ABSTRACT
Atmospheric methane (CH4) is a potent greenhouse gas, and its mole fraction has more than doubled since the preindustrial era1. Fossil fuel extraction and use are among the largest anthropogenic sources of CH4 emissions, but the precise magnitude of these contributions is a subject of debate2,3. Carbon-14 in CH4 (14CH4) can be used to distinguish between fossil (14C-free) CH4 emissions and contemporaneous biogenic sources; however, poorly constrained direct 14CH4 emissions from nuclear reactors have complicated this approach since the middle of the 20th century4,5. Moreover, the partitioning of total fossil CH4 emissions (presently 172 to 195 teragrams CH4 per year)2,3 between anthropogenic and natural geological sources (such as seeps and mud volcanoes) is under debate; emission inventories suggest that the latter account for about 40 to 60 teragrams CH4 per year6,7. Geological emissions were less than 15.4 teragrams CH4 per year at the end of the Pleistocene, about 11,600 years ago8, but that period is an imperfect analogue for present-day emissions owing to the large terrestrial ice sheet cover, lower sea level and extensive permafrost. Here we use preindustrial-era ice core 14CH4 measurements to show that natural geological CH4 emissions to the atmosphere were about 1.6 teragrams CH4 per year, with a maximum of 5.4 teragrams CH4 per year (95 per cent confidence limit)-an order of magnitude lower than the currently used estimates. This result indicates that anthropogenic fossil CH4 emissions are underestimated by about 38 to 58 teragrams CH4 per year, or about 25 to 40 per cent of recent estimates. Our record highlights the human impact on the atmosphere and climate, provides a firm target for inventories of the global CH4 budget, and will help to inform strategies for targeted emission reductions9,10.
Subject(s)
Atmosphere/chemistry , Fossil Fuels/history , Fossil Fuels/supply & distribution , Human Activities/history , Methane/analysis , Methane/history , Biomass , Carbon Radioisotopes , Coal/history , Coal/supply & distribution , Global Warming/prevention & control , Global Warming/statistics & numerical data , History, 18th Century , History, 19th Century , History, 20th Century , History, 21st Century , Ice Cover/chemistry , Methane/chemistry , Natural Gas/history , Natural Gas/supply & distribution , Petroleum/history , Petroleum/supply & distributionABSTRACT
Radiocarbon analyses are commonly used in a broad range of fields, including earth science, archaeology, forgery detection, isotope forensics, and physiology. Many applications are sensitive to the radiocarbon ((14)C) content of atmospheric CO2, which has varied since 1890 as a result of nuclear weapons testing, fossil fuel emissions, and CO2 cycling between atmospheric, oceanic, and terrestrial carbon reservoirs. Over this century, the ratio (14)C/C in atmospheric CO2 (Δ(14)CO2) will be determined by the amount of fossil fuel combustion, which decreases Δ(14)CO2 because fossil fuels have lost all (14)C from radioactive decay. Simulations of Δ(14)CO2 using the emission scenarios from the Intergovernmental Panel on Climate Change Fifth Assessment Report, the Representative Concentration Pathways, indicate that ambitious emission reductions could sustain Δ(14)CO2 near the preindustrial level of 0 through 2100, whereas "business-as-usual" emissions will reduce Δ(14)CO2 to -250, equivalent to the depletion expected from over 2,000 y of radioactive decay. Given current emissions trends, fossil fuel emission-driven artificial "aging" of the atmosphere is likely to occur much faster and with a larger magnitude than previously expected. This finding has strong and as yet unrecognized implications for many applications of radiocarbon in various fields, and it implies that radiocarbon dating may no longer provide definitive ages for samples up to 2,000 y old.
