Global Climate and Energy Project

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The Global Climate and Energy Project (GCEP) at Stanford University, "seeks new solutions to one of the grand challenges of this century: supplying energy to meet the changing needs of a growing world population in a way that protects the environment." [1]

Contents

Beginning in December 2002, GCEP is a 10-year, $225m research project aimed at developing new energy technologies. These new energy technologies include areas of interest such as renewable energy, CO2 capture and storage, hydrogen storage and electrocatalysis. [2] It has the support of four major companies - ExxonMobil, General Electric, Schlumberger, and Toyota. Under the heading "Grand Challenge", it identifies a global warming-related need to reduce greenhouse gas emissions through future energy development.

Targeted goals

1. Identify promising research opportunities for low-emissions, high-efficiency energy technologies.

2. Identify barriers to the larger scale application of these new technologies within the project.

3. Conduct fundamental research into technologies that will help to overcome these barriers and provide the basis for large-scale applications.

4. Share research results with a wide audience, including the science and engineering community, media, business, governments, and potential end-users. [1]

Research overview

More than 200 Stanford University faculty members are involved in the program. With students, technicians and others who are actively engaged at the tasks at hand, Stanford's Global Climate and Energy Project focuses on traditional issues like renewable energy, fossils and nuclear energy, energy storage, grid modernization and its environmental impact. There are several separate research projects being conducted but all share the same common goal, which is to develop new technologies to support the decline of greenhouse gases and carbon emissions. [3]

Stanford awarded projects

Nighttime radiative cooling: Harvesting the darkness of the universe

A device was created that generated electricity for night time use to allow heat to radiate into outer space. This project was awarded by one of Stanford's top projects because it opened up and exposed large temperature differences between earth and space. This allowed light to be released at night without any electrical inputs or battery-powered technology.

Electrochemical tuning of electronic structures to create highly active electrocatalysts

The project was created to tackle metal catalysts for a cheaper cost and separate water into oxygen and clean burning hydrogen fuels. The research study was done using lithium to enrich hydrogen production. This was done with several catalytic materials and applied physics to reach the common goal for tuning electronic structures into active electrocatalysts. [4]

Results of project 10-year anniversary

After 10 years, the Stanford Global Climate Energy Project has helped support up to 80 research programs within Stanford's internal research and have expanded it to 38 others across the world. One example of the program's success is a 2007 study of artificial photosynthesis by Caltech scientist Nathan Lewis, Harry Gray and Harry Atwater who developed Joint Center on Artificial photosynthesis. This was a development towards artificial solar fueled technology. Stanford University's president John Hennessy said "We sat back and realized that energy was going to be a really big research topic for the university...GCEP was the beginning of that process, Stanford is a place where the idea of taking on a big challenge is not only OK, but expected." [5]

Awarding $9.3 million for innovative energy research

The GCEP was awarded a $9.3 million research project on energy funded technology to be developed over six new research based projects. Including Stanford University, four other universities are involved in the positive development of this energy project. Sally Benson, a professor for energy resources engineers at Stanford University said "These six projects are potential game changers that could help transform our global energy system in the future.” [6]

Related Research Articles

<span class="mw-page-title-main">Renewable energy</span> Energy collected from renewable resources

Renewable energy is energy from renewable resources that are naturally replenished on a human timescale. Renewable resources include sunlight, wind, the movement of water, and geothermal heat. Although most renewable energy sources are sustainable, some are not. For example, some biomass sources are considered unsustainable at current rates of exploitation. Renewable energy is often used for electricity generation, heating and cooling. Renewable energy projects are typically large-scale, but they are also suited to rural and remote areas and developing countries, where energy is often crucial in human development.

<span class="mw-page-title-main">Solar energy</span> Radiant light and heat from the Sun, harnessed with technology

Solar energy is radiant light and heat from the Sun that is harnessed using a range of technologies such as solar power to generate electricity, solar thermal energy, and solar architecture. It is an essential source of renewable energy, and its technologies are broadly characterized as either passive solar or active solar depending on how they capture and distribute solar energy or convert it into solar power. Active solar techniques include the use of photovoltaic systems, concentrated solar power, and solar water heating to harness the energy. Passive solar techniques include orienting a building to the Sun, selecting materials with favorable thermal mass or light-dispersing properties, and designing spaces that naturally circulate air.

<span class="mw-page-title-main">Energy development</span> Methods bringing energy into production

Energy development is the field of activities focused on obtaining sources of energy from natural resources. These activities include the production of renewable, nuclear, and fossil fuel derived sources of energy, and for the recovery and reuse of energy that would otherwise be wasted. Energy conservation and efficiency measures reduce the demand for energy development, and can have benefits to society with improvements to environmental issues.

