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Transcript
Future Scenarios for
China’s Carbon Emissions
Jim Watson and Tao Wang
Kennedy School of Government, Harvard University, 7th July 2008
Sussex Energy Group
SPRU - Science and Technology Policy Research
Overview
1 Energy and emissions trends in China
2 Who owns China’s emissions?
3 Future emissions scenarios
•
Explaining our approach
•
Application to China (so far …)
4 Conclusions
Sussex Energy Group
SPRU - Science and Technology Policy Research
Global trends and developing
countries
According to the IEA World Energy Outlook 2007:
• World primary energy demand will grow 55% between 2005 and
2030: From 11.4 billion toe to 17.7 billion toe
• 74% of this increase will be due to growth in developing
countries; 45% from China and India
• The developing country share of global energy demand will
increase from 41% in 2005 to 47% in 2015, and over 50% in 2030
• China and India account for 45% of world coal demand. These
countries will account for over 80% of the increase in coal
demand to 2030
Sussex Energy Group
SPRU - Science and Technology Policy Research
m tonnes of coal equivalent
Recent trends in China
Primary energy demand
2000
Primary energy demand in China
1500
1000
500
0
1980
Coal
1983
Oil
1986
1989
Gas
1992
1995
1998
Hydro & Nuclear
Sussex Energy Group
SPRU - Science and Technology Policy Research
2001
2004
Total
Recent trends in China
Power generation capacity
800
Capacity (GW)
700
• 2006 capacity reached 622GW (484GW coal)
• 2007 capacity reached 713GW (530GW coal)
600
500
400
300
200
100
0
1980
1985
Fossil
1990
Hydro
1995
Nuclear
Sussex Energy Group
SPRU - Science and Technology Policy Research
2000
Wind
2005
Total
m tonnes of carbon (mtC)
Recent trends in China
Carbon emissions
2000
1800
1600
1400
1200
1000
800
600
400
200
0
1980 1982 1984 1986 1988 1990 1992 1994 1996 1998 2000 2002 2004 2006
CIDIAC
Sussex Energy Group
SPRU - Science and Technology Policy Research
Dutch EPA
Emissions (m tonnes of Carbon)
National carbon emissions in 2007
Estimates (Dutch EPA)
2000
1800
1600
1400
1200
1000
800
600
400
200
0
China
USA
EU
Sussex Energy Group
SPRU - Science and Technology Policy Research
India
Russia
Per capita emissions in 2007
Estimates (Dutch EPA)
Emissions (tonnes of Carbon)
25
20
15
10
5
0
China
USA
EU
Sussex Energy Group
SPRU - Science and Technology Policy Research
India
Russia
China also faces serious climate
change impacts
• Chinese studies project a range of impacts, e.g.
– Decreases in agricultural yields and increased costs of food
production
– Decreased run-off of rain water in northern China; increased runoff in Southern China. Adds to water imbalance that is already
causing problems
– Expected increases in storms; vulnerability of prosperous coastal
zones (e.g. Shanghai) to small sea level rises
• As a result, climate change taken increasingly seriously at
national level – focus is reducing energy intensity
• Government has a climate change co-ordinating group and has
produced a climate change strategy
Sussex Energy Group
SPRU - Science and Technology Policy Research
But who owns these emissions?
• The extent to which
carbon emissions in
China should be ‘owned’
by China has been the
subject of much debate
• China has emerged as a
major trading economy –
with a rapidly growing
trade surplus with the
developed world
• How much of China’s
carbon footprint is due to
its exports?
Sussex Energy Group
SPRU - Science and Technology Policy Research
Who owns China’s emissions?
• Headline results:
– Emissions from exports in 2004 :1490 million tonnes of CO2
– Emissions avoided due to imports: 381 million tonnes of CO2
– Combining these, 23% of China’s emissions due to net exports
• One reason is large (& growing) trade surplus: tripled between
2004 and 2005 to $102bn, rose again to $177 bn in 2006, and
over $250bn in 2007
• Another reason is relatively high carbon intensity of Chinese
economy. In 2000, the US produced 0.5 kg CO2 per dollar of
economic activity whereas China produced 2.76kg per dollar
• This result challenges production-based emissions targets,
and suggests that consumption-based targets could be better
Sussex Energy Group
SPRU - Science and Technology Policy Research
Who owns China’s emissions?
1800
Emissions in 2004
(m tonnes of C)
1600
1400
US
China
1200
1000
800
600
400
China's Net
Exports
200
0
Sussex Energy Group
SPRU - Science and Technology Policy Research
Japan
UK
Analysing future emissions
A carbon budget approach
• The main aim of our Tyndall Centre project is to develop a set of
scenarios to explore future carbon emissions in China – and
analyse implications
• There are a number of scenario options – e.g. exploratory or
more goal-driven
• We are using a cumulative emissions method so scenarios meet
a specific target; used previously by Tyndall for the UK
• Tyndall’s scenario tool enables us to quantify possible trends in
different Chinese sectors (e.g. transport & households)
• Collaborating with organisations in the UK & China, including
workshops in Beijing and London to discuss key features
Sussex Energy Group
SPRU - Science and Technology Policy Research
Why cumulative emissions?
The UK Climate Change Bill
Sussex Energy Group
SPRU - Science and Technology Policy Research
Why cumulative emissions?