Subject(s)
Air Pollutants/analysis , Air Pollutants/history , Atmosphere/chemistry , Carbon/analysis , Fossil Fuels/analysis , Fossil Fuels/history , Carbon Cycle , Carbon Radioisotopes , Computer Simulation , History, 21st Century , Models, Theoretical , Time FactorsABSTRACT
This paper examines the use of lawsuits against three industries that were eventually found to be selling products damaging to human heath and the environment: lead paint, asbestos, and fossil fuels. These industries are similar in that some companies tried to hide or distort information showing their products were harmful. Common law claims were eventually filed to hold the corporations accountable and compensate the injured. This paper considers the important role the lawsuits played in helping establish some accountability for the industries while also noting the limitations of the lawsuits. It will be argued that the lawsuits helped create pressure for government regulation of the industries' products but were less successful at securing compensation for the injured. Thus, the common law claims strengthened and supported administrative regulation and the adoption of industry alternatives more than they provided a means of legal redress.
Subject(s)
Asbestosis/prevention & control , Fossil Fuels/adverse effects , Global Warming/legislation & jurisprudence , Lead Poisoning/prevention & control , Paint/standards , Social Responsibility , Asbestos/history , Asbestos/poisoning , Asbestosis/etiology , Asbestosis/history , Consumer Product Safety/legislation & jurisprudence , Environmental Exposure/adverse effects , Environmental Exposure/legislation & jurisprudence , Environmental Exposure/prevention & control , Fossil Fuels/history , Global Warming/history , Global Warming/prevention & control , Government Regulation , History, 20th Century , History, 21st Century , Humans , Industry/history , Industry/legislation & jurisprudence , Industry/standards , Knowledge , Lead Poisoning/etiology , Lead Poisoning/history , Mineral Fibers/adverse effects , Mineral Fibers/history , Paint/history , Paint/poisoning , Product Surveillance, Postmarketing , Scientific Misconduct/history , Scientific Misconduct/legislation & jurisprudence , United States , Workers' Compensation/history , Workers' Compensation/legislation & jurisprudenceABSTRACT
The manufactured gas industry provided cities in the United States with energy for light and power during much of the period from approximately 1850 to 1950. This article explores the history of the effects of this industry on air, land, and water environments; it also examines attempts by the courts and municipal and state governments to regulate gas-waste pollution and the industry's response. The article concludes by exploring the heritage of badly contaminated sites that the manufactured gas industry left to the nation after it was replaced by natural gas after World War II.
Subject(s)
Conservation of Energy Resources/history , Environmental Pollution/history , Extraction and Processing Industry/history , Fossil Fuels/history , Environment , Environmental Pollution/adverse effects , Fossil Fuels/adverse effects , History, 19th Century , History, 20th Century , United StatesSubject(s)
Cities , Climate Change , Electricity , Environment , Urban Health , Waste Products , Carbon Dioxide/economics , Carbon Dioxide/history , Cities/economics , Cities/ethnology , Cities/history , Cities/legislation & jurisprudence , Climate Change/economics , Climate Change/history , Electric Power Supplies/history , Electricity/history , Fossil Fuels/economics , Fossil Fuels/history , Greenhouse Effect/economics , Greenhouse Effect/history , Greenhouse Effect/legislation & jurisprudence , History, 20th Century , History, 21st Century , Industry/economics , Industry/education , Industry/history , Transportation/economics , Transportation/history , Urban Health/history , Urban Population/history , Waste Products/economicsSubject(s)
Agriculture/statistics & numerical data , Atmosphere/chemistry , Fossil Fuels/statistics & numerical data , Methane/analysis , Agriculture/history , Animals , Antarctic Regions , Biomass , China , Ethane/analysis , Fires , Fossil Fuels/history , Greenland , History, 20th Century , History, 21st Century , Methane/metabolism , Microbial Consortia/physiology , Oryza/metabolismABSTRACT
Methane and ethane are the most abundant hydrocarbons in the atmosphere and they affect both atmospheric chemistry and climate. Both gases are emitted from fossil fuels and biomass burning, whereas methane (CH(4)) alone has large sources from wetlands, agriculture, landfills and waste water. Here we use measurements in firn (perennial snowpack) air from Greenland and Antarctica to reconstruct the atmospheric variability of ethane (C(2)H(6)) during the twentieth century. Ethane levels rose from early in the century until the 1980s, when the trend reversed, with a period of decline over the next 20 years. We find that this variability was primarily driven by changes in ethane emissions from fossil fuels; these emissions peaked in the 1960s and 1970s at 14-16 teragrams per year (1 Tg = 10(12) g) and dropped to 8-10 Tg yr(-1) by the turn of the century. The reduction in fossil-fuel sources is probably related to changes in light hydrocarbon emissions associated with petroleum production and use. The ethane-based fossil-fuel emission history is strikingly different from bottom-up estimates of methane emissions from fossil-fuel use, and implies that the fossil-fuel source of methane started to decline in the 1980s and probably caused the late twentieth century slow-down in the growth rate of atmospheric methane.
