Difference between revisions of "Biomass"

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It is difficult to assess the environmental impact of biomass on a regional or national level because of the unique complexity of each individual biomass facility. Every unit has different ecosystems, whether agricultural, natural, or industrial, to draw resources from. As a result, the overall carbon output is a large part due to how well the biofuel material used from ecosystems is replenished so that that it can neutralize the carbon emitted by biomasses<Ref>Organisation for Economic Co-operation and Development. Biomass and Agriculture: Sustainability, Markets and Policies. Paris: OECD, 2004, p. 151.</Ref>. So what can be said with confidence about the environmental effectiveness of biofuel? There is more consensus about the need for biofuel in the transportation sector, mainly because other renewable energies lack the technological efficiency needed to power transport. Biofuel does emit considerably less carbon than fossil fuel<Ref> "Scientists set sights on biomass to reduce fossil fuel dependence". 2006, Imperial College London. October 29th, 2008. http://www.physorg.com/news10331.html</Ref>, and can be implemented on a wider scale fairly easily.  
 
It is difficult to assess the environmental impact of biomass on a regional or national level because of the unique complexity of each individual biomass facility. Every unit has different ecosystems, whether agricultural, natural, or industrial, to draw resources from. As a result, the overall carbon output is a large part due to how well the biofuel material used from ecosystems is replenished so that that it can neutralize the carbon emitted by biomasses<Ref>Organisation for Economic Co-operation and Development. Biomass and Agriculture: Sustainability, Markets and Policies. Paris: OECD, 2004, p. 151.</Ref>. So what can be said with confidence about the environmental effectiveness of biofuel? There is more consensus about the need for biofuel in the transportation sector, mainly because other renewable energies lack the technological efficiency needed to power transport. Biofuel does emit considerably less carbon than fossil fuel<Ref> "Scientists set sights on biomass to reduce fossil fuel dependence". 2006, Imperial College London. October 29th, 2008. http://www.physorg.com/news10331.html</Ref>, and can be implemented on a wider scale fairly easily.  
  
Biomass can also play an important role in two related fields, sequestration of CO2 and renewable hydrogen power. Sequestration (hyperlink) is the capture of carbon that arises after fuel has been created so that it doesn’t enter the atmosphere. If done in conjuction with biomass, sequestration could potentially solve one of its major obstacles – biomass could then be both renewable and close to carbon neutral. In fact, it is thought that combining biomass and sequestration can produce overall negative carbon emissions<Ref>Faaij, Andre. "Modern Biomass Conversion Technologies.(Author abstract)." Mitigation and Adaptation Strategies for Global Change 11.2 (March 2006): 335(33). Academic OneFile. Gale. Middlebury College, Middlebury, VT. 29 Oct. 2008.</Ref>.  If combined with hydrogen power, another important piece of the puzzle in solving global warming<Ref>Pacala, S. and Socolow, R., "Stabilization Wedges: Solving the Climate Problem for the Next 50 Years with Current Technologies". 2004 www.sciencemag.org, October 28th, 2008.</Ref> sequestration from biomass can become a truly powerful force in solving this crisis. Renewable hydrogen power can be extracted through the biomass process, and since carbon is simply extracted from hydrogen<Ref>Faaij, Andre. "Modern Biomass Conversion Technologies.(Author abstract)." Mitigation and Adaptation Strategies for Global Change 11.2 (March 2006): 335(33). Academic OneFile. Gale. Middlebury College, Middlebury, VT. 29 Oct. 2008.</Ref>, creating hydrogen power using sequestration strategies can truly find an environmentally effective way to utilize biomass<Ref> Turner, A. John,"Sustainable Hydrogen Production". 2004, www.sciencemag.com, October 28th, 2008.</Ref>.
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Biomass can play an important role in two related fields: sequestration of CO2 and renewable hydrogen power. Sequestration (hyperlink) is the capture of carbon that occurs after fuel has been created so that it doesn’t enter the atmosphere. If done in conjuction with biomass, sequestration could potentially solve one of its major obstacles – biomass could then be both renewable and close to carbon neutral. In fact, it is thought that combining biomass and sequestration can produce overall negative carbon emissions<Ref>Faaij, Andre. "Modern Biomass Conversion Technologies.(Author abstract)." Mitigation and Adaptation Strategies for Global Change 11.2 (March 2006): 335(33). Academic OneFile. Gale. Middlebury College, Middlebury, VT. 29 Oct. 2008.</Ref>.  If combined with hydrogen power, another important piece of the puzzle in solving global warming<Ref>Pacala, S. and Socolow, R., "Stabilization Wedges: Solving the Climate Problem for the Next 50 Years with Current Technologies". 2004 www.sciencemag.org, October 28th, 2008.</Ref> sequestration from biomass can become a truly powerful force in solving this crisis. Renewable hydrogen power can be extracted through the biomass process, and since carbon is simply extracted from hydrogen<Ref>Faaij, Andre. "Modern Biomass Conversion Technologies.(Author abstract)." Mitigation and Adaptation Strategies for Global Change 11.2 (March 2006): 335(33). Academic OneFile. Gale. Middlebury College, Middlebury, VT. 29 Oct. 2008.</Ref>, creating hydrogen power using sequestration strategies can truly find an environmentally effective way to utilize biomass<Ref> Turner, A. John,"Sustainable Hydrogen Production". 2004, www.sciencemag.com, October 28th, 2008.</Ref>.
  
