Teaching Ecological Economics: Climate, Energy, Water International Society for Ecological Economics Washington, D.C. June 29, 2016 Jonathan M. Harris and Anne-Marie Codur http://ase.tufts.edu/gdae Copyright © 2015 Jonathan M. Harris
Welcome message from author
This document is posted to help you gain knowledge. Please leave a comment to let me know what you think about it! Share it to your friends and learn new things together.
Transcript
Teaching Ecological Economics:
Climate, Energy, Water
International Society for Ecological Economics
Washington, D.C. June 29, 2016
Jonathan M. Harris and Anne-Marie Codur
http://ase.tufts.edu/gdaeCopyright © 2015 Jonathan M. Harris
Figure 18.1 Carbon Emissions from Fossil Fuel Consumption, 1860-2010Source: Carbon Dioxide Information Analysis Center (CDIAC), http://cdiac.ornl.gov/trends/trends.htm, accessed
November 2013.
Figure 18.3: Per-Capita Emissions of Carbon by
Country
Source: U.S. Department of Energy, International Energy Annual 2008.
17.62
9.19 9.26
5.73
6.52
4.07
2.41
1.45
0.37
0
5
10
15
20
UnitedStates
Germany Japan France China Mexico Brazil India Bangladesh
Met
ric
Ton
s o
f C
O2
Pe
r C
apit
a
0
2
4
6
8
10
12
1980 2000 2020 2040 2060 2080 2100 2120
Ca
rbo
n E
mis
sio
ns
(B
illio
n T
on
s C
arb
on
)
Year
550 ppm
450 ppm
Figure 18.10 Carbon Stabilization Scenarios (450 and 550
ppm CO2) Source: Adapted from Climate Change 2001: The Scientific Basis, http://www.ipcc.ch/
Figure 3: Business as Usual, Paris Pledges, and 2° C Path
Source: http://www.nytimes.com/interactive/2015/11/23/world/carbon-pledges.html?_r=1
Can Renewable Energy Provide a
Solution to Climate Change?
• Long-term link between economic growth and carbon
emissions
• Need to “decouple” economic activity from carbon
emissions
• Micro issues: Market pricing and policy actions
determine speed of transition
• Macro issues: An end to growth, or a new kind of energy
economy? Or both?
Global Energy Consumption by Source, 2012
Source: International Energy Agency (IEA 2013)
Oil31.5%
Coal28.8%
Natural Gas21.3%
Nuclear 5.1%
Hydropower 2.3%
Biomass 10.0%
Wind, solar, geothermal
1.0%
Availability of Global Renewable Energy
Source: Jacobson and Delucchi (2011); U.S. Energy Information Administration;
Stanford Engineering News, http://engineering.stanford.edu/news/wind-could-meet-many-times-world-
total-power-demand-2030-researchers-say
Energy Source
Total Global
Availability (trillion
watts)
Availability in Likely-
Developable Locations
(trillion watts)
Wind 1700 40 – 85
Wave > 2.7 0.5
Geothermal 45 0.07 – 0.14
Hydroelectric 1.9 1.6
Tidal 3.7 0.02
Solar photovoltaic 6500 340
Concentrated solar power 4600 240
Total global energy use in 2006: 15.8 Trillion Watts
Infrastructure Requirements for Supplying All Global
Energy in 2030 from Renewable Sources
Source: Jacobson and Delucchi (2011).
Energy Source
Percent of 2030
Global Power
Supply
Number of
Plants/Devices Needed
Worldwide
Wind turbines 50 3,800,000
Wave power plants 1 720,000
Geothermal plants 4 5,350
Hydroelectric plants 4 900
Tidal turbines 1 490,000
Rooftop solar PV systems 6 1.7 billion
Solar PV power plants 14 40,000
Concentrated solar power
plants
20 49,000
TOTAL 100
Land requirement: about 2% of total global land area.
(Can be combined with agricultural uses)
Global Potential for Energy Efficiency
Source: Blok et al. (2008) Global status report on energy efficiency 2008. Renewable Energy and Energy
Efficiency Partnerships. www.reeep.org
Oil28%
Coal29%
Natural Gas22%
Nuclear6%
Hydro-power
3%
Business As Usual ScenarioTotal Demand: 18,048 Mtoe
Non-Hydro
Renewables
12%
Oil26%
Coal17%
Natural Gas20%
Nuclear11%
Hydro-power
3%
Aggressive Climate Change Scenario Policy
Total Demand: 14,920 Mtoe
Non-Hydro
Renewables
23%
Source: International Energy Agency, 2011.
