Advocacy Messages for the Natural Gas Sector November 2010.
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Transcript of Advocacy Messages for the Natural Gas Sector November 2010.
Natural Gas CARES for the World
Global production will increase over the next 20 years, with growing supplies from both conventional and unconventional resources.
The natural gas sector has the best safety record in the industry.
Natural gas is clean.
Natural gas produces less nitrogen oxide than coal, and more than 50% less CO2. Gas produces no sulphur and no solid waste.
Natural gas promotes
sustainable transport.
Natural gas vehicles can improve air quality and energy efficiency in large cities.
Natural gas is abundant.
Natural gas is safe.
Natural gas is available
now.
Natural gas is flexible.
Gas can serve as a flexible partner in power generation for intermittent energy sources like wind and solar, facilitating the phase-in of renewables.
Natural gas is the
affordable choice.
Modern gas-fired plants have a capital cost that is half that of coal, one-third the cost of nuclear and one-fifth the cost of onshore wind.
Natural gas does not require
subsidies.
Unlike heavily subsidized renewable technologies, natural gas use allows countries to affordably reduce their emissions.
Natural gas is efficient.
Modern gas-fired power plants are 40% more efficient than coal plants.
Natural gas saves time.
Gas-fired plants require less construction time than nuclear or coal plants.
Affordable Reliable Efficient
Gas is readily available from a variety of sources, both pipeline and LNG. The environmental benefits of gas can be realized immediately.
Natural gas is a clean, affordable, reliable, efficient, and secure energy source. It has a vital role to play in a sustainable energy future.
Clean Secure
Natural Gas is Clean
Natural gas produces lower emissions than any other fossil fuel.– Natural gas combustion produces an average of 60 kgCO2/MMBtu, while burning
coal produces 92-102 kgCO2/MMBtu.
Gas-fired power generation produces far lower emissions.– The most advanced combined cycle gas turbine (CCGT) power plants can produce
less than 350 kgCO2 per MWh—half the amount produced by the most efficient coal-fired power plants.
0
20
40
60
80
100
120
Lignite Anthracite Coking Crude oil LPG Natural gas
Em
issio
ns In
ten
sity (kg
CO
2/m
mB
TU
)
CO2 Emissions Intensity Comparison of Coal, Oil and Natural Gas
Source: IPCC, PFC EnergyCoal
0
200
400
600
800
1000
1200
Coal Oil Gas Nuclear
Lif
ecycle
Em
issio
ns (kg
CO
2e/M
Wh
)
European Powergen Lifecycle GHG Emissions by Fuel Type: Future Plants
Plant Emissions
Non-Plant Emissions
Natural Gas Promotes Sustainable Transport
Natural gas vehicles can promote air quality. Delhi’s switch to compressed natural gas (CNG) vehicles for public transport helped to reduce carbon monoxide and particulate levels.
Over the past decade, the number of natural gas vehicles worldwide has grown from 1.3 million to 11.4 million, and the number of countries using CNG in transportation has doubled.
Although the vast majority of CNG vehicles are passenger cars, CNG could play a larger role in long-haul trucking and transportation in the future.
2000 2001 2002 2003 2004 2005 2006 2007 2008 20090
2
4
6
8
10
12
CNG Vehicle Fleet
Others
Bangladesh
Ukraine
Colombia
China
Italy
India
Brazil
Iran
Argentina
Pakistan
Source: IANGV, PFC Energy
Million
Natural Gas is the Affordable Choice
The capital costs for gas-fired power plants in the United States and Europe are far lower than the costs per kW for coal and nuclear.
Even in China, the capital costs for gas-fired power generation are competitive with coal.
US EU Asia China0
500
1000
1500
2000
2500
3000
3500
4000
4500
5000
Capital Costs per kW
Gas Coal Nuclear
Source: PFC Energy
$
On a per kW basis, natural gas is very competitive relative to other fuels.
Natural Gas Does Not Require Subsidies
Unlike heavily subsidized renewable technologies, natural gas use allows countries to affordably reduce their carbon emissions.
Government subsidies and direct spending accounted for about one-third of the $145 billion invested in clean energy projects worldwide in 2009.¹
In the United States, for example, subsidies provided for energy include:– Renewable Energy Production Tax Credit– Nuclear Energy Production Tax Credit– Energy Investment Tax Credit– Loan Guarantees– Clean Coal Technologies Investment Tax Credit– Local and State Incentives
1. Bloomberg New Energy Finance
Natural gas, unlike most renewable technologies, does not require government subsidies to remain competitive—allowing countries to achieve emissions
targets while avoiding market distortions.
CO2
TPES
0% 10% 20% 30% 40% 50% 60% 70% 80% 90% 100%
42 %
26 %
38 %
34 %
20 %
21 % 19 %
Global Total Primary Energy Supply (TPES) and CO2 by Fuel Source, 2007
Coal Oil Gas Other
Natural Gas is Available Now
In contrast to renewable technologies that in some cases will require decades of research and innovation, the environmental benefits of gas can be realized today.
