8-a. What is Sustainability & How Does it Relate to Natural Resource Management? Larry D. Sanders (SPRING 2006) Dept. of Ag Economics Oklahoma State University 1 INTRODUCTION --ch. 11-12 Hackett; Lectures 21 Mar, 4 Apr Purpose: – to become aware of the concept of sustainability & long term thinking Learning Objectives. To understand/become aware of: 1. The concept of sustainability with respect to agriculture. 2. The concept of sustainability with respect to poor developing countries & the global system 3. The importance of long term thinking to avoid possibly irreversible or very costly damage & loss of life 2 Imperatives for Sustainable Systems Economy (efficiency) Environment (maintain/ enhance) Individual/ Community (cohesion) 3 Sustainability: Normative standard/social goal Vision of the future Iroquois Confederation (7 generations) More inclusive/comprehensive view of economic development/well-being Whatever it takes to maintain the lives & livelihoods of people in the system 4 Sustainable Agriculture, as an example: “An integrated system of plant & animal production practices having a site specific application that will, over the long term: satisfy human food & fiber needs; enhance environmental quality & the natural resource base upon which the agricultural economy depends; make the most efficient use of nonrenewable resources and on-farm resources and integrate, where appropriate, natural biological cycles & controls; sustain the economic viability of farm farm operation; and enhance the quality of life for farmers and society as a whole.” --The Food, Agriculture, Conservation, & Trade Act of 1990 5 “5 Capitals” of Viederman: 1.Nature’s Capital: the flow of natural resources & cycling of waste (& life-sustaining ecosystem) 2.Human Capital: people using knowledge/skills to function 3.Human-created Capital: technology & productive facilities 4.Social Capital: networks of civic institutions & norms 5.Cultural Capital: myths/stories/visions shared by people 6 Sustainability as an Ethical Standard Individualism vs. interdependence Need buy-in by key participants Crosses disciplines Concept of “multifunctionality” for sustaining farms 7 Energy Consumption by Primary Source Pre 17th century: human, animal, hydro 1635-1880: Wood 1880-1945: Coal 1945-Present: Petroleum (80% of energy from fossil fuels) 2030: ??? 8 US Energy Production by Source, 2000 (quadrillion btu); [US imports 30% of energy consumption] 25 20 Coal 23 Natural Gas 20 Crude Oil 15 10 5 Nuclear 12 Wood/waste 8 3 3 Hydro 3 0.5 0 Energy Flexible Energy, Inc., “Fall 2001 Energy Review”; www.flexibleenergy.com Natural Gas Plant Liquids Geothermal/other 9 Energy Trends--Sustainable? (1990-2000 annual growth rates) Coal (0%) 60 50 40 WORLD OIL PRODUCTION (mil.bls) 30 20 10 0 1990 Nuclear Power (1%) 70 1970 Power (22%) Solar (16%) Geothermal (4%) Oil Production (2%) Hydro Power (2%) 1950 Wind 10 11 12 US Energy Supply, 2004 NG: 23% Coal: 23% Nuclear: 8% petroleum natural gas coal nuclear energy renewable energy Renewable: 6% --Biomass 47% Petroleum: 40% --Hydro 45% --Geothermal 5% --Wind 2% DOE, EIA, Renewable Energy Trends 2004. --Solar 1% 13 World Marketed Energy Consumption, 19702025 (quadrillion Btu) 700 600 500 400 energy consumption 300 200 100 0 1970 1980 1990 2001 2010 2020 2025 Energy Information Administration, DOE, 2004. 