Bioenergy Action Plan

Last updated December 06, 2023

On April 25, 2006, Executive Order S-06-06, the Bioenergy Action Plan was issued by the then governor of California, Arnold Schwarzenegger, outlining a set of target goals which would establish the increasing use and production of biofuels and biopower for both electricity generation and substitution of natural gas and petroleum within the state of California. The plan asked multiple state agencies (the Bioenergy Interagency Working Group) to work towards the advancement of biomass programs in California. The order would also help provide statewide environmental protection, mitigation and economic advancement. The plan was passed on July 7, 2006, with progress reports issued in 2007 and 2009.

An updated plan was released in 2011. The 2011 plan supports the goals of current California Governor Jerry Brown’s Clean Energy Jobs Plan. The 2011 plan evaluates strategies for overcoming the litigation challenges which deterred progress in the 2006 plan. The 2011 plan also recommends new actions for environmental progress in the state of California ^[1]^[2]^[3]^[4]

Types of biofuels and biomass energies

Cellulosic feed stocks derived from forestry, agricultural, and urban wastes
Gasification
Pyrolysis
Biomass-to-liquids conversions
Landfill gas use in energy systems^[1]^[4]

Goals and benefits of incorporating plan(s)

Capturing methane from landfills and converting manure for overall climate benefits
Forest and agricultural waste biomass as a source of fuel
Combining heat (from waste biomass) for energy (electricity)
Improving forest health and animal welfare via converting urban forestry and agricultural residues
Enhancing rural economic development via the exportation of green fuels
Creates local jobs (at new refinery and green plants)
Protects watersheds and helps to avoid wildfires
Reducing statewide petroleum dependence^[4]

Bioenergy Interagency Working Group responsibilities

Use the state and federal budgets to ease the passing of institutional, legislative and regulatory changes which are necessary for plan to be implemented.
Carry out the state's target objectives.
Prove the commercial readiness of production and conversion technologies for the expansion of biomass and biofuel energies.
Develop and demonstrate projects for the biomass-fueled electricity plants and refineries.
Help place a value and market potential on renewable sources of energy, fuel and chemicals.
Produce and demonstrate new cropping, handling, storage, and distribution systems for renewable energy plants.
Demonstrate efficient biomass harvesting systems at (at least) three sites.
Communicate the benefits of bioenergy to the general public and policy makers.
Research new sources of financing for future project development.^[1]

2006 Bioenergy Action Plan

The original plan was written based on reviews and recommendations from public workshops and more than 40 public documents, as well as multiple prior research programmes and policy developments around the world. Stakeholder considerations for California's potential as a leader in renewable energies was taken into account. The plan established a biofuel production target of California producing a minimum of 20% its own biofuels by 2010, 40% by 2020, and 75% by 2050. The production target for the use of biomass electricity was a 20% increase from the prior in-state goals for renewable generation by both 2010 and 2020.

The 2006 plan also sought the building of at least four afforestation and carbon sequestration projects, across the state, which would supply three to five megawatts of biomass-fueled electricity to an electricity gasification plant or bio-refinery. Potential sources of energy, fuel, and chemicals from forest fuel, harvest residues, and other small wood forest products were also identified, as well as the efficiency of harvesting small forest biomass. Each individual agency also had its own specific set of responsibilities towards meeting the goals of the Bioenergy Action Plan.

The 2006 Bioenergy Action Plan outlined five statewide policy objectives:

Maximize the contributions of bioenergy toward achieving the state's petroleum reduction, climate change, renewable energy, and environmental goals.
Establish California as a market leader in technology innovation, sustainable biomass development, and market development for bio-based products.
Coordinate research, development, demonstration, and commercialization efforts across federal and state agencies.
Align existing regulatory requirements to encourage production and use of California's biomass resources.
Facilitate market entry for new applications of bioenergy including electricity, biogas, and biofuels”.^[1]

