Post on 18-Jun-2018
Modelling greenhouse policies and oil resource production
Christophe McGlade Tuesday 8th April 2014
Outline
• Motivations and background • Modelling approaches
– TIAM-UCL – BUEGO
• Results – ‘Unburnable’ oil – The importance of considering uncertainty over future
CO2 emissions mitigation
Motivations and background
• UNFCCC entered into force in 1994 and recognised the need to prevent dangerous anthropogenic climate change
– ‘Dangerous’ is a value judgement, but policy makers concluded that the warming should be limited to below 2°C
– This has been explicitly included in the Copenhagen Accord of 2009 and the text adopted by the UNFCCC in Durban
• The IPCC has recently related the likelihood of staying within certain levels of average temperature rise to cumulative emissions of CO2
– Existing reserves (and resources) of fossil fuels vastly exceed the budgets associated with a 2oC rise • However, level of future GHG emissions reductions are only one source of uncertainty
affecting oil and gas projections • Many of the existing models aiming to project oil and gas production and consumption
choose to focus only on one side of the market – Curve fitting – Pure demand side modelling – Consequently cannot take account of real production and market dynamics
• Need to use models that take account of whole energy system (including emissions) to project future oil and gas production and consumption
Example of uncertainty: resource estimates
• Uncertainty in resource estimates arises for a large number of reasons…
– The use of contradictory, ambiguous or inconsistent definitions
– Problems associated with sources that report reserve data
– ‘Political reserves’ – The inclusion of stranded volumes in reserve
estimates – Estimating current and future recovery factors – Differences between methodologies used to
estimate undiscovered oil and gas volumes – Scarcity of reports estimating volumes of Arctic oil
and light tight oil and the prices at which these resources may become available
– Which unconventional oil production technologies will be utilised
– Chosen oil richness cut-off yield for kerogen oil – Functions utilised to estimate volumes of reserve
growth – And many more…
Uncertainty in ultimately recoverable resources of ‘all oil’
Other examples : Cost and GDP/population uncertainty
Production costs have doubled since 2005 Close correlation with oil price
Macro-economic drivers of demand Huge variation in future projections of population and GDP
56789
101112131415
Glo
bal p
opul
atio
n (b
illio
ns) REF
A2R (RCP 8.5)
B1
UN 2011 - med
0
100
200
300
400
500
600
700
800
Glo
bal G
DP
(200
0$ tr
illio
n)
REF
A2R (RCP 8.5)
B1
R² = 0.8401
05
10152025303540455055
0 10 20 30 40 50 60 70 80 90 100 110
Eco
nom
ic c
ost (
nom
inal
$/b
bl)
Oil price (nominal $/bbl)100
120
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200
220
240
2000 2002 2004 2006 2008 2010 2012
Cap
ital c
ost i
ndex
(fro
m 2
000)
• Assumptions over the level of future technological deployment and GHG emissions reduction are also likely to have major effects on projected oil and gas production levels
• Next, how to model these?
TIAM-UCL: bottom-up energy system model
• TIMES Integrated Assessment Model (TIAM) • Dynamic partial equilibrium model with
objective function that minimises total discounted costs
• Technologically detailed bottom-up whoel energy system model with reduced-from climate module
• 16 regions with flexible time horizon through to 2100
• Numerous modifications undertaken to improve fossil fuel modelling including:
– Improving the resources availability and production costs of all fossil fuels
– Introduction of region specific constraints on the growth and decline of conventional oil and gas production to model more accurately empirical and geological factors dictating possible rates of production
– Introduction of new array of Fischer-Tropsch fuels (coal-to-liquids, gas-to-liquids etc.)
The ‘Bottom-Up Economic and Geological Oil field production model’
• TIAM-UCL cannot, however, take account of a number of specific sources of uncertainty including smaller-scale, shorter-term, geopolitical, or more oil-sector specific uncertainties
• Have therefore also developed BUEGO, which incorporates the major economic and geological factors driving oil production at a field level – Demand levels generated by TIAM-UCL – Examine expected behaviour of oil companies developing oil field projects
• Includes 7000 producing, undiscovered, and discovered but undeveloped oil fields
• Existing fiscal regimes of 133 countries • Oil price generated endogenously
0
10
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60
70
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130
2005 2010 2015 2020 2025 2030 2035
OIl
prod
ucti
on (m
bbl/
d)
Developed Undeveloped Reserve growth FallowUndiscovered Arct ic Mined bitumen In situ bitumenExt ra-heavy Light t ight oil NGL Biofuels
Model details • Relies upon existing geological model
containing a detailed representation of each of the 7000 field’s:
– 2P reserves – Potential capacity additions – Natural decline rates
• Have added field level: – Capital costs – Operating costs – Government tax takes – Water depths
• Operation of model – Net present value of each field calculated at an
initially low assumed oil price – Field developed if NPV is positive – Oil price is increased (and so new fields will be
developed) until demand matches supply in a given year
– Model moves on to next year and repeats until 2035
0
10
20
30
40
50
60
70
80
2005 2010 2015 2020 2025 2030 2035
Oil
prod
ucti
on (m
bbl/
d)
AFR_ N AFR_ P AUS CAN CHICSA_ N CSA_ P EEU FSU INDJAP MEA_ N MEA_ P MEX ODASKO UK USA WEU
Demand from TIAM-UCL
Maximum production
With no capital investment
Importance of accounting for government tax take
• BUEGO calculates the tax take at each iteration of the oil price for all potential capacity additions in each year
• Tax takes vary markedly both between and within countries
– E.g. within a given country, tax take can vary for fields of different size, water depth, production potential etc.