Using gas to displace coal in power generation offers an immediate opportunity to reduce emissions. In the United States, coal accounts for 80% of CO2 emissions from the power sector and 33% of all US CO2 emissions—and doubling the utilization rates at existing gas-fired plants could displace enough coal to reduce coal-related emissions by 20%.¹
The Intergovernmental Panel on Climate Change (IPCC) has noted that as the fossil fuel with the lowest CO2 intensity, natural gas offers an immediate opportunity to reduce emissions.
1. Source: US Congressional Research Service
Natural Gas is Flexible
Gas can serve as a flexible partner in power generation for intermittent technologies like solar and wind, facilitating the phase-in of renewables.
Wind power, for example, typically has a very low capacity factor—in most cases between 20% and 40%—meaning that those energy sources are effectively idle for 60% to 80% of the time.
Because gas is a load-following resource—gas turbines can be adjusted upward and downward fairly rapidly according to load changes—gas is essential to complement the growth in variable energy sources.
Renewable Energy Research Laboratory, University of Massachusetts, and US DOE
Natural Gas is Efficient
Modern gas-fired power plants are 40% more efficient than coal-fired plants. Combined cycle gas turbine (CCGT) plants can achieve thermal efficiency rates of 55-60%, compared with thermal efficiency of 42% for coal and 33% for nuclear.
CCGT plants—producing both electricity and heat—have boosted overall plant efficiencies considerably, reducing GHG emissions per unit of energy generated.
Natural gas transmission, distribution and consumer use have become more efficient—and sound energy policies can lead to further improvements. In a 2008 survey of natural gas utilities in 33 US states with energy efficiency programs, reported energy savings averaged 9% for residential users and 7% for all users.¹
Sample Gas Turbine Performance
First operation year of prototype machine
1981 1992 2002
Gas Turbine Power Output (MW) 144 278 334
Gas Turbine Efficiency (% Lower Heating Value, or LHV)
34.8 38.7 39.5
Combined Cycle Efficiency (%LHV) 51.4 59.0 59.3
Source: Mitsubishi Heavy Industries Review, Dec. 2007
1. American Gas Association, 2008
Natural Gas Saves Time
Gas-fired power plants require less construction time than either coal-fired plants or nuclear facilities.
A typical gas-fired power plant can take only two years to construct—less than half the lead time required to build a coal-fired plant, and less than one-third the time required to construct a nuclear plant.
This shorter construction time makes it easier for firms to make efficient investment decisions.
Nuclear plants in particular have been subject to extreme cost overruns and larger-than-expected decommissioning costs. The lengthy construction time (often more than six years) and the volatile regulatory climate for nuclear are serious disincentives for potential investors.
Natural gas-fired plants have a clear advantage over coal and nuclear with regard to construction time.
Natural Gas is AbundantConventional Gas Production to Grow Over Next Two Decades
Global gas production will increase over the next 20 years, with growing supplies from both conventional and unconventional resources.
Australasia, Russia and the Former Soviet Union and the Middle East are all expected to increase gas production over the next 15-20 years.
There are many questions still to be answered about the extent of unconventional gas resources, but the potential resources are enormous.
Source: PFC Energy, Global Gas Supply Forecast
Natural Gas is AbundantConventional Gas Production to Grow Over Next Two Decades
Natural Gas is AbundantUnconventional Gas Resources (in-place)
Coal Bed Methane
Tight Gas
Shale Gas
Estimated Resources
8.2
9.7
5.5
3.4
3.4
1.1
1.0
Continent total shown in quadrillion cubic feet
Sources: PFC Energy Global LNG Service, Rogner 1997
Unconventional gas resources are nearly five times as large as the global conventional gas reserves,
according to some estimates. The key question is: how much of it is recoverable?
( 232 Tcm)
( 96 Tcm)
( 156 Tcm)( 28 Tcm)
( 31 tcm)
( 275 Tcm)
( 96 Tcm)
Natural Gas is AbundantUnconventional Gas Resources (in-place)
Natural Gas is Safe
The natural gas industry has an excellent safety record, with fewer risks for severe accidents than those presented by other energy sources.
Gas-fired power generation also excels in terms of local environmental safety. Gas-fired plants produce fewer pollutants than coal-fired plants, generating far lower levels of sulfur oxides and nitrogen oxides—primary contributors to acid rain and smog—as well as mercury.
The favorable safety and environmental profile of gas power plants aids in the siting and permitting process.
Source: Canadian Energy Research Institute, 2008
Natural Gas Generates Jobs and Growth
Natural gas can play a key role in sustainable economic growth.