2007 and 2009 progress reports

2007

19% of all power currently (now, i.e. 2007) comes from biomass
Biomass power facilities are producing nearly 1,000 megawatts of electrical generating capacity
950 million gallons of 5.7% ethanol gasoline and over 43 million gallons of biodiesel were consumed in 2006 compared to the 14.5 billion gallons of gasoline and 4 billion gallons of convention diesel consumed
Existing ethanol facilities only produce nearly 68 million gallons, the proposed plants could produce up to 364 million gallons per year.
The production of biodiesel provides another 14 million gallons
Gasoline amendments passed which favor the use of 10% ethanol blends
96 electricity biomass facilities have been certified and 21 facilities have gone through pre-certification
Between 285 and 391 megawatts of new renewable electricity was added in 2006 to the electricity grid
33 biomass power facilities are expanded which created 640 megawatts of new renewable energy capacity
Emission rates and standards in preference for low-carbon sources of electricity have been adopted by Senate Bill 1368
10 dairy digesters have been installed across California, which generate 2.5 megawatts of electrical power from dairy manure or a mixture of manure, food-wastes and wastewater
Specialty crops (figs and barley) are being converted to energy
New waste discharge regulations for dairies and dairy lagoons have been adopted^[2]

2009

11% of electricity consumed comes from renewable resources
Nearly 20% of renewable electricity generated came from biomass fuels
943 megawatts of biopower generated
Three idled biomass plants have resumed operations
One idled coal facility and two working coal facilities have been converted to biomass plants
309 megawatts of landfill gas has been generated to electricity biopower
66 megawatts digester gas biopower generated
One billion gallons of 6% ethanol consumed yet only 5.7% produced within California
50 million gallons of biodiesel consumed yet only 12% produced within California
2010 biopower and biofuel production via biomass targets are evaluated as “unlikely”
Adopted low-carbon fuel standard for reducing greenhouse gas emissions by 10% by 2020^[3]

2011 Bioenergy Action Plan

Less than 40 actions out of the 63 initial actions from the 2006 plan were completed by the time the 2011 plan was developed/adjusted. The 2006 plan was reviewed at two public workshops on June 3, 2010, and December 14, 2010. The new version of the plan was changed accordingly to assure complete coordination with the goals targeted in California Governor Jerry Brown's Clean Energy Job Plan and the Clean Energy Future Plan. The 2011 plan extends the 20% renewable electricity production with California to 2013 instead of the 2010 goal, with a 33% renewable electricity goal by 2020. Fuel-related refineries, blenders, producers and importers are expected to reduce their carbon emissions by 10% by 2020. The production of 21 billion gallons of biofuels is projected for 2022. As with the 2006 plan, each state agency has its own individual set of goals and responsibilities.

The 2011 Bioenergy Plan objectives are outlined as:

Increase bioenergy production at existing facilities including restarting idling plants and repowering existing facilities.
Construct new bioenergy facilities.
Integrate bioenergy facilities with the use of multiple fuels in collection, processing, and treatment operations.
Commercialize conversion technologies by funding research and development.
Remove regulatory hurdles and streamline processes.^[4]

Related Research Articles

<span class="mw-page-title-main">Biofuel</span> Type of biological fuel produced from biomass from which energy is derived

Biofuel is a fuel that is produced over a short period from biomass, rather than by the very slow natural processes involved in the formation of fossil fuels, such as oil. Biofuel can be produced from plants or agricultural, domestic, or industrial biowaste. Biofuels are mostly used for transportation but can also be used for heating and electricity. Biofuels are regarded as a renewable energy source. However, the use of biofuel has been controversial because of the several disadvantages associated with the use of it. These include for example : the "food vs fuel" debate, biofuel production methods being sustainable or not, leading to deforestation and loss of biodiversity or not.

Cellulosic ethanol is ethanol produced from cellulose rather than from the plant's seeds or fruit. It can be produced from grasses, wood, algae, or other plants. It is generally discussed for use as a biofuel. The carbon dioxide that plants absorb as they grow offsets some of the carbon dioxide emitted when ethanol made from them is burned, so cellulosic ethanol fuel has the potential to have a lower carbon footprint than fossil fuels.