<span class="mw-page-title-main">Hydrogen economy</span> Using hydrogen to decarbonize sectors which are hard to electrify

The hydrogen economy is an umbrella term that draws together the roles hydrogen can play alongside renewable electricity to decarbonize specific economic sectors, sub-sectors and activities which may be technically difficult to decarbonize through other means, or where cheaper and more energy-efficient clean solutions are not available. In this context, hydrogen economy encompasses hydrogen’s production through to end-uses in ways that substantively contribute to avoiding the use of fossil fuels and mitigating greenhouse gas emissions.

<span class="mw-page-title-main">Sustainable energy</span> Energy that responsibly meets social, economic, and environmental needs

Energy is sustainable if it "meets the needs of the present without compromising the ability of future generations to meet their own needs." Most definitions of sustainable energy include considerations of environmental aspects such as greenhouse gas emissions and social and economic aspects such as energy poverty. Renewable energy sources such as wind, hydroelectric power, solar, and geothermal energy are generally far more sustainable than fossil fuel sources. However, some renewable energy projects, such as the clearing of forests to produce biofuels, can cause severe environmental damage.

<span class="mw-page-title-main">Climate change mitigation</span> Actions to reduce net greenhouse gas emissions to limit climate change

Climate change mitigation is action to limit climate change. This action either reduces emissions of greenhouse gases or removes those gases from the atmosphere. The recent rise in global temperature is mostly due to emissions from burning fossil fuels such as coal, oil, and natural gas. There are various ways that mitigation can reduce emissions. These are transitioning to sustainable energy sources, conserving energy, and increasing efficiency. It is possible to remove carbon dioxide from the atmosphere. This can be done by enlarging forests, restoring wetlands and using other natural and technical processes. The name for these processes is carbon sequestration. Governments and companies have pledged to reduce emissions to prevent dangerous climate change. These pledges are in line with international negotiations to limit warming.

Renewable Fuels are fuels produced from renewable resources. Examples include: biofuels, Hydrogen fuel, and fully synthetic fuel produced from ambient carbon dioxide and water. This is in contrast to non-renewable fuels such as natural gas, LPG (propane), petroleum and other fossil fuels and nuclear energy. Renewable fuels can include fuels that are synthesized from renewable energy sources, such as wind and solar. Renewable fuels have gained in popularity due to their sustainability, low contributions to the carbon cycle, and in some cases lower amounts of greenhouse gases. The geo-political ramifications of these fuels are also of interest, particularly to industrialized economies which desire independence from Middle Eastern oil.

<span class="mw-page-title-main">Low-carbon economy</span> Economy based on energy sources with low levels of greenhouse gas emissions

A low-carbon economy (LCE) or decarbonised economy is an economy based on energy sources that produce low levels of greenhouse gas (GHG) emissions. GHG emissions due to human activity are the dominant cause of observed climate change since the mid-20th century. Continued emission of greenhouse gases will cause long-lasting changes around the world, increasing the likelihood of severe, pervasive, and irreversible effects for people and ecosystems. Shifting to a low-carbon economy on a global scale could bring substantial benefits both for developed and developing countries. Many countries around the world are designing and implementing low-emission development strategies (LEDS). These strategies seek to achieve social, economic, and environmental development goals while reducing long-term greenhouse gas emissions and increasing resilience to the effects of climate change.

The Investor Network on Climate Risk (INCR) is a nonprofit organization of investors and financial institutions that promotes better understanding of the financial risks and investment opportunities posed by climate change. INCR is coordinated by Ceres, a coalition of investors and environmental groups working to advance sustainable prosperity.

<span class="mw-page-title-main">Greenhouse gas emissions by the United States</span> Climate changing gases from the North American country

The United States produced 5.2 billion metric tons of carbon dioxide equivalent greenhouse gas (GHG) emissions in 2020, the second largest in the world after greenhouse gas emissions by China and among the countries with the highest greenhouse gas emissions per person. In 2019 China is estimated to have emitted 27% of world GHG, followed by the United States with 11%, then India with 6.6%. In total the United States has emitted a quarter of world GHG, more than any other country. Annual emissions are over 15 tons per person and, amongst the top eight emitters, is the highest country by greenhouse gas emissions per person. However, the IEA estimates that the richest decile in the US emits over 55 tonnes of CO2 per capita each year. Because coal-fired power stations are gradually shutting down, in the 2010s emissions from electricity generation fell to second place behind transportation which is now the largest single source. In 2020, 27% of the GHG emissions of the United States were from transportation, 25% from electricity, 24% from industry, 13% from commercial and residential buildings and 11% from agriculture. In 2021, the electric power sector was the second largest source of U.S. greenhouse gas emissions, accounting for 25% of the U.S. total. These greenhouse gas emissions are contributing to climate change in the United States, as well as worldwide.