Projected 2035 Global Energy Demand, by Source
Growth of Solar PV and Wind Installations (2003-2012)
Source: Worldwatch Institute (2014).
$0 $50 $100 $150 $200 $250
Nuclear
Coal
Gas combined cycle
Hydroelectric
Wind-offshore
Wind-onshore
Solar thermal electricity
Solar PV, utility scale
$/MWh
Levelized Cost of Electricity for New Generation
EIA Lazard
Sources: http://www.lazard.com/perspective/levelized-cost-of-energy-v8-abstract/
http://www.eia.gov/forecasts/aeo/electricity_generation.cfm
0 2 4 6 8 10 12 14
Wind
Photovoltaics
Hydropower
Biomass
Nuclear
Natural gas
Oil
Coal
Eurocents per kilowatt-hour
Externality Cost of Various Electricity Generating Methods,
European Union
Source: Owen, A. D. 2006. "Renewable energy: externality costs as market barriers."
Energy Policy 34: 632-642.
Solar Energy Price Decreases, 1998-2013
Source: Barbose, G., S. Weaver and N. Darghouth. 2014. Tracking the Sun VII: an historical
summary of the installed price of photovoltaics in the United States from 1998 to 2013. SunShot
Initiative, U.S. Department of Energy
Projected further decreases in solar costs, 2015 - 2040
Source: Feldman et al 2014. Photovoltaic System Pricing Trends: historical, recent, and near-term projections. U.S.
Department of Energy SunShot Initiative: http://www.nrel.gov/docs/fy14osti/62558.pdf
Source: Solar Energy Industries Association, 2014. “Solar Energy Facts: 2014 Year in Review”.
http://www.seia.org/sites/default/files/Q4%202014%20SMI%20Fact%20Sheet.pdf
Declining Energy Intensity in Industrial Economies, 1991-2008
0.6
0.65
0.7
0.75
0.8
0.85
0.9
0.95
1
1.05
1.1
1991 1993 1995 1997 1999 2001 2003 2005 2007
Canada
United States
Germany
United Kingdom
France
Italy
Japan
Source: US Energy Information Administration (EIA), 2011.
Ene
rgy
Inte
nsi
ty-
Btu
pe
r Y
ear
20
05
U.S
. D
olla
rs (
19
91
bas
e y
ear
)
Year
Source: EIA 2013.Source: EIA 2012.
90 unitscarbon-based
100 units carbon-based
2015 2035
Renewables 10 units
Renewables 20 units
100 units total
120 units total~1% p.a. growth in energy demand
Copyright © 2015 Jonathan M. Harris
Business as Usual Scenario
90 unitscarbon-based 60 units
carbon-based
2015 2035
10 units
Renewables 20 units
100 units total
80 units total
~1% p.a. decline in energy demand
Copyright © 2015 Jonathan M. Harris
Based on modest investment in services, efficiency, renewables, with no loss in employment (probably a gain)
Services, Efficiency, & Renewables Scenario
Source: US Department of Energy, 2013
Accessed at: http://www.eia.doe.gov
Decline since 2007: 12%
US CO2 Emissions, 1990-2014
Source: US Department of Energy, 2016
Accessed at: http://www.eia.doe.gov
Reduction in population growth rates and in GDP growth rates could accentuate this
trend, and will be necessary to meet carbon targets, but there is a lot of scope for
energy and carbon intensity reduction.
Although 2012 was unusual, it shows the pattern of declining emissions: growth in
population and per capita output were outweighed by decreases in energy intensity (energy
use per dollar of GDP) and carbon intensity (carbon emissions per unit of energy use).
CARBON
INTENSITY
PERCENT CHANGES IN EMISSIONS DRIVERS, 2012
ENERGY
INTENSITY
PER CAPITA
OUTPUT
POPULATION
percent change
A good trend, but needs
continuing….
Source: U.S. Energy Information Administration, Annual Energy Outlook 2009 - 2013
ARRA2009 denotes the American Recovery and Reinvestment Act of 2009.
Public Energy R&D Investment
0
2000
4000
6000
8000
10000
12000
1975 1980 1985 1990 1995 2000 2005 2010 2015
Mill
ion
s o
f 2
01
4 D
olla
rs
France
Germany
Japan
United Kingdom
United States
Source: International Energy Agency, 2014.
Policies for the Renewable Energy
Transition
• Subsidy reform: eliminate fossil fuel subsidies
• Pigovian tax on externalities including carbon
• Energy research and development
• Feed-in tariffs
• Subsidies, including favorable tax provisions and loan
terms
• Renewable energy targets
• Efficiency standards and labelling
• Financing mechanisms with zero up-front costs
http://www.ase.tufts.edu/gdae/Pubs/climate/ClimatePolicyBrief3.pdf
Carbon in Soils, Grasslands, Forests,
and Wetlands
• Carbon release from soil degradation and deforestation
is major atmospheric carbon source.