A biorefinery is a refinery that converts biomass to energy and other beneficial byproducts. The International Energy Agency Bioenergy Task 42 defined biorefining as "the sustainable processing of biomass into a spectrum of bio-based products and bioenergy ". As refineries, biorefineries can provide multiple chemicals by fractioning an initial raw material (biomass) into multiple intermediates that can be further converted into value-added products. Each refining phase is also referred to as a "cascading phase". The use of biomass as feedstock can provide a benefit by reducing the impacts on the environment, as lower pollutants emissions and reduction in the emissions of hazard products. In addition, biorefineries are intended to achieve the following goals:

Supply the current fuels and chemical building blocks
Supply new building blocks for the production of novel materials with disruptive characteristics
Creation of new jobs, including rural areas
Valorization of waste
Achieve the ultimate goal of reducing GHG emissions

Bioenergy is energy made or generated from biomass, which consists of recently living organisms, mainly plants. Types of biomass commonly used for bioenergy include wood, food crops such as corn, energy crops and waste from forests, yards, or farms. The IPCC defines bioenergy as a renewable form of energy. Bioenergy can either mitigate or increase greenhouse gas emissions. There is also agreement that local environmental impacts can be problematic.

<span class="mw-page-title-main">Renewable energy in the European Union</span>

Renewable energy plays an important and growing role in the energy system of the European Union. The Europe 2020 strategy included a target of reaching 20% of gross final energy consumption from renewable sources by 2020, and at least 32% by 2030. The EU27 reached 22.1% in 2020, up from 9.6% in 2004, but declined to 21.8% in 2021. These figures are based on energy use in all its forms across all three main sectors, the heating and cooling sector, the electricity sector, and the transport sector.

Energy crops are low-cost and low-maintenance crops grown solely for renewable bioenergy production. The crops are processed into solid, liquid or gaseous fuels, such as pellets, bioethanol or biogas. The fuels are burned to generate electrical power or heat.

The United States produces mainly biodiesel and ethanol fuel, which uses corn as the main feedstock. The US is the world's largest producer of ethanol, having produced nearly 16 billion gallons in 2017 alone. The United States, together with Brazil accounted for 85 percent of all ethanol production, with total world production of 27.05 billion gallons. Biodiesel is commercially available in most oilseed-producing states. As of 2005, it was somewhat more expensive than fossil diesel, though it is still commonly produced in relatively small quantities.

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.

Biofuel is fuel that is produced from organic matter (biomass), including plant materials and animal waste. It is considered a renewable source of energy that can assist in reducing carbon emissions. The two main types of biofuel currently being produced in Australia are biodiesel and bioethanol, used as replacements for diesel and petrol (gasoline) respectively. As of 2017 Australia is a relatively small producer of biofuels, accounting for 0.2% of world bioethanol production and 0.1% of world biodiesel production.

<span class="mw-page-title-main">Biofuel in Sweden</span> Use of renewable fuels from living organisms in Sweden

Biofuels are renewable fuels that are produced by living organisms (biomass). Biofuels can be solid, gaseous or liquid, which comes in two forms: ethanol and biodiesel and often replace fossil fuels. Many countries now use biofuels as energy sources, including Sweden. Sweden has one of the highest usages of biofuel in all of Europe, at 32%, primarily due to the widespread commitment to E85, bioheating and bioelectricity.

Second-generation biofuels, also known as advanced biofuels, are fuels that can be manufactured from various types of non-food biomass. Biomass in this context means plant materials and animal waste used especially as a source of fuel.

Renewable energy in Finland grew to 38.7% of total final energy consumption by year end 2014, achieving joint second position with Latvia in terms of renewable energy consumption by share amongst the EU-28 countries, behind its neighbour Sweden in first position on a 52.6% share. The 2014 share in Finland breaks down as renewable energy providing 52% of the heating and cooling sector, 31.4% of the electricity sector and 21.6% of the transport sector. By 2014, Finland had already exceeded its 2020 target for renewable energy use under the EU renewable energy directive as shown in the table of country targets.