14 The Physics of Energy-Sustainability difficult to maintain Energy: the capacity for doing work The First Law of Thermodynamics: the energy of the universe remains constant (nothing is destroyed; also known as the Law of Conservation of Matter & Energy) The Second Law of Thermodynamics: entropy always moves toward a maximum (energy moves from order to disorder; also known as the Law of Energy Degradation) 15 Entropy & Energy Economics Gross vs. Net Energy Economic Reserves Exponential Growth Irreversibility Externalities 16 Exponential Growth: the 29th Day “A French riddle for children illustrates another aspect of exponential growth--the apparent suddenness with which it approaches a fixed limit. Suppose you own a pond on which a water lily is growing. The lily plant doubles in size each day. If the lily were allowed to grow unchecked, it would completely cover the pond in 30 days, choking off other forms of life in the water. For a long time the lily plant seems small, & so you decide not to worry about cutting it back until it covers half the pond. On what day will that be? On the 29th day, of course. You have one day to save your pond.” (D. Meadows et al, 1972) 17 Exponential Growth & Doubling Time Growth Rate (%) 0.1 0.5 1.0 4.0 7.0 10.0 Doubling Time (yrs) 700 140 70 18 10 7 18 Energy Reserves--Past Predictions Reserves Meadows et al estimates of selected nonrenewable resource reserves, static vs. exponential (1972): – Natural Gas--38-22 years – Petroleum--31-20 years – Coal--2300-111 years What did Meadows overlook or underestimate? OIL NATURAL GAS COAL 1992 1994 2083 time 19 Classification of Hydrocarbon & other Nonrenewable Resources (Harris) KNOWN UNKNOWN RESERVES •Hypothetical •Demonstrated •Speculative •Measured SUBECONOMIC/ •Indicated •Inferred •Undiscoverable •Irretrievable Technological/Geological Feasibility 20 Petroleum Fuel Estimates Historically Conservative Liquid-reserves revisions plus new discoveries have kept ahead of consumption during 1990s In 2003, confirmed liquid-resources in 1992 were 26% higher reserves than originally estimated In 2003, confirmed gas resources discovered in 1992 were 36% greater resources than originally estimated Upward revisions to previous global reserves estimates account for about 75% of all additions Alexander’s Gas & Oil Connections, volume 8, Issue #21, 30 Oct 03; www.gasandoil.com 21 Energy--Policy & Environment to achieve sustainability National Energy Strategy How to achieve MC(s) = MB(s)? – Market Pollution Permits – Per unit Pollution Taxes – Liability & Bonding Systems for Large Stationary Polluters – Fuel Taxes, Options & Impacts 22 Energy--Transition to Future Fuels for Sustainability Transition – Increasing costs – Alternative Fuel &/or New Technology Policy Options – Research & Development – Regulation – Tax – Market Incentives 23 Trends in Renewable Energy Wind, solar electricity costs – reduced by 80-90% 1980-2000 – Projected competitive 2005-2015 Spain, Germany, Denmark provide over 20% electricity w/wind power US provides 6% of total energy use w/renewable energy; 86% w/coal, oil, natural gas Fossil fuels provide 75% of total energy world-wide; biomass provides about 13% US per capita energy use growth rate falling from 7% in 1960s to 2% in 2000 Union of Concerned Scientists, “Clean Energy”, www.ucsusa.org Energy Information Administration, DOE. 24 Alternative Energy Costs, 2003* Average national price of electricity: $0.08/kwh – $24.04/Btu, 2000*** Solar-electric (photovoltaic): $0.20/kwh Solar-heat (thermal panels): $0.08/kwh Wind-electric: $0.04/kwh Ground-heat pump: $0.03/kwh** Gasoline: $12.58/Btu, 2000*** Natural gas: $7.49/Btu, 2000*** * National Geographic News, 28 Oct 2004. ** heat pump cost inferred, not stated. *** Flexible Energy, Inc. 25 World Marketed Energy Consumption by Energy Source, 1970-2025 (quadrillion Btu) 300 250 Oil Natural Gas Coal Nuclear Other 200 150 100 50 0 1970 1980 1990 2000 2010 2020 2025 Energy Information Administration, DOE, 2004. 