• Field-level modelling is therefore needed to understand properly the tax levied by countries (and the NPV of new projects)
• Figure demonstrates the effect of varying the oil price from $70-110/bbl for a field of a fixed size in each country
– Arrows give direction of change – Colours indicate nature of fiscal
regime
0
20
40
60
80
100
120
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2010 2015 2020 2025 2030
Oil
pric
e ($
/bbl
)
Low carbon scenario
New policies scenario
LCS_ OPEC
Example output: ‘Oil price’ generated under a selection of scenarios
• BUEGO results suggest that following an initial peak in 2012 (results suggest) there will be a softening of prices throughout the 2010s
• Whether this will actually happen is another matter…
• Results also suggest that if OPEC restrictions are removed, the oil price would drops by around $15/bbl in 2010s and $25/bbl in 2025
Example output: unburnable oil • To have a reasonable chance of staying below 2oC, going to need to leave some
fossil fuels in the ground • Use BUEGO to help understand that with a global effort to mitigate emissions, how
much oil does not need to be used, and where is this located?
0
10
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2005 2008 2011 2014 2017 2020 2023 2026 2029 2032 2035
Prod
uctio
n (m
illio
n bb
l/d)
AFR_N AFR_P AUS CAN CHI CSA_N CSA_PEEU CIS IND JPN MEA_N MEA_P MEXODA SKO UK USA WEU
0
10
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2005 2008 2011 2014 2017 2020 2023 2026 2029 2032 2035
Prod
uctio
n (m
illio
n bb
l/d)
AFR_N AFR_P AUS CAN CHI CSA_N CSA_PEEU CIS IND JPN MEA_N MEA_P MEXODA SKO UK USA WEU
2oC scenario with CCS 2oC scenario without CCS
Cumulative production
Un-burned reserves
60
23
22
6
6
0 84
52
37
1
127
25
30
0
302 387
123
0
20
3
810 485
Distribution of unburnable reserves when CCS is allowed
Unconventional oil • Assuming different demand levels affects production both on a global level and
within certain countries • E.g. in Canada the switch from a 3.5oC scenario to 2oC severely constrains oil
production – Even then this assumes CCS is available and there is a rapid decarbonisation of the energetic
inputs to unconventional oil production.
0
1
2
3
4
5
6
7
8
2005 2010 2015 2020 2025 2030 2035
Oil
prod
ucti
on (m
bbl/
d)
Developed Undeveloped Reserve growthFallow Undiscovered Arct icMined bitumen In situ bitumen Ext ra-heavyLight t ight oil NGL Biofuels
0
1
2
3
4
5
6
7
8
2005 2010 2015 2020 2025 2030 2035
Oil
prod
ucti
on (m
bbl/
d)
Developed Undeveloped Reserve growthFallow Undiscovered Arct icMined bitumen In situ bitumen Ext ra-heavyLight t ight oil NGL Biofuels
3.5oC scenario – production exceeds 7 mbbl/d in 2035
2oC scenario with CCS – production fails to reach 5 mbbl/d in 2035
-2.0 -1.5 -1.0 -0.5 0.0 0.5 1.0 1.5
CO2
Demand
Availability
Tech dev
Cost
Difference from central scenario (Tcm/y)
High
Low
-30 -20 -10 0 10 20
CO2
Demand
Availability
Tech dev
Cost
Difference from REF (mbbl/d)
High
Low
Differences in oil production in 2050 Differences in gas production in 2050
Effects of uncertainty on production levels
Difference from central scenario (mbbl/d)
• Can test the importance of different major sources of uncertainty using TIAM-UCL
Conclusions and lessons for new oil and gas models
• There are numerous uncertainties that can have a major effect on oil and gas projections – Need to focus on scenarios and not ‘predictions’, particularly changes between different scenarios – Understanding these uncertainties and mitigating them to the extent possible will lead to more robust outlooks – Of all sources of uncertainty examined, uncertainty over future emissions reductions have the most significant effect
on oil production projections. This therefore cannot be ignored. – Different sources of uncertainty have the largest impact on oil and gas projections. Different scenarios need to be
implemented to explore future potential levels for the two commodities – By considering some areas of uncertainty, it may be possible to reduce the sensitivity to other sources of uncertainty
(e.g. if CO2 emissions reduction is considered, then uncertainty over resource potential is less important since much of the reserve base must remain unused)
• Need for a whole systems approach to modelling oil and gas production and consumption within the global energy system
– Curve fitting or simple demand-side modelling are not suitable for producing robust outlooks • Disaggregated (i.e. field-level) modelling is the best method for producing reliable projections
– Tax-take varies on a field-by-field basis. Difficult to calculate what the specific tax take (and hence price required for development to proceed) will be for new projects if modelling at a country or regional scale
– Cost data is more reliable at the field level and easier to model how it depends on components and so might change in the future
– Quality of crude produced is field-specific • Modelling at a more aggregated level (e.g. country or regional) is nevertheless possible, but requires
careful calibration with field-level models – Need to ensure natural decline rates or depletion rate constraints are properly specified – Need to ensure different categories of oil (developed reserves, undeveloped reserves, reserve growth, undiscovered,
Arctic, unconventional, deepwater, NGL etc.) are specified separately (as have very different characteristics and potentials)
Thank you Any questions?
www.ucl.ac.uk/energy
christophe.mcglade.09@ucl.ac.uk
UCL Energy Institute
UCL Institute of Sustainable Resources
+44 (0)20 3108 5961