Tyndall UK scenario for 450ppm
Budget:
4.6 GtC
Sussex Energy Group
SPRU - Science and Technology Policy Research
Analysing future emissions
A carbon budget approach
• We have used IPCC Assessment Report 4 global budget
– 490GtC for 21st century
– Stabilise at 450 ppm CO2
– Likely range of 1.9-4.4°C temperature rise
• Two different approaches to deciding China’s cumulative
emission budget for this period:
– Equal carbon emissions per capita
– Equal carbon emissions intensity of GDP
• Two medium-term pathways to connect these budgets to
current policy analysis
Sussex Energy Group
SPRU - Science and Technology Policy Research
Analysing future emissions
Medium term pathways
• Critical issues for Chinese policy (& identified in our
workshops) is change in industrial structure & innovation
• Challenge for China is ‘rebalancing growth’
– Away from energy intensive investment …
– Away from export-led growth …
– … towards domestic consumption; value added; innovation
• Medium term pathways rebalance with different speeds / extents
– IEA ‘Alternative Policy’ scenario. Includes some policies but is
conservative about possible shift in emissions pathway
– ERI scenario B (2004) includes govt efficiency targets, shift from
heavy industry etc. Gives ambitious emissions goal for 2020
Sussex Energy Group
SPRU - Science and Technology Policy Research
Analysing future emissions
Medium term pathways
We will … promote the shift from the pattern of economic
growth that relies mainly on investment and exports to one
that relies on a balanced combination of consumption,
investment and exports.
Haphazard investment and unneeded development projects in
energy intensive and highly polluting industries and
industries with excess production capacity will be resolutely
stopped.
Wen Jiabao, March 2008
Sussex Energy Group
SPRU - Science and Technology Policy Research
Analysing future emissions
Medium-term pathways
3000
Emissions (mtC)
2500
2000
1500
1000
500
0
1990 2000 2010 2020 2030 2040 2050 2060 2070 2080 2090 2100
Actual
ERI Scenario B
Sussex Energy Group
SPRU - Science and Technology Policy Research
IEA 2007 Alt
Analysing future emissions
From medium to long-term
• Calculated budgets from 490GtC (global) using two methods
– Per capita gives 70GtC for China (UN population projections)
– Per unit of GDP gives 111GtC for China (IEA growth projections)
• Turning points in 2020 and 2030
– Pre 2020 thought to be too early / ambitious
– Post 2030 risks running out of budget
• Adjustment to lower per capita budget to make it compatible
with higher medium-term pathway. Raise to 90GtC.
Sussex Energy Group
SPRU - Science and Technology Policy Research
Analysing future emissions
From medium to long-term
3000
Emissions (mtC)
2500
2000
1500
1000
500
0
1990 2000 2010 2020 2030 2040 2050 2060 2070 2080 2090 2100
Actual
IEA 2007 Alt
ERI Scenario B
90GtC
70GtC
111GtC
Sussex Energy Group
SPRU - Science and Technology Policy Research
111GtC
Analysing future emissions
Our four scenarios
Scenario 1
Scenario 2
Scenario 3
Scenario 4
Cumulative
budget
70GtC
111GtC
90GtC
111GtC
Medium-term
pathway
ERI
ERI
IEA
IEA
Year of peak
2020
Low Peak 2030
2020
2030
GDP growth
rate
2-4%
5-8%
4-6%
2-8%
Population
growth rate
UN 2004 prediction
Sussex Energy Group
SPRU - Science and Technology Policy Research
Analysing future emissions
Our four scenarios
Scenario 1
Scenario 2
Scenario 3
Scenario 4
Economic &
industrial
Structure
Service sector
dominant /
Moderate
service sector
Service sector
largest
Service &
industry strong
moderate
industry; mostly
‘innovative’
Strong
‘innovative’
industry
Strong trad
industry; some
‘innovative’
Traditional
manufacturing
dominant
Nature of
innovation
Radical
Radical
Significant
Incremental
Slower diffusion
than scenario 1
Incremental
Focus on legacy
industries
Sussex Energy Group
SPRU - Science and Technology Policy Research
Analysing future emissions
Our four scenarios
Scenario 1
Scenario 2
Scenario 3
Scenario 4
Energy
demand
Slow growth
Moderate growth
Moderate growth
High growth
Primary
energy
priorities
Renewables
Renewables
Nuclear
Fossil fuels
Fossil fuels or
nuclear
Fossil fuels
Fossil fuels
Nuclear
Renewables
Renewables
Energy
demand
Stringent
efficiency
standards; quick
behaviour
change
Moderate
standards
Slow efficiency
progress
Incremental
efficiency
Slower change
in behaviour
Significant
behaviour
change
Slow behaviour
change
Sussex Energy Group
SPRU - Science and Technology Policy Research
Analysing future emissions
Some emerging issues
• Some technologies / options may be critical
– Hard to see how CCS can fail to be critical: speed of
implementation and extent may vary
– We may need ‘reality check’ on transport: e.g. balance of
efficiency and low carbon alternatives to oil
• Changes in institutions and governance are not developed
enough within scenarios, e.g.
– Energy decentralisation more than a technical phenomenon
– Extent to which behaviour change is possible
– Relationship between central, provincial and local govt
– Relative strength of environmental vs economic policy
Sussex Energy Group
SPRU - Science and Technology Policy Research
Next steps
• Draft working paper summarises scenarios so far: comments
are welcome
• Iterative process with spreadsheet tool so changes in
emissions in different sectors fit within overall carbon budget
• Identify critical areas for early action that are common across
most scenarios
• Develop policy implications: for China and for international
community (especially UK)
• Launch of final results in early 2009
Sussex Energy Group
SPRU - Science and Technology Policy Research
Thanks
http://www.sussex.ac.uk/sussexenergygroup
Sussex Energy Group
SPRU - Science and Technology Policy Research