaroo population (million) 150
8,492
What are the upside flow on effects?
• Better Land Care• not hard hooves
• More drought tolerant species• Can rapidly breed up• Very good lean meat
• But there are also downsides
Don’t underestimate flow on effects !
“Shoo-Roo” : Sonic Kangaroo Repeller
World Car Fleet
• ~ 900 million• “Shoo Roo” = $5 each• $4.5 billion industry
• Beware less obvious flow on effects & detail
Get back to familiar ground?
“Scaling it up” - Reservoir distribution
Channel Sands (Reservoir)
Overbank shales & mud (Seal)
Cut-off channel sands (billabong) –mud and sand
Highly variable reservoir and seals
Non-marine (fluvial Facies)
Braided Stream Deposits
1. Channel sands2. No continuous sealing
surfaces.3. Multiple vertical
migration path for buoyant fluids
SandstoneSiltstone
Can we model such complex and tortuous migration pathways ?Are our reservoir simulators up to it?How many wells required to fill this pore space
Injection Point
•Tidal sands + deltaic sequences
Ideal Reservoirs
•Extensive
•Thick
•Stacked reservoirs
•Good quality
•Intraformational seals
•Offshore
Reservoir & seal
Doust & Omatsola 1990; Cohen & McClay 1996
Niger Delta Ceduna delta
Numerous oil fields
Listric faults
Smaller field sizes and geomechanics issues
Gippsland Basin
Fine grained marine sediments = seal
Beach sands = extensive reservoir
Beach sands = extensive reservoir
Organic rich mud & siltOrganic rich mud & siltin coastal swampsin coastal swamps= coal & seal & poor reservoir = coal & seal & poor reservoir
Extensive aeoliansandstones Localised meandering channel
sands – inter-connected and isolated
Regional marine & coastal sandstones and shales Alternating interdistributary
bay deltaic sands and muds
Depositional Environments
• Highly variable • But predictable • Need good modern analogues to
compare to the ancient rocks• Conventional Petroleum Geology
production issues• Normal Reservoir Engineering
challenges
If we scale up – the detail in the rocks is where the real battle will be fought !
What about the number of wells required?
Issue 6: This is something we must pay a lot of attention to
… it could be embarrassing (costly) if we get this one
wrong ….
INJECTION REQUIREMENT
Mt CO2 / year
t CO2 / day
x 106 cu ft / day
No. of Wells
Reservoir Quality
Wells for 1200 MW
PP
Sleipner 1 2,740 51
Small Power Plant (~600MW) 5 13,699 255
Monash Project 13 35,616 664
"Best" Coal Storage Pilots
0.002 to 0.007 6 to 20
0.11 -0.37
In Salah 1 2,740 51
Large Power Plant (~1200MW) 10 27,398 510
North Rankin Gas Field (Gas
Production flow rate)Up to 200
Very very poorSuperb
1600 - 3000 mDVery Poor 5 - 45mD fractured
Superb multi D
Superb multi D
Good 150 - 250 mD
Good 150 - 250 mD
25
50
531
10
30
50
50
2.3
2.5
Exists – Proposed – Modelled – Problematic
No.’s of Wells vs Reservoir Quality
Prudhoe Bay ~ 88 eq ~240,000 4473Very Good
300 mD (to D’s)38
(323) 5
Highly dependent on;•Depth and age•Environment of deposition •permeability x thickness,• assumption production ~ injection rates• vertical vs horizontal wells,• reservoir stimulation &• onshore vs offshore costs and limitations• reservoir heterogeneity and continuity (capacity)• multiple perforations• long term reliability / deliverability ????
Fluvial - old, ~ 2000m
Marine: mass flow - young, 1200m
Coal
Deltaic - 2000m
Marine - young, 2500m
Fluvial - 2500m
Fluvial - 2500m
Deltaic, aeolian -2000m
Environment, Age & Depth
1
1
3 (2) (horiz
3 (7?)
1
?
Conclusions
• Scaling up Issues include;• Policy, Technical, Legal, Regulatory &
Financial• … and their interactions ….• Beware of;• Well numbers, …. and• Unexpected flow on effects ?