For information on plastics derived from renewable raw resources, see Bioplastic. For information on plastics which are biodegradable see Biodegradable plastic.

Biodegradable plastics are plastics that will decompose in the natural environment. Plastic is the general common term for a wide range of synthetic or semisynthetic organic solid materials suitable for the manufacture of industrial products Decomposition (or spoilage) refers to the break down of tissue of a formerly living Organism into simpler forms of matter See also Nature The natural environment, commonly referred to simply as the environment, is a terminology that is comprised of all living and Biodegradation of plastics can be achieved by enabling microorganisms in the environment to metabolize the molecular structure of plastic films to produce an inert humus-like material that is less harmful to the environment. Biodegradation is the process by which organic substances are broken down by the enzymes produced by living organisms Plastic is the general common term for a wide range of synthetic or semisynthetic organic solid materials suitable for the manufacture of industrial products A microorganism (also spelled micro organism or micro-organism and also called a microbe) is an Organism that is Microscopic (usually Metabolism is the set of Chemical reactions that occur in living Organisms in order to maintain Life. Humus (Origin 1790–1800 Latin: earth ground) is the organic material in Soil lending it a dark brown or black colouration Bioplastics are biodegradable plastics whose components are derived from renewable raw materials. For information on plastics which are biodegradable see Biodegradable plastic. The use of bio-active compounds compounded with swelling agents ensures that, when combined with heat and moisture, they expand the plastic's molecular structure and allow the bio-active compounds to metabolise and neutralize the plastic.

Contents 1 Advantages and disadvantages 2 Mechanisms 3 Environmental concerns 4 Energy Costs For Production 5 References 6 See also 7 External links

Advantages and disadvantages

The advantage of biodegradable plastics is that, in the proper conditions (sun, moisture, oxygen, etc), the plastics degrade to the point where organisms can digest them. This reduces problems with litter and reduces harmful effects on wildlife. Litter is Waste disposed in the wrong place by Unlawful human action and can vary in size of incident occurrence or items Composting is a good methodology. Composting is the Aerobic decomposition of Biodegradable Organic matter, producing Compost.

The main disadvantage with oil-based biodegradable plastics is that their degradation may contribute to global warming through the release of carbon dioxide as a main end product. Petroleum ( L petroleum, from Greek πετρέλαιον, lit Biodegradation is the process by which organic substances are broken down by the enzymes produced by living organisms Global warming is the increase in the average measured temperature of the Carbon dioxide ( Chemical formula:) is a Chemical compound composed of two Oxygen Atoms covalently bonded to a single This does not apply to starch-based plastics as they are formed from carbon which is already in the ecosystem (via photosynthesis). Starch, CAS # 9005-25-8 Chemical formula (C6H10O5n is a Polysaccharide Photosynthesis is a Metabolic pathway that converts Light Energy into Chemical energy. Another disadvantage with biodegradable plastic is that degradation occurs very slowly, if at all, in a sealed landfill. Also, biodegradable plastics cannot be mixed with other plastics when sent for recycling; this damages the recycled plastic and reduces its value.

Mechanisms

Materials such as polyhydroxyalkanoate (PHA) biopolymer are completely biodegradable. Biopolymers are a class of Polymers produced by living organisms Fully biodegradable plastics are more expensive, partly because they are not widely enough produced to achieve large economies of scale.

Other types are semi-biodegradable, but avoid increased costs by using existing manufacturing processes and are based mainly on conventional non-biodegradable resins. These plastics can be manufactured to be clear or opaque, and in any color. A disadvantage of this approach is that the products of degradation of the conventional material will remain in the environment for years.

Environmental concerns

Over 200 million tonnes of plastic are manufactured annually around the world, according to the SPE. The Society of Plastics Engineers (SPE is an international organization dedicated to the advancement of knowledge and education for all Plastics professionals Of those 200 million tons, 26 million are manufactured in the United States. The EPA reported in 2003 that only 5. 8% of those 26 million tons of plastic waste are recycled, although this is increasing rapidly.