Subject(s)
Atmosphere/chemistry , Ethane/analysis , Fossil Fuels , Methane/analysis , Snow/chemistry , Antarctic Regions , Biofuels , Biomass , Fires , Fossil Fuels/history , Fossil Fuels/statistics & numerical data , Geography , Greenland , History, 20th Century , History, 21st Century , Ice/analysis , Models, TheoreticalABSTRACT
The source of 25 to 30 percent of America's seafood, the Mississippi River Delta's cornucopian world is now uncertain. And yet, even if shrimp, oysters, and finfish are unaffected by the BP Oil Spill - a big if - one can already reflect on the passing of the culture once built upon gathering them. For almost three centuries, levees made life possible along the riverbanks and in the wetlands beyond. Those same levees also ensured the wetlands would eventually melt away into the Gulf. Cutting off the silt left behind during annual river inundations subjected the fragile land to erosion. Sulfur, natural gas, and oil production companies dug twenty thousand miles of canals to gain more direct routes to their fields and to pump out their mineral wealth. This caused salt-water intrusion that killed off plant life and caused more erosion. The world that sustained my Plaquemines ancestors was less subject to collapse following disasters not only because the ecosystem before the wetlands' ongoing loss was then more vibrant, complex, and robust; but also because their lives, especially their culinary lives, were more vibrant, complex, and robust. Life was hard, but when it came to putting food on the table, life followed the seasons.
Subject(s)
Disasters , Ecosystem , Fisheries , Food Supply , Fossil Fuels , Seafood , Animals , Conservation of Natural Resources/economics , Conservation of Natural Resources/history , Disasters/economics , Disasters/history , Ecology/economics , Ecology/education , Ecology/history , Fisheries/economics , Fisheries/history , Food Supply/economics , Food Supply/history , Fossil Fuels/economics , Fossil Fuels/history , History, 21st Century , Mississippi/ethnology , Rivers , Seafood/economics , Seafood/history , Socioeconomic Factors/history , WetlandsABSTRACT
This article explores the proposition that a reason for high agricultural productivity in the early nineteenth century was relatively high energy availability from draught animals. The article is based on the collection of extensive new data indicating different trends in draught power availability and the efficiency of its use in different countries of Europe. This article shows that the proposition does not hold, and demonstrates that, although towards the end of the nineteenth century England had relatively high numbers of draught animals per agricultural worker, it also had low number of workers and animals per hectare, indicating the high efficiency of muscle power, rather than an abundance of such power. The higher efficiency was related to a specialization on less labour-intensive farming and a preference for horses over oxen.
Subject(s)
Agriculture , Conservation of Energy Resources , Efficiency , Livestock , Physical Exertion , Rural Population , Agriculture/economics , Agriculture/education , Agriculture/history , Conservation of Energy Resources/economics , Conservation of Energy Resources/history , Conservation of Natural Resources/economics , Conservation of Natural Resources/history , Europe/ethnology , Fossil Fuels/economics , Fossil Fuels/history , History, 19th Century , History, 20th Century , Rural Health/history , Rural Population/history , Socioeconomic Factors/historyABSTRACT
Home heating and lighting markets have played crucial and underappreciated roles in driving energy transitions. When historians have studied the adoption of fossil fuels, they have often privileged industrial actors, markets, and technologies. My analysis of the factors that stimulated the adoption of anthracite coal and petroleum during the nineteenth century reveals that homes shaped how, when, and why Americans began to use fossil fuel energy. Moreover, a brief survey of other fossil fuel transitions shows that heating and lighting markets have been critical drivers in other times and places. Reassessing the historical patterns of energy transitions offers a revised understanding of the past for historians and suggests a new set of options for policymakers seeking to encourage the use of renewable energy in the future.