 
== Socio-cultural and Geographic Implications ==
 
== Socio-cultural and Geographic Implications ==

Revision as of 21:09, 2 November 2008

Overview

When talked about as a part of the solution to Global Warming, Biomass refers to the conversion of organic material into fuel, which is known as biofuel Confusing sentence. Perhaps reword to simply read: Biomass is organic material that has been converted into biofuel.. The material used in biomass ranges from plants and trees to organic waste from factories or municipal dumps. Biomass is known as a renewable fuel because it takes energy from easily renewable sources, such as plants and waste. Reword of second half of sentence into a new sentence: It still does emit carbon into the atmosphere, but less so than more conventional forms of fuel, such as ____ and _____. [1]. Fossil fuels are of limited quantity and are destructive to the balance of carbon in the atmosphere because of their carbon cycle – the time it takes for new coal or oil to develop and ‘ingest’ the carbon that it emits when used as a fuel. A carbon cycle of this kind of energy takes incredibly long to complete and therefore cannot be considered biomass. slightly confused by this last sentence.

In 2005, research from the Copernicus Institute of Sustainable Development, recently noted as a leader in the field of biomass[2] concluded that approximately 10% percent of total energy used comes from biomass, “making biomass by far the most important renewable energy source used to date” [3]. Because of its technological readiness, can become a viable and effective way to combat global warming, especially in the next few years. It does, however, come with certain obstacles.

Technology

What about the technical process of biomass, at least in theory, makes it such an attractive solution? Nix the first sentence. The process of Biomass essentially mimics the natural process of carbon cycles, and, although it emits greenhouse gases, can create carbon neutral fuels if paired with forestation and protection of biodiversity (see: find correct Paragraph). When plants are alive, they consume carbon through photosynthesis, only to die and eventually release the carbon back into the atmosphere. This delicate balance is a symbiotic relationship – plants and trees need carbon to survive and the earth’s eco-system needs to maintain a certain level of carbon in order to function. Yet when humans began processing huge amounts of fossil fuels, such as coal or oil, it upset the balance of carbon in the atmosphere. In other words, the more biomass we create, the more unbalanced and non-renewable energy sources can be replaced with renewable ones. Waste biomass, on the other hand, goes through the same process as plants, trees, and crops, though it relies on a different justification. By taking advantage of the inevitable carbon emissions that waste creates, biomass can create methane based biofuel, which doesn’t add any more carbon to the atmosphere than the waste would emit already[4]. This is because public and industrial waste can contain dangerous toxins and release similar amounts of methane when left on its own.