China has set the goal of attaining one percent of its renewable energy generation through bioenergy in 2020.

<span class="mw-page-title-main">Biofuels by region</span> Use of biofuel as energy source across the world

The use of biofuels varies by region. The world leaders in biofuel development and use are Brazil, United States, France, Sweden and Germany.

As of 2019, renewable energy technologies provide about 17.3% of Canada's total primary energy supply. For electricity renewables provide 67%, with 15% from nuclear and 18% from hydrocarbons.

United States policy in regard to biofuels, such as ethanol fuel and biodiesel, began in the early 1990s as the government began looking more intensely at biofuels as a way to reduce dependence on foreign oil and increase the nation's overall sustainability. Since then, biofuel policies have been refined, focused on getting the most efficient fuels commercially available, creating fuels that can compete with petroleum-based fuels, and ensuring that the agricultural industry can support and sustain the use of biofuels.

Energy in the U.S. state of Hawaii is produced from a mixture of fossil fuel and renewable resources. Producing energy is complicated by the state's isolated location and lack of fossil fuel resources. The state relies heavily on imports of petroleum. Hawaii has the highest share of petroleum use in the United States, with about 62% of electricity coming from oil in 2017. As of 2021 renewable energy made up 34.5% on Oahu, Maui and the island of Hawaii.

Renewable energy in Thailand is a developing sector that addresses the country’s present high rate of carbon emissions. Several policies, such as the Thirteenth Plan or the Alternative Energy Development Plan, set future goals for increasing the capacity of renewable energy and reduce the reliance of nonrenewable energy. The major sources of renewable energy in Thailand are hydro power, solar power, wind power, and biomass, with biomass currently accounting for the majority of production. Thailand’s growth is hoped to lead to renewable energy cost reduction and increased investment.

The economic biomass potential of Turkey is 32 million tons of oil equivalent (Mtoe)/year. Total biomass production is estimated to reach 52.5 Mtoe by 2030. Arable crops in Central Anatolia and the Mediterranean have the most potential for electricity, and in 2021 biomass generated 7.6 TWh, which was 2.3% of the nation's electricity, from over 2 GW capacity. An estimated 6.5 million homes in Turkey use biomass as their main source of heating fuel.

Biofuels play a major part in the renewable energy strategy of Denmark. Denmark is using biofuel to achieve its target of using 100% renewable energy for all energy uses by 2050. Biofuels provide a large share of energy sources in Denmark when considering all sectors of energy demand. In conjunction with Denmark's highly developed renewable energy resources in other areas, biofuels are helping Denmark meet its ambitious renewable energy targets.

References

1 2 3 4 California Energy Commission. "Bioenergy action plan for California" (PDF). California Energy Commission. Retrieved 6 February 2012.
1 2 Brown, S. "2007 progress to plan - bioenergy action plan for California" (PDF). California Energy Commission. Retrieved 6 February 2012.
1 2 Orta, J. "2009 progress to plan ‐ bioenergy action plan for California" (PDF). California Energy Commission. Archived from the original (PDF) on 24 March 2012. Retrieved 6 February 2012.
1 2 3 4 O'Neill, G. "2011 bioenergy action plan" (PDF). Efficiency and Renewables Division. California Energy Commission. Retrieved 6 February 2012.

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[bioenergy_one-1] 1 2 3 4 California Energy Commission. "Bioenergy action plan for California" (PDF). California Energy Commission. Retrieved 6 February 2012.

[progress_one-2] 1 2 Brown, S. "2007 progress to plan - bioenergy action plan for California" (PDF). California Energy Commission. Retrieved 6 February 2012.

[progress_two-3] 1 2 Orta, J. "2009 progress to plan ‐ bioenergy action plan for California" (PDF). California Energy Commission. Archived from the original (PDF) on 24 March 2012. Retrieved 6 February 2012.

[bioenergy_two-4] 1 2 3 4 O'Neill, G. "2011 bioenergy action plan" (PDF). Efficiency and Renewables Division. California Energy Commission. Retrieved 6 February 2012.

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