26 Energy Use in US—2000 Transportation 26% Commercial/ Residential 36% Transportation Industry Commercial/Residential Industry 38% Union of Concerned Scientists, “Clean Energy”, www.ucsusa.org 27 Government Subsidies Matter to Many Energy Sources Nuclear energy received $145 bil. in federal subsidies 1943-1999 Solary energy received $4.4 bil. Wind energy received $1.3 bil. Oil/gas projected to receive $11 bil. tax breaks 1999-2003 Union of Concerned Scientists, “Clean Energy”, www.ucsusa.org 28 How much will change in the future? “In the long term [2020], . . . with fossil fuels remaining the dominant source of energy. . . ., our dependence on foreign sources of petroleum is expected to increase and domestic natural gas production and natural gas imports are expected to grow significantly.” --Mary J. Hutzler, Department of Energy, March 21, 2001 (www.eia.doe.gov) 29 World CO2 Emissions by Fossil Fuel, 19702025 (billion metric tons co2) 40000 35000 30000 25000 Coal Natural Gas Oil 20000 15000 10000 5000 0 1970 1980 1990 2001 2010 2020 2025 Energy Information Administration, DOE, 2004. 30 Agrarian Evolution & Long Term Thinking Process of agricultural evolution has led to a small percentage of large farms producing most of sales in US – displaced farm labor has moved into non-ag sector either in rural communities becoming more diversified or moving to urban areas Agricultural evolution in developing countries more rapid, more disruptive, more destructive & harmful – 40-50% world population lives in urban slums 31 Urban/environmental pressures increasing Low-income countries face water shortages, water pollution, air pollution, minimal shelter shortages, transportation stresses Industrialization that is needed to uplift economies will result in greater stresses on environment & natural resource base 1.2-1.3 billion in absolute poverty 2/3 of world population live on less than $2/day 32 “Market Myopia”? Biased w/short term perspective Discount rates favor present & devalue long term Tend to under-value cultural/social costs 33 Population & Food Production Distribution is an issue: AREA POPULATION ASIA 40% AFRICA 10% L. AMERICA 10% EUROPE 25% N. AMERICA 10% OTHER 5% FOOD 15% 5% 10% 45% 25% 1% NOTE: While global distribution is an issue, hunger exists in all parts of the world, including the developed Western countries of Europe and the US. 34 World Hunger Each minute 20-35 humans die from hunger & malnutrition – 7-20 are children – At minimum, equals a “Hiroshima” every 5 days (140,000) Chronic Hunger & Malnutrition: 14% of World Population – 842 million people – Lack of food and vatamin/mineral deficiencies (iron, A, iodine, zinc) Source: World Food Day, various programs 35 World Hunger (cont.) Point of comparison: All Wars/conflicts of 20th century claimed 130 mil-260 mil. Hunger Deaths in Past 10 yrs 100-200 mil. 250,000 infants/small children may die each week from diet-related, “easily” preventable diseases Thousands more--diet-related blindness & physical & mental retardation Source: World Food Day, various programs. 36 8000 BC 5-10 MIL. 5000 BC 20 MIL 3000 BC 50 MIL. 1400 BC 100 MIL. 0 200 MIL. 1200 400 MIL. 2000 1700 800 MIL. 0 1900 1.5 BIL. BC 1960 3 BIL. 1996 6 BIL. 2006 6.5 bil. 2036-50 11-12 BIL???37 14000 12000 10000 8000 6000 19 96 00 19 00 12 BC 14 00 BC 00 50 m il. 4000 3 MILLION HUMANS HUMAN POPULATION GROWTH, ESTIMATED & PROJECTED (3 Million BC-2036) YEAR Local, Regional, Global Conflicts Likely to Increase Land stress Water stress* – 2025: 48 countries – 2050: 52 countries Energy stress Pollution stress Health stress *Source: M. Hamm, “Integrating Local and Global Food Systems”, NPPEC, St. Louis, September 2004 38 World Hunger (cont.) World Hunger is NOT a food production problem – Technology alone won’t solve the problem – Monoculture export agriculture may worsen problem – Patent movement may worsen problem Economics--poverty--is the problem – 1.2 billion people are below poverty level – Distribution of resources is part of that – Education is critical to the solution 39 World Hunger (cont.) What causes poverty is complex and often varies – Geography, weather, manmade conflicts, bad policies, corruption Economic development is the key Education is the foundation for economic development But . . . – What is the carrying capacity of earth? – Will the US allow development outside its plan? – What pressures can we expect to worsen? » Economic? » Physical? » Sociopolitical? – Does population tend to stabilize as economy and distribution improve? 