More specifically, the biomass process consists of collection of the organic/ waste material, the conversion of that matter to liquid known as feedstock, and the subsequent conversion of feedstock into biofuel. There are many technologies to convert feedstock into biofuels; they are usually categorized into thermochemical, biochemical, and chemical processes. Thermochemical strategies use heat to break down the feedstock, biochemical strategies use enzymes and bacteria, while chemical strategies use chemical reactions. Specific processes are usually chosen according to the matter the feedstock is comprised of[5]. See the chart above for a more detailed summary of biomass techniques. Good info, but reread this section for clarity. I started to skim in the middle of the first paragraph.

Environmental Implications

It is difficult to assess the environmental impact of biomass on a regional or national level because of the unique complexity of each individual biomass facility. Every unit has different ecosystems, whether agricultural, natural, or industrial, to draw resources from. As a result, the overall carbon output is a large part due to how well the biofuel material used from ecosystems is replenished so that that it can neutralize the carbon emitted by biomasses[6]. So what can be said with confidence about the environmental effectiveness of biofuel? There is more consensus about the need for biofuel in the transportation sector, mainly because other renewable energies lack the technological efficiency needed to power transport. Biofuel does emit considerably less carbon than fossil fuel[7], and can be implemented on a wider scale fairly easily.

Biomass can play an important role in two related fields: sequestration of CO2 and renewable hydrogen power. Sequestration (hyperlink) is the capture of carbon that occurs after fuel has been created so that it doesn’t enter the atmosphere. If done in conjuction with biomass, sequestration could potentially solve one of its major obstacles – biomass could then be both renewable and close to carbon neutral. In fact, it is thought that combining biomass and sequestration can produce overall negative carbon emissions[8]. If combined with hydrogen power, another important piece of the puzzle in solving global warming[9] sequestration from biomass can become a truly powerful force in solving this crisis. Renewable hydrogen power can be extracted through the biomass process, and since carbon is simply extracted from hydrogen[10], creating hydrogen power using sequestration strategies can truly find an environmentally effective way to utilize biomass[11].

Socio-cultural and Geographic Implications

As mentioned above, the effectiveness of biomass largely depends on its geographical placement. Since biomass on its own does produce carbon emissions, there needs to be a balance of agricultural protection (keeping crop-land, forests, other eco-systems diverse and lush) and protection against deforestation (since wood is such an excellent source of biomass). In Middlebury, Vermont, for example, the local college is constructing a biomass plant with their surrounding eco-system in mind. At the same time that the plant is being constructed, they have decided to focus on “sustainable forestry methods,”[12], to combat the inevitable carbon emissions that the plant will produce[13]. If planned with the nearby ecosystems in mind, biomass plants can even have a positive impact on biodiversity through initiatives such as reforestation[14].

Comprehensive plans for biomass based on specific communities and regions can also have economic benefits for farmers. In the European Union, farmers seem to be quite willing to participate, whether on a communal or continental level. However, it is up to the specific regions and communities to ensure that the crops and plants harvested by farmers, which will likely be specifically for biomass, are guaranteed to be sold or subsidized. Farmers would also need detailed instruction on how to most efficiently farm for their region, since biomass is such new territory. Generally, farmers need to be given the opportunity to succeed in order for biomass to grow on any geographical scale[15]. This kind of approach has happened particularly well in Austria, where a concept called “systematic management” has been made the implementation of biomass for heating homes a success. Systematic management is a complex system that takes into account social structures of an area in order to figure out the best way to introduce new technology. Austria has used this system to introduce more than 600 biomass plants in the last 20 years[16]. Although comprehensive approaches such as this are difficult to achieve, Austria has shown that it is by no means impossible.

Yet economic opportunity is not the only social necessity in the implementation of biofuel. There also needs to be a balance between food production and crops for biomass. An example of an unbalanced surge in biomass crop was the food crisis in 2007. Across the globe, farmers were taken advantage of the new and expanding biomass market, selling crops like corn and sugarcane usually put on the food market to the renewable energy sector. Because there was little regulation, and even in some cases subsidies for selling biomass-intended crops, food prices shot up[17]. The price rise affected people and countries everywhere, but it most devastatingly affected the poor in developed countries (CITATION, ethanol source). Despite this crisis, biomass does not have to affect people in developing countries this negatively. In fact, since more conventional forms of cooking and heating used in those countries, such as firewood, are part of the spectrum of biomass, these countries might be well prepared to make the transition to larger scale biomass plants[18]. NOTE: I haven't included political and economic yet because I wasn't sure if that could be interweaved into the essay or made their own topic, but I have all the info.