Energy Costs For Production

Various researchers have undertaken extensive life cycle assessments of biodegradable polymers to determine whether these materials are more energy efficient than polymers made by conventional fossil fuel-based means. Research done by Gerngross, et al estimates that the fossil fuel energy required to produce a kilogram of polyhydroxyalkanoate (PHA) is 50. 4 MJ/kg ^{[1] [2]}, which coincides with another estimate by Akiyama, et al^[3], who estimate a value between 50-59 MJ/kg. This information does not take into account the feedstock energy, which can be obtained from non-fossil fuel based methods. Polylactide (PLA) was estimated to have a fossil fuel energy cost of 54-56. 7 from two sources^{[4] [5]}, but recent developments in the commercial production of PLA by NatureWorks has eliminated some dependence fossil fuel based energy by supplanting it with wind power and biomass-driven strategies. They report making a kilogram of PLA with only 27. 2 MJ of fossil fuel-based energy and anticipate that this number will drop to 16. 6 MJ/kg in their next generation plants. In contrast, polypropylene and high density polyethylene require 85. 9 and 73. 7 MJ/kg respectively^[6], but these values include the embedded energy of the feedstock because it is based on fossil fuel.

Gerngross reports a 2. 65 total fossil fuel energy equivalent (FFE) required to produce a single kilogram of PHA, while polypropylene only requires 2. 2 kg FFE^[7]. While this assessment is valid, it is important to realize the feedstock for PP continues to be fossil fuel-based, and in the light of limited fossil based resources, production of polymers with a slight increase in total energy could be advantageous by lowering dependence on fossil fuels. Gerngross assesses that the decision to proceed forward with any biodegradable polymer alternative will need to take into account the priorities of society with regard to energy, environment, and economic cost.

Furthermore, it is important to realize the youth of alternative technologies. Technology to produce PHA, for instance, is still in development, and energy consumption can be further reduced by eliminating the fermentation step,^[8] or by utilizing food waste as feedstock. ^[9] The use of alternative crops other than corn, such as sugar cane from Brazil, are expected to lower energy requirements- manufacturing of PHAs by fermentation in Brazil enjoys a favorable energy consumption scheme where bagasse is used as source of renewable energy. Bagasse (sometimes spelled bagass) is the Biomass remaining after Sugarcane or Sorghum stalks are crushed to extract their juice and is ^[10]

Many biodegradable polymers that come from renewable resources (i. e. , starch-based, PHA, PLA) also compete with food production, as the primary feedstock is currently corn. For the US to meet its current output of plastics production with BPs, it would require 1. 62 square meters per kilogram produced^[11]. While this space requirement could be feasible, it is always important to consider how much impact this large scale production could have on food prices and the opportunity cost of using land in this fashion versus alternatives.

References

1. ^ Gerngross, T. U. Nature Biotechnology 1999, 17, 541-544.
2. ^ Gerngross, T. U. ; Slater, S. C. Scientific American 2000, 283, 37-41.
3. ^ Akiyama, M. ; Tsuge, T. ; Doi, Y. Polymer Degradation and Stability 2003, 80, 183-194.
4. ^ Vink, E. T. H. ; Rabago, K. R. ; Glassner, D. A. ; Gruber, P. R. Polymer Degradation and Stability 2003, 80, 403-419.
5. ^ Bohlmann, G. Biodegradable polymer life cycle assessment, Process Economics Program, 2001.
6. ^ Frischknecht, R. ; Suter, P. Oko-inventare von Energiesystemen, third ed. , 1996.
7. ^ Gerngross, T. U. ; Slater, S. C. Scientific American 2000, 283, 37-41.
8. ^ Metabolix
9. ^ Microbes manufacture plastic from food waste Technology News, April 10, 2003. Last retrieved June 13, 2007.
10. ^ PHB Industrial, Brazil
11. ^ Vink, E. T. H. ; Glassner, D. A. ; Kolstad, J. J. ; Wooley, R. J. ; O'Connor, R. P. Industrial Biotechnology 2007, 3, 58-81.

See also

• Biodegradable waste
• Plastic bag
• Photodegradation
• Bioplastic

External links

• The European Bioplastics Association Information on Bioplastics and Biodegradable Polymers, Market Information
• bioplastics24.com News and market directory for the bioplastics industry
• Biopolymer.net : Links to organisations, companies and everything related to biopolymers/bioplastics. Biodegradable waste is a Type of waste, typically originating from Plant or Animal sources which may be broken down by other living organisms A plastic bag or pouch is a type of flexible Packaging made of thin flexible plastic film Photodegradation is degradation of a photodegradable Molecule caused by the absorption of Photons, particularly those Wavelengths found For information on plastics which are biodegradable see Biodegradable plastic.
• Friendly Bags Great source for articles on biodegradable plastic bags
• Wiki Wiki of Biodegradable materials
• Cereplast Biodegradable plastic manufacturer
• KAYSONS 'Low Cost' Biodegradable plastic manufacturer

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