Subject(s)
Coal , Economics , Housing , Petroleum , Public Health , Renewable Energy , Residence Characteristics , Carbon/economics , Carbon/history , Coal/economics , Coal/history , Economics/history , Economics/legislation & jurisprudence , Fossil Fuels/economics , Fossil Fuels/history , History, 19th Century , History, 20th Century , Household Products/economics , Household Products/history , Housing/economics , Housing/history , Housing/legislation & jurisprudence , Petroleum/economics , Petroleum/history , Public Health/economics , Public Health/education , Public Health/history , Public Health/legislation & jurisprudence , Renewable Energy/economics , Renewable Energy/history , Renewable Energy/legislation & jurisprudence , Residence Characteristics/history , United States/ethnologyABSTRACT
Global terrestrial ecosystems absorbed carbon at a rate of 1-4 Pg yr(-1) during the 1980s and 1990s, offsetting 10-60 per cent of the fossil-fuel emissions. The regional patterns and causes of terrestrial carbon sources and sinks, however, remain uncertain. With increasing scientific and political interest in regional aspects of the global carbon cycle, there is a strong impetus to better understand the carbon balance of China. This is not only because China is the world's most populous country and the largest emitter of fossil-fuel CO(2) into the atmosphere, but also because it has experienced regionally distinct land-use histories and climate trends, which together control the carbon budget of its ecosystems. Here we analyse the current terrestrial carbon balance of China and its driving mechanisms during the 1980s and 1990s using three different methods: biomass and soil carbon inventories extrapolated by satellite greenness measurements, ecosystem models and atmospheric inversions. The three methods produce similar estimates of a net carbon sink in the range of 0.19-0.26 Pg carbon (PgC) per year, which is smaller than that in the conterminous United States but comparable to that in geographic Europe. We find that northeast China is a net source of CO(2) to the atmosphere owing to overharvesting and degradation of forests. By contrast, southern China accounts for more than 65 per cent of the carbon sink, which can be attributed to regional climate change, large-scale plantation programmes active since the 1980s and shrub recovery. Shrub recovery is identified as the most uncertain factor contributing to the carbon sink. Our data and model results together indicate that China's terrestrial ecosystems absorbed 28-37 per cent of its cumulated fossil carbon emissions during the 1980s and 1990s.
Subject(s)
Carbon/metabolism , Ecosystem , Fossil Fuels/history , Atmosphere/chemistry , Biomass , Carbon/analysis , Carbon Dioxide/analysis , Carbon Dioxide/chemistry , Carbon Dioxide/metabolism , China , Forestry/history , History, 20th Century , Soil/analysis , Trees/metabolismSubject(s)
Civil Rights/history , Internationality , Politics , Public Policy , Fossil Fuels/history , Freedom , History, 20th Century , Humans , Industry/history , Iran , Islam/history , Leadership , Terrorism/history , United Kingdom , United StatesABSTRACT
Nitrogen inputs to the US from human activity doubled between 1961 and 1997, with most of the increase in the 1960s and 1970s. The largest increase was in use of inorganic N fertilizer, but emissions of NOx from fossil-fuel combustion also increased substantially. In 1961, N fixation in agricultural systems was the largest single source of reactive N in the US. By 1997, even though N fixation had increased, fertilizer use and NOx emissions had increased more rapidly and were both larger inputs. In both 1961 and 1997, two thirds of reactive N inputs were denitrified or stored in soils and biota, while one third was exported. The largest export was in riverine flux to coastal oceans, followed by export in food and feeds, and atmospheric advection to the oceans. The consumption of meat protein is a major driver behind N use in agriculture in the US Without change in diet or agricultural practices, fertilizer use will increase over next 30 years, and fluxes to coastal oceans may increase by another 30%. However, substantial reductions are possible.