<span class="mw-page-title-main">Fossil fuel phase-out</span> Gradual reduction of the use and production of fossil fuels

Fossil fuel phase-out is the gradual reduction of the use and production of fossil fuels to zero, to reduce deaths and illness from air pollution, limit climate change, and strengthen energy independence. It is part of the ongoing renewable energy transition, but is being hindered by fossil fuel subsidies.

Carbon capture and storage (CCS) is a technology that can capture carbon dioxide CO2 emissions produced from fossil fuels in electricity, industrial processes which prevents CO2 from entering the atmosphere. Carbon capture and storage is also used to sequester CO2 filtered out of natural gas from certain natural gas fields. While typically the CO2 has no value after being stored, Enhanced Oil Recovery uses CO2 to increase yield from declining oil fields.

<span class="mw-page-title-main">100% renewable energy</span> Practice of exclusively using easily replenished natural resources to do work

100% renewable energy is the goal of the use renewable resources for all energy. 100% renewable energy for electricity, heating, cooling and transport is motivated by climate change, pollution and other environmental issues, as well as economic and energy security concerns. Shifting the total global primary energy supply to renewable sources requires a transition of the energy system, since most of today's energy is derived from non-renewable fossil fuels.

<span class="mw-page-title-main">Climate change in Massachusetts</span> Climate change in the US state of Massachusetts

Climate change in Massachusetts affects both urban and rural environments, including forestry, fisheries, agriculture, and coastal development. The Northeast is projected to warm faster than global average temperatures; by 2035, the Northeast is "projected to be more than 3.6°F (2°C) warmer on average than during the preindustrial era."

<span class="mw-page-title-main">Greenhouse gas emissions by Australia</span> Release of gases from Australia which contribute to global warming

Greenhouse gas emissions by Australia totalled 533 million tonnes CO2-equivalent based on greenhouse gas national inventory report data for 2019; representing per capita CO2e emissions of 21 tons, three times the global average. Coal was responsible for 30% of emissions. The national Greenhouse Gas Inventory estimates for the year to March 2021 were 494.2 million tonnes, which is 27.8 million tonnes, or 5.3%, lower than the previous year. It is 20.8% lower than in 2005. According to the government, the result reflects the decrease in transport emissions due to COVID-19 pandemic restrictions, reduced fugitive emissions, and reductions in emissions from electricity; however, there were increased greenhouse gas emissions from the land and agriculture sectors.

The milestones for carbon capture and storage show the lack of commercial scale development and implementation of CCS over the years since the first carbon tax was imposed.

Sally M. Benson is a professor of energy engineering at Stanford University. In 2014, she was appointed as director of the Precourt Institute for Energy, the university's hub of energy research and education. Benson will continue on as director of Stanford's Global Climate and Energy Project (GCEP), a position she has had since 2007.

<span class="mw-page-title-main">Carbon capture and utilization</span>

Carbon capture and utilization (CCU) is the process of capturing carbon dioxide (CO2) from industrial processes and transporting it via pipelines to where one intends to use it in industrial processes.

<span class="mw-page-title-main">Direct air capture</span> Method of carbon capture from carbon dioxide in air

Direct air capture (DAC) is the use of chemical or physical processes to extract carbon dioxide directly from the ambient air. If the extracted CO2 is then sequestered in safe long-term storage, the overall process will achieve carbon dioxide removal and be a "negative emissions technology" (NET).

<span class="mw-page-title-main">Climate change in Texas</span> Climate change in the US state of Texas

The climate in Texas is changing partially due to global warming and rising trends in greenhouse gas emissions. As of 2016, most area of Texas had already warmed by 1.5 °F (0.83 °C) since the previous century because of greenhouse gas emissions by the United States and other countries. Texas is expected to experience a wide range of environmental impacts from climate change in the United States, including rising sea levels, more frequent extreme weather events, and increasing pressure on water resources.

References

  1. 1 2 "About Us - GCEP".
  2. "GCEP Research". web.stanford.edu. Retrieved 2017-05-04.
  3. "Research Overview | Energy". energy.stanford.edu. Retrieved 2019-12-16.
  4. "Stanford Innovative energy research". 2015-08-12.
  5. Hennessy, John (November 8, 2012). "Cultural Shift from Stanford U. President". Stanford News.
  6. Benson, Sally (August 12, 2015). "Sally Benson Quote".
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