Revision as of 22:49, 28 September 2011

one

two

References:

1. http://ourenergypolicy.org/docs/2/biofuels-taskforce.pdf

2. http://www.environment.gov.au/atmosphere/fuelquality/publications/2000hours-vehicle-fleet/pubs/2000-hours-vehicles.pdf

3. Anaerobic Metabolism of Biodiesel and Its Impact on Metal Corrosion Deniz F. Aktas, Jason S. Lee, Brenda J. Little, Richard I. Ray, Irene A. Davidova, Christopher N. Lyles, Joseph M. Suflita Energy & Fuels 2010 24 (5), 2924-2928(http://pubs.acs.org/doi/full/10.1021/ef100084j)

4. http://www.mda.state.mn.us/news/publications/renewable/biodiesel/biodieselcoldissues.pdf

5. http://www.afdc.energy.gov/afdc/pdfs/fueltable.pdf

6. The viscosities of three biodiesel fuels at temperatures up to 300°C R.E. Tate, K.C. Watts, C.A.W. Allen K.I. Wilkie Fuel 2006 85, 1010-1015 (https://netfiles.uiuc.edu/mccrady/shared/Biodiesel/The%20viscosities%20of%20three%20biodiesel%20fuels%20at%20temperatures%20up%20to%20300%208C.pdf)

7. http://www.dtic.mil/cgi-bin/GetTRDoc?AD=ADA317177&Location=U2&doc=GetTRDoc.pdf

8. Microbial Biosynthesis of Alkanes Andreas Schirmer, Mathew A. Rude, Xuezhi Li, Emanuela Popova and Stephen B. del Cardayre Science 30 July 2010: Vol. 329 no. 5991 pp. 559-562 http://www.sciencemag.org/content/329/5991/559

9.http://msdssearch.dow.com/PublishedLiteratureDOWCOM/dh_0119/0901b803801195a5.pdf?filepath=oxysolvents/pdfs/noreg/327-00014.pdf&fromPage=GetDoc

10.Metabolic engineering of Escherichia coli for 1-butanol production Shota Atsumi, Anthony F. Cann, Michael R. Connor, Claire R. Shen, Kevin M. Smith, Mark P. Brynildsen, Katherine J.Y. Chou, Taizo Hanai1, James C. Liao Metabolic Engineering Volume 10, Issue 6, November 2008, Pages 305-311

11. http://www.nrel.gov/vehiclesandfuels/pdfs/sr368051.pdf

12. http://www.arpltd.com/n-butano.htm

last section

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Team:Washington/Protocols/test

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Revision as of 22:49, 28 September 2011

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+Deniz F. Aktas, Jason S. Lee, Brenda J. Little, Richard I. Ray, Irene A. Davidova, Christopher N. Lyles, Joseph M. Suflita  Energy & Fuels 2010 24 (5), 2924-2928(http://pubs.acs.org/doi/full/10.1021/ef100084j)
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+. The viscosities of three biodiesel fuels at temperatures up to 300°C
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+R.E. Tate, K.C. Watts, C.A.W. Allen K.I. Wilkie Fuel 2006 85, 1010-1015 (https://netfiles.uiuc.edu/mccrady/shared/Biodiesel/The%20viscosities%20of%20three%20biodiesel%20fuels%20at%20temperatures%20up%20to%20300%208C.pdf)
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+. Microbial Biosynthesis of Alkanes  Andreas Schirmer, Mathew A. Rude, Xuezhi Li, Emanuela Popova and Stephen B. del Cardayre Science 30 July 2010: Vol. 329 no. 5991 pp. 559-562   http://www.sciencemag.org/content/329/5991/559
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+.Metabolic engineering of Escherichia coli for 1-butanol production Shota Atsumi, Anthony F. Cann, Michael R. Connor, Claire R. Shen, Kevin M. Smith, Mark P. Brynildsen, Katherine J.Y. Chou, Taizo Hanai1, James C. Liao  Metabolic Engineering Volume 10, Issue 6, November 2008, Pages 305-311
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-:::::::::::::::::<font face=sans-serif><font-weight: bold><span style="font-size:110%">The ideal fuel would be compatible with modern engines and  infrastructure, and also be able to be produced in a renewable manner. No current biofuel has the same identical enough to that of diesel to be able to  fully integrate with current engines and infrastructure. No known alternative fuel is able to match the chemical properties of diesel. Currently, the only way to renewably  produce a fuel with the chemical properties and compatibility of diesel would be to make a biofuel with a composition identical to that of diesel. This would require a biological pathway that is able to produce alkanes, the main class of compounds in diesel. Alkanes are simple chains of carbon and hydrogen. The majority of the alkanes found in diesel have a carbon chain of 10 to 20 carbons long. Alkanes make up approximately 62%  of jet diesel (a fairly representative diesel fuel)([[#References | [7]]]). This 62% includes 34% straight chain alkanes that contain only one linear chain, and 28% branched chain alkanes that contain 1 or more carbon branches. The remaining 38% consists mostly of cyclic and aromatic hydrocarbons.  If long (10+) chain length alkanes could be biologically produced, it would allow for the production of a fuel that is both renewable and fully compatible with current engines and infrastructure.</span></font>
-----
-= The Solution: a Microbial Alkane Production Pathway=
-[[Image:Washington2011_AlkaneAndBackCycle.png|right|400px|frameless]]
-A recent study([[#References | [8]]]) conducted by LS9, inc. has shown the production of long chain length alkanes in ''E. coli'' using two genes found in many cyanobacteria species. The first gene codes for Acyl-ACP Reductase (AAR) which reduces long chain length acyl-ACPs into the corresponding fatty aldehydes. Acyl-ACPs are  essential intermediates in fatty acid biosynthesis in every known organism, meaning that this system can work in a wide range of organisms. This long chain fatty acid acts as a substrate for Aldehyde Decarbonylase (ADC), the enzyme that removes the carbonyl group (C=O) from the fatty aldehyde, yielding an alkane one carbon shorter than the original Acyl-ACP and a molecule  of formate. Since the vast majority of the fatty acyl-ACPs produced by ''E. coli'' have an even chain length, this system produces detectable amounts of only odd chain length  alkanes. This study reported production of the C13, C15, and C17 alkanes, as well as the C17 alkene (unsaturated hydrocarbon), with a maximum alkane yield of 300 mg/L. This chain length range fall well within the range of those found in diesel, so this system is theoretically able to make the alkane portion of a fuel compatible with current engines and infrastructure.
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