Natural Gas. Hydraulic Fracturing 101. NC Energy Policy Issues Committee February 15 th, 2012

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Bruce McKenzie
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1 Natural Gas Hydraulic Fracturing 101 NC Energy Policy Issues Committee February 15 th, 2012 Tom Hassenboehler Vice President of Policy Development and Legislative Affairs

2 About ANGA ANGA is dedicated to increasing the understanding of the environmental, economic and national security benefits of clean, abundant, dependable and efficient North American natural gas.

3 ANGA Members

4 Future U.S. Energy Demand Energy Consumption by Fuel (quadrillion BTU) % 3.5% 19.7% 25.9% % 8.6% 21.5% 25.2% % 8.1% 21.3% 23.8% Renewables Nuclear Coal Natural Gas % 36.7% 33.2% Oil Source: EIA Annual Energy Outlook 2011

5 The Real Role of Renewables 97.4 quadrillion btu 2010 Natural Gas 25% Oil 37% Coal 22% Nuclear 9% Renewables 8% 0.9% Wind 0.1% Solar 0.4% Geothermal 2.5% Hydroelectric 4.1% Biomass & Biofuels quadrillion btu 2035 Oil 33% Natural Gas 24% Renewables 14% 1.4% Wind 0.1% Solar 1.1% Geothermal 2.7% Hydroelectric Coal 21% Nuclear 8% 8.2% Biomass & Biofuels Source: EIA Annual Energy Outlook 2011

The Shale Gas Revolution Cody Bakken Baxter-Mancos Mancos Mowry Gammon Niobrara Antrim Marcellus/ Devonian/Utica EIA: 2011 862TCF shale Lewis Barnett- Woodford Pierre

6 The Shale Gas Revolution Cody Bakken Baxter-Mancos Mancos Mowry Gammon Niobrara Antrim Marcellus/ Devonian/Utica EIA: TCF shale Lewis Barnett- Woodford Pierre Woodford Barnett Eagle Ford Mulky Fayetteville Haynesville New Albany Floyd-Neal 2,543TCF total 67% INCREASE in just three years Source: EIA Annual Energy Outlook, 2008 to 2011

North Carolina Resource Potential From Reid, J.C. and R.C. Milici. 2008.

7 North Carolina Resource Potential From Reid, J.C. and R.C. Milici Hydrocarbon Source Rocks in the Deep River and Dan River Triassic Basins, North Carolina

8 Abundant by Any Estimate Estimates of U.S. Recoverable Natural Gas (TCF trillion cubic feet)) , , , ,268 1,314 1,312 1,532 2,074 2,170 2,102 2,100 2, ICF^ 2010 CERA 2010 MIT 2011 EIA NPC 2011 Survey High INGAA ICF 2011 Study Potential Gas Committee Other Estimates Sources: ICF: As reported in MIT Energy Initiative, 2010, The Future of Natural Gas, interim report ; Table 2.1 EIA: See PGC: Potential Gas Committee s Advance Summary and press release of its biennial assessment; see CERA: IHS CERA, 2010, Fueling North America s Energy Future: The Unconventional Natural Gas Revolution and the Carbon Agenda MIT: MIT Energy Initiative, 2010, The Future of Natural Gas, interim report NPC: Realizing the Potential of North America s Abundant Natural Gas and Oil Resources Johns Hopkins University ; Prudent Development Study 2011

9 How We Use Natural Gas How Natural Gas is Used Today 3% Transportation 14% Commercial 30% Electric Power 32% Industrial 21% Residential Source: EIA, Natural Gas Year In Review, 2009

Reduces CO 2 emissions 50% Reduces NOx emissions 80% Virtually Eliminates SO 2

10 Cleaner For Power Generation When used to generate electricity, natural gas burns cleaner than other fuel sources, with less pollutants and no mercury. Reduces CO 2 emissions 50% Reduces NOx emissions 80% Virtually Eliminates SO 2 Emissions 99.96% Virtually Eliminates Particulate Emissions 99.74% Completely Eliminates Mercury Emissions 100%

11 Cleaner for Vehicles Compared to gasoline or diesel, NGVs: Reduce CO 2 emissions 20-30% Reduce CO emissions Reduce NOx emissions Reduce Particulate Matter emissions Reduce VOC emissions 70-90% 75-95% 90% 89%

12 Benefits: What We Can Do Replacing 3.5 million medium- and heavy-duty trucks and buses with CNG-powered counterparts by 2035 would save at least 1.2 million barrels of oil per day.