• Preventing releases from agricultural soils, wetlands,
and grasslands would lessen human-re;eased carbon by
around 20%.
• Preventing further deforestation would reduce emissions
by another 10%.
• Enhancing uptake by forests, grasslands, and soils
would be equivalent to reducing net emissions by an
additional 30% or more.
The composition of the planet’s water
The Hydrologic Cycle
0 1000 1700 2500 6000 15000 70000
Data not available
Cubic meters per person per year
Water scarce Water stressed
Global Freshwater Availability
Region Average water availability
(cubic meters/person)
Middle East and North Africa 500
Sub-Saharan Africa 1,000
Caribbean 2,466
Asia/Pacific 2,970
Europe 4,741
Latin America 7,200
North America (including
Mexico)
13,401
Water Availability per region (2012)
Agriculture share of water consumed – selected
countries
Countries % of water consumed that is used for
irrigation
Vietnam 95%
India 90%
Egypt 86%
Mexico 77%
China 65%
Brazil 60%
United States 40%
France 12%
Sweden 4%
Germany 0.3%
Calculating water footprint:
Step 1: decomposing water in 3 types
Calculating water footprint:
Step 2: adding all the water (green, blue, grey)
necessary throughout the process of production
of all goods and servicesProduct Virtual-water
content (liters)
1 sheet of paper (80 g/m2) 10
1 tomato (70 g) 13
1 slice of bread (30 g) 40
1 orange (100 g) 50
1 apple (100 g) 70
1 glass of beer (250 ml) 75
1 glass of wine (125 ml) 120
1 egg (40 g) 135
1 glass of orange juice (200 ml) 170
1 bag of potato crisps (200 g) 185
1 glass of milk (200 ml) 200
1 hamburger (150 g) 2,400
1 cotton T-shirt 2,700
1 pair of shoes (bovine leather) 8,000
Type of fuel
Amount of water needed in the
extraction/production of 2 Million
BTUs of energy
Natural Gas (conventional) 5 gallons
Unconventional natural gas (shale) 33 gallons
Oil (conventional) 32 gallons
Oil tar sands (mining) 616 gallons
Biofuel type 1 (irrigated corn) 35,616 gallons
Biofuel type 2 (irrigated soy) 100,591 gallons
Virtual water used in six types of fuels, for a
round trip New York City- Washington D.C.
Calculate your own water footprint:
http://www.gracelinks.org/1408/water-
footprint-calculator
The average person living in the US consumes about 2220 gallons of water
a day - That’s 8,500 liters or 25 bathtubs each day
Diet makes a huge difference:
Meat eater = 30 bathtubs Vegetarian = 15 bathtubs Vegan = 12 bathtubs
0
500
1000
1500
2000
2500
3000
Agricultural goods
Industrial goods
Domestic water consumption
National Water Footprint for selected countries,
in cubic meters per person per year
Transfers of virtual water through trade
Virtual-water balance per country
(billion cubic meters)
Trade of virtual water : cotton
Demand
Supply (MC)
Marginal Social Cost (MSC)
Price
Quantity of WaterQSQEQ*
PE
PS
P* A B C
Regulation by the market:
internalizing negative externalities
Subsidies to irrigation lead to a consumption of Quantity Qs of water
Qe would be the market equilibrium without subsidies
Q* would be the ecologically optimal quantity withdrawn
Price
pe
r U
nit
Quantity of Water Used
Uniform Rate Structure
Price
pe
r U
nit
Quantity of Water Used
Increasing Block Rate Structure
Price
pe
r U
nit
Quantity of Water Used
Decreasing Block Rate Structure
Pricing Structures
$0 $50 $100 $150 $200 $250
Atlanta
San Francisco
San Diego
Charlotte, N.C.
Austin, Tex.
Santa Fe, N.M.
City
Average monthly water bill
Cities with the greatest differences in water rates
50 gallons per person per day 100 150
A few American Cities applying the
increasing bloc rate structure
The acequias of
New Mexico are
communal irrigation
canals, a way to
share water for
agriculture in a dry
land.
Tiwa Indians
irrigated farmland in
the area as long as
1.300 years ago.
“Communities have relied on institutions resembling neither the state nor the
market to govern some resource systems with reasonable degrees of success
over long periods of time ” Elinor Ostrom, in “Governing the Commons” (1990)
Re-creating collective systems of
management of the commons?
Related Documents