References

  1. Kimes, Laura. Biomass Conversion: Emerging Technologies, Feedstocks, and Products Washington D.C, U.S. environmental protection agency, 2007.
  2. BioEnergy Trade, Copernicus Institute: the Netherlands. Oct. 26th 2008, [1].
  3. Faaij, Andre. "Modern Biomass Conversion Technologies.(Author abstract)." Mitigation and Adaptation Strategies for Global Change 11.2 (March 2006): 335(33). Academic OneFile. Gale. Middlebury College, Middlebury, VT. 29 Oct. 2008
  4. Shanmugam, P., and N.J. Horan. "Simple and rapid methods to evaluate methane potential and biomass yield for a range of mixed solid wastes.(Report)." Bioresource Technology 100.1 (Jan 2009): 471(4). Academic OneFile. Gale. Middlebury College, Middlebury, VT. 29 Oct. 2008
  5. Kimes, Laura. Biomass Conversion: Emerging Technologies, Feedstocks, and Products Washington D.C, U.S. environmental protection agency, 2007.
  6. Organisation for Economic Co-operation and Development. Biomass and Agriculture: Sustainability, Markets and Policies. Paris: OECD, 2004, p. 151.
  7. "Scientists set sights on biomass to reduce fossil fuel dependence". 2006, Imperial College London. October 29th, 2008. http://www.physorg.com/news10331.html
  8. Faaij, Andre. "Modern Biomass Conversion Technologies.(Author abstract)." Mitigation and Adaptation Strategies for Global Change 11.2 (March 2006): 335(33). Academic OneFile. Gale. Middlebury College, Middlebury, VT. 29 Oct. 2008.
  9. Pacala, S. and Socolow, R., "Stabilization Wedges: Solving the Climate Problem for the Next 50 Years with Current Technologies". 2004 www.sciencemag.org, October 28th, 2008.
  10. Faaij, Andre. "Modern Biomass Conversion Technologies.(Author abstract)." Mitigation and Adaptation Strategies for Global Change 11.2 (March 2006): 335(33). Academic OneFile. Gale. Middlebury College, Middlebury, VT. 29 Oct. 2008.
  11. Turner, A. John,"Sustainable Hydrogen Production". 2004, www.sciencemag.com, October 28th, 2008.
  12. Ray, Sarah, "New biomass facility to reduce greenhouse gases by almost 12,500 tons a year". 2006, Middlebury College, October 15th, 2008. http://www.middlebury.edu/about/pubaff/news_releases/2006/news632951384540792349.htm
  13. Biomass Assessment Team, "Biomass Fuel Assessment for Middlebury College" (2004)
  14. Faaij, Andre. "Modern Biomass Conversion Technologies.(Author abstract)." Mitigation and Adaptation Strategies for Global Change 11.2 (March 2006): 335(33). Academic OneFile. Gale. Middlebury College, Middlebury, VT. 29 Oct. 2008.
  15. Organisation for Economic Co-operation and Development. Biomass and Agriculture: Sustainability, Markets and Policies. Paris: OECD, 2004, p. 354.
  16. Organisation for Economic Co-operation and Development. Biomass and Agriculture: Sustainability, Markets and Policies. Paris: OECD, 2004, p. 307.
  17. Wahlberg, Katarina. Are We Approaching a Global Food Crisis? Between Soaring Food Prices and Food Aid Shortage. 2008, http://www.globalpolicy.org/socecon/hunger/general/2008/0303foodcrisis.htm, October 29th, 2008.
  18. Organisation for Economic Co-operation and Development. Biomass and Agriculture: Sustainability, Markets and Policies. Paris: OECD, 2004, p. 93.
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