40 Poor Countries less efficient in energy use, thus more wasteful & polluting Developed (relatively wealthy) countries have decreased CO2/GDP$ emissions 50% in past 30 years Low-income countries produce about 5x more emissions/GDP$ than rich countries Example: 1. US co2 emissions/person: 24x India 2. US co2 emissions/GDP$: 1/3 of India levels 41 Poor Countries’ access to clean air/water result in severe health problems Over 1 billion people don’t have access to safe drinking water 2 billion don’t have adequate sanitation High rates of illness/disabilities 42 Economic Development Argument Raise people out of poverty Lower fertility rates Increase use of cleaner, less resource-intensive technologies Often destructive to culture More sustainable? – No guarantee that technology will keep up – tendency for multinational corporate exploitation – failures of empowerment often occur (especially w/women), leading to dependency, injustice, corruption, more exploitation, political destabilization 43 Income Distribution increasingly skewed Wealthiest 20% of world population accounts for 83% of world income Poorest 20% account for 1.4% of world income Gap has more than doubled since 1960 US: Top 1% have as much after tax income as bottom 100 million people (60%+) 44 Arguments for failure of sustainable environmental systems Rural poor living in fragile ecosystems Ineffective property rights/lack of enforcement Concentration of power/lack of accountability (especially w/multinationals, & non-democratic governments) Trade in waste/toxics Trade agreements that weaken environmental protection 45 Arguments for failure of sustainable environmental systems (continued) Political power controlling; lack of public access Government/corporate control of news media Market has a short term perspective Tax incentives distort environment/natural resource management Lack of leadershp in fostering ethical vision of sustainability Cultural dysfunction may lead to social problems 46 Alternatives that may lead to sustainable global situation Disaster(s) cause rapid reduction in population? Government intervention? – incentives – command & control – “new world order” Free Market may work? Multinationals take over? 47 Major Fuel Prices $ per 1,000 cu. ft. $ per gallon 3.00 14 76% 2.00 Gasoline, Regular; $/gal Diesel, No.1; $/gal $2.32 12 10 8 6 1.00 $1.32 4 Natural Gas, Wellhead; $/mcf 2 0.00 0 2002 Source: U.S. Dept of Energy, EIA 2003 2004 2005 48 Energy Costs as a Share of COP Vary by Crop 40% Indirect Direct 30% 20% 10% 0% Oilseed & grain Vegetables Source: Ag Census, 2002. Fruit & tree nuts Green-house & nursery Cotton Livestock Activities 49 Sources Alexander’s Gas & Oil Connections, volume 8, Issue #21, 30 Oct 03; www.gasandoil.com Energy Information Administration, DOE, “International Energy Outlook 2004”, www.eia.doe.gov Flexible Energy, Inc., “Fall 2001 Energy Review”; www.flexibleenergy.com Hackett, text. Hamm, M. “Integrating Local and Global Food Systems”, NPPEC, St. Louis, September 2004. Harris, J., Environmental and Natural Resource Economics,Houghton Mifflin Co., 2002 (slide 19, Lesson 12a this course adapted from US Bureau of Mines & USGS, 1976). Mary J. Hutzler, Department of Energy, March 21, 2001(www.eia.doe.gov) Union of Concerned Scientists, “Clean Energy”, www.ucsusa.org World Food Day, United Nations, various programs. 50 L8a: Homework Read Ch. 11, Hackett (21 Mar) Read Ch. 12, Hackett (23 Mar) Do # 2, p. 282 (23 Mar) – 4 points Do #6, p. 322 (28 Mar) – 4 points Refer to “Internet Links” (30 Mar) –3 points – Select 2 links (pp. 282-283) – Briefly review, including » Content » Bias or objectivity » Likely use of material Refer to “Internet Links” (4 Apr) –3 points – Select 2 links (pp. 323) – Briefly review, including » Content » Bias or objectivity » Likely use of material Alternate Homework--tba 51