Transportation Energy Systems Analysis Newsletter The Transportation Energy Systems Analysis Newsletter is a quarterly mailing about the latest research, publications, and updates in the analytical community, especially those supported by the Vehicle Technologies Office. Transportation Fact of the Week Newsletter. The Energy Systems division pursues applied research and development to strengthen the economy, enable energy independence, mobility, and national security. The division conducts research, development, and demonstration from bench through development based on critical alliances/partnerships with industrial partners, universities, other national laboratories, and other Argonne divisions.
How the United States uses energy
Americans use a lot of energy in homes, in businesses, and in industry, and to travel and transport goods. There are four end-use sectors that purchase or produce energy for their own consumption and not for resale:
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- The residential sector includes homes and apartments.
- The commercial sector includes offices, malls, stores, schools, hospitals, hotels, warehouses, restaurants, and places of worship and public assembly.
- The industrial sector includes facilities and equipment used for manufacturing, agriculture, mining, and construction.
- The transportation sector includes vehicles that transport people or goods, such as cars, trucks, buses, motorcycles, trains, aircraft, boats, barges, and ships.
These end-use sectors consume energy from primary energy and also purchase and use most of the electricity (a secondary energy source) the electric power sector produces and sells. The electric power sector consumes primary energy to generate electricity for sale to the other four sectors and for export to Canada and Mexico. The end-use sectors also produce some electricity for their own use (called direct use).
Total energy consumption in the end-use sectors includes their primary energy use, purchased electricity, and electrical system energy losses (energy conversion and other losses associated with the generation, transmission, and distribution of purchased electricity) and other energy losses. Total electrical system energy losses are apportioned to each end-use sector according to each sector's share of total annual U.S. electricity purchases.
U.S. energy consumption increased in nearly every year since 1949. A large decrease occured in 2009 during the economic recession when real gross domestic product (GDP) fell about 2.5% compared with 2008, and total energy consumption decreased by nearly 5%. These were the largest single-year decreases in both real GDP and in total energy consumption from 1950 through 2009.
In the ten years from 2010 through 2019, total annual energy consumption increased in five years and decreased in five years. In 2018, total U.S. energy consumption reached a record high of about 101 quadrillion British thermal units (Btu), which was about 0.3% higher than the previous record-high consumption in 2007. Total energy use in 2019 of about 100 quadrillion Btu was about 1% lower than in 2018. Economic growth and other factors such as weather and fuel prices can influence consumption in each sector differently.
Total U.S. energy consumption has increased, but energy consumption per capita has flattened in recent years
While total U.S. energy consumption has trended upward over time and the U.S. population has increased, the amount of energy consumption per capita (per person) peaked in the late 1970s, was relatively flat from the mid-1980s through 2008, and from 2009 through 2019, was at about the same level as in the late 1960s.
Disc cover 3 serial for mac. Factors contributing to lower U.S. per capita energy consumption since the 1980s include Soundtoys 5 mac torrent.
- Increases in efficiency of appliances, electrical equipment, and building insulation largely resulting from the establishment of energy efficiency standards and improved building energy codes
- Increases in the average fuel efficiency of vehicles resulting from the establishment of Corporate Average Fuel Economy (CAFÉ) standards
- Availability of financial incentives for energy efficiency investments
- An overall increase in utility-scale electricity generation with higher efficiency natural gas-fired combined-cycle and combined-heat-and-power generators
- A reduction in the energy intensive production of metals and other manufacturing
- Higher population growth in warmer climate regions of the country than in colder climate regions resulting in lower heating energy consumption and lower total residential and commercial sector energy use
- Increases in the number of roof-top solar photovoltaic systems, which avoid most of electrical system energy losses and result in lower total energy consumption by the residential and commercial sectors
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U.S. energy consumption per dollar of GDP declined nearly every year since 1949
Along with per capita energy consumption, another measure of the intensity of energy consumption is how efficiently the economy uses energy to produce every dollar of Gross Domestic Product (GDP). The amount of U.S. energy consumption per real 2012 dollar of GDP (the value adjusted to account for changes in the value of the U.S. dollar) declined in most years between 1949 and 2019. Although growth of U.S. energy consumption is closely tied to growth in GDP and other economic factors, it is partially offset by improvements in energy efficiency and other changes in the economy that result in lower energy use per unit of economic output. Many of the factors that contribute to lower per capita energy consumption also contribute to lower energy consumption per dollar of GDP. Reg key fl studio 12.0.2.
Last updated: June 18, 2020
Power Engineering Guide | Energy Topics | Global
The Future of Nuclear Energy in a Carbon-Constrained World study is the eighth in the MIT Energy Initiative’s Future of series, which aims to shed light on a range of complex and important issues involving energy and the environment. A central theme is understanding the role of technologies that might contribute at scale in meeting rapidly growing global energy demand in a carbon constrained world. Nuclear power could certainly play an important role, and it was the subject of the first of these interdisciplinary studies at MIT—the 2003 Future of Nuclear Power report. More recent studies have looked at the roles of CO2 sequestration, natural gas, the electric grid, and solar power. Following a 2009 update to the original nuclear study, now is an appropriate time to take a fresh look at nuclear, given advances in inherently safer technologies, a sharpened focus on the need to reduce CO2 emissions in the energy sector, and challenges of cost and public perceptions of safety.
The study is designed to serve as a balanced, fact-based, and analysis-driven guide for stakeholders involved in nuclear energy. Policy makers, utilities, existing and startup energy companies, regulators, investors, and other power-sector stakeholders can use this study to better understand the challenges and opportunities currently facing nuclear energy in the U.S. and around the world. The report distills results and findings from more than two years of primary research, a review of the state of the art, and quantitative modeling and analysis.