The natural gas sector generates jobs.– In Canada, the natural gas sector directly employs nearly
190,000 people, and this number rises to 600,000 when indirect employment is included—or more than 3.5% of Canada’s labor force¹
– In the United States, the natural gas industry directly employs more than 620,000 people—and indirectly employs an additional 2.2 million people—for a total of 2.1% of US employment.²
Natural gas creates economic growth.– In the US, the economic value directly added to the economy by
the gas sector is more than $170 billion annually³, in the form of:• Worker salaries• Federal, state and local tax revenue• Royalties• Spending and savings generated from revenues and worker
compensation 1. Canadian Natural Gas Association 2. America’s Natural Gas Alliance3. America’s Natural Gas Alliance
Indirect Employment2.6 million
Direct Employment
811,000
Natural Gas-Related Employment in Canada
and the US
UK: Natural Gas in the Power Sector Case Study
UK gas demand experienced a jolt in the early 1990s with the introduction of CCGTs into the power mix. – Since 2000, gas demand growth in the UK has
come from power, while all other sectors have trended downward.
Beginning in the early 1990s, the UK system has relied increasingly on CCGTs, which accounted for some 45% of power generation in 2009, growing 10% since 2000.
Due to the rise in natural gas penetration in the power mix since 1990, PFC Energy estimates that the UK achieved a 22% reduction in CO2 emissions by 2007, as compared with the “business as usual” case.
UK: Power by Production Type
Thermal
Other
Nuclear
CCGT
0
100
200
300
400
1970
1973
1976
1979
1982
1985
1988
1991
1994
1997
2000
2003
2006
2009
TWh
A supportive government with a clear agenda to boost the role of natural gas in power generation
created significant efficiency gains in the UK.
A supportive government with a clear agenda to boost the role of natural gas in power generation
created significant efficiency gains in the UK.
UK: Natural Gas Penetration in the Power Sector
0
50,000
100,000
150,000
200,000
250,000
300,000
350,000
400,000
1971 1975 1979 1983 1987 1991 1995 1999 2003 2007
GWh
0%
10%
20%
30%
40%
50%
60%
70%
Coal and coal products Petroleum productsNatural gas NuclearHydro Solar/wind/otherCombustible renewables and waste Gas Penetration (right axis)
Argentina: Natural Gas in the Transport Sector Case Study
NGV growth in Argentina resulted from: domestic market
dynamics (higher prices for gasoline relative to natural gas) and policy interventions (early support for infrastructure and campaigns emphasizing CNG
safety).
NGV growth in Argentina resulted from: domestic market
dynamics (higher prices for gasoline relative to natural gas) and policy interventions (early support for infrastructure and campaigns emphasizing CNG
safety).
Argentina has the world’s second-largest NGV fleet, and one of the world’s highest penetration rates for NGVs at approximately 20% of the total vehicle fleet. More than 80% of the NGV fleet consists of non-commercial users (private vehicles rather than trucking or taxi fleets).
CNG use in vehicles began in the 1980s, but accelerated throughout the 1990s and particularly the early 2000s due to increasing investments in retail networks. The development of Argentina’s gas pipeline network also facilitated the expansion of CNG.
The initial phase (1984-1988) of the CNG program involved extensive state support and guidance.
In the mid-1980s, early investments in refueling stations and CNG conversions for municipal vehicles were led by the state.
The state company Gas del Estado played a key role in publicizing the virtues of natural gas—promoting it as an inexpensive, safe and environmentally sound alternative—and in certifying the early conversion kits.
Over time, independent retailers became the dominant players in expanding the retail network, and the state’s role diminished to cover only regulations.
20002001200220032004200520062007200820090
0.20.40.60.8
11.21.41.61.8
2
Argentina: NGV Vehicle FleetMillions
Source: IANGV, PFC Energy
South Korea: Natural Gas in the Residential Sector Case Study
The residential sector in South Korea has been quite successful in replacing coal with cleaner-burning natural gas for its heating needs.
PFC Energy calculates a 12% reduction in CO2
emissions by 2007 relative to the “business as usual” case if South Korea had maintained its 1990 fuel mix.
Looking to the future, South Korea plans to further reduce its dependence on oil and coal in its total energy mix and to increase the share of natural gas.– Between 2009 and 2013, oil is expected to lose
3.3% of its market share and coal 1.6%. Over the same period, natural gas’ market share will rise by more than 2%.
South Korea: Coal and Natural Gas Penetration in the Residential Sector
67%
4%
14%
28%
5%
45%41%
4%
0%
25%
50%
75%
Coal Penetration inResidential Sector
Natural Gas Penetration inResidential Sector
1990 1995 2000 2007 1990 1995 2000 2007
South Korea’s concerted efforts to prioritize gas rather than coal have
allowed it to cut emissions and achieve greater efficiency—while still meeting
rapidly growing demand.
South Korea’s concerted efforts to prioritize gas rather than coal have
allowed it to cut emissions and achieve greater efficiency—while still meeting
rapidly growing demand.
South Korea: Natural Gas Penetration in the Residental Sector
0
5
10
15
20
1971 1975 1979 1983 1987 1991 1995 1999 2003 2007
mmtoe
0%
10%
20%
30%
40%
50%HeatElectricityCombustible renewables and wasteSolar/wind/otherNatural gasPetroleum productsCoal and coal productsGas Penetration (right axis)