13 PRODUCTION

14 Risk Natural Gas Risk vs. Benefit All energy production comes with some environmental risk. Benefits Energy Security, Clean Air, Jobs, Enhanced Domestic Competiveness Realizing the Benefits Requires commitment of industry and regulators to continuous improvement in practices to eliminate or minimize environmental risk.

15 Conventional/Unconventional Geology

16 Drilling Down: A Closer Look responsible-development/dig-deeper

17 Horizontal Drilling Traditional Wells Horizontal Drilling

18 Hydraulic Fracturing Multiple protective layers extend from surface to below aquifers. Groundwater aquifers Private well, about 500 feet deep Public well, about 1,000 feet deep Several layers of steel tubes encased in cement protect groundwater supplies Shale Fractures Protective steel casing encased in cement extends to shale depth Depth from surface is typically more than a mile

19 Small Environmental Footprint Drilling 2 4 weeks Fracturing 3 5 days Producing decades surrounding land reclaimed

20 A Regulated Process Regulated by states and under the following federal laws: Clean Water Act surface water discharge, storm water runoff Clean Air Act air emissions associated with processing equipment and engines Safe Drinking Water Act underground injection disposal/reuse of produced water and flowback fluids Federal Land Policy and Management Act permitting for federal onshore resources Outer Continental Shelf Lands Act permitting for federal offshore resources National Environmental Policy Act permits and environmental impact statements Occupational Safety and Health Act requires information about chemicals used at every site Emergency Planning and Community Right-to-Know Act annual reporting to emergency responders of chemicals stored and used above certain quantities Extensive State Oversight implement federal laws and regulate drilling fluids and produced water management Detailed state regulatory information available at

21 Frack Fluid Makeup Water & Sand 99.5% Additives - 0.5% Acid Friction Reducer Surfactant Gelling Agent Scale Inhibitor ph Adjusting Agent Breaker Crosslinker Iron Control Corrosion Inhibitor Antibacterial Agent Clay Stabilizer

$Voluntary Disclosure System Chemical Disclosure & Operation Updates http://fracfocus.$

22 Voluntary Disclosure System Chemical Disclosure & Operation Updates created by GWPC and IOGCC 134 companies registered Information is currently posted on 11,270 wells 155,496 website visits

amount of water consumed by: 750 704 364 472 1,000 MWh 204 coal-fired power plant

23 How Much Is 5 Million Gallons Of Water? A typical deep shale gas well stimulation = ~ 5 million gallons It s the same amount of water consumed by: ,000 MWh 204 coal-fired power plant 14 in 11 HOURS 1,000 MWh nuclear power plant in 6 HOURS Corn Field over ACRES per SEASON Avg. golf course every 370 DAYS

24 Production: The Power of Progress Smaller surface impact. Less waste. The average well site today is just 30% of the size of its 1970s counterpart and today s wells can access over 60 times more below-ground area. Onsite water Recycling. Closes loop water recycling system. This eliminates the need to dig and use an open reserve pit. Greener Fluids. Many service companies are moving toward biodegradable solutions-such as food ingredients and ultra-violet light. Fewer air emissions. More efficient operations also means less energy consumption, and thus less air emissions, per unit of natural gas produced.

26 Example: Regulation in PA NPC: Realizing the Potential of North America s Abundant Natural Gas and Oil Resources Johns Hopkins University ; Prudent Development Study 2011

27 Example: Regulation in PA

28 Example: Regulation in PA

29 Example: Regulation in PA