HHMI Teachers’ Workshop: Biofuels – More Than Ethanol From Corn Starch Aditya Kunjapur, Ph.D. Candidate, MIT July 20,
Outline Context for biofuels and key facts Photosynthesis and carbon fixation Feedstocks Fuels Recap 2
Context for biofuels and key facts Photosynthesis and carbon fixation Feedstocks Fuels Recap 3 Outline
What is “BioEnergy” According to the International Energy Agency (IEA): “Material which is directly or indirectly produced by photosynthesis and which is utilized as a feedstock in the manufacture of fuels and substitutes for petrochemical and other energy intensive products.” 4 IEA Bioenergy:
Overview of BioEnergy 5 Energy Photosynthesis Chemosynthesis Photons Inorganic Molecules -Plants -Algae -Cyanobacteria -Chemolithotrophs (in deep oceans, isolated caves, etc) Fuels or Chemicals Biomass + CO 2 Enzymatic -Same organism -Different organism Thermochemical -Pyrolysis -Gasification -Ethanol -Biodiesel -Jet Fuel -Methane Energy Capture Chemical Conversion
Some advantages of bioenergy compared to other renewables The only renewable source that can replace fossil fuels in all energy markets – in the production of heat, electricity, and fuels for transport (IEA) The source of a variety of drop-in liquid fuels The source of petroleum in the first place The primary way by which atmospheric CO 2 is consumed 6
7
8 Breakdown of US renewables in
Percentage of the world’s energy 9 Biomass-based energy accounted for ~10% of world total primary energy supply in 2009 – Includes cooking/heating in developing countries Global production of biofuels: – 2000: 16 billion liters – 2011: 100+ billion liters Total road transport fuel globally: 3% – Brazil: 23% Source: IEA
Life cycle of traditional biofuels Important consideration: life cycle greenhouse gas emissions SC Opinion on Greenhouse Gas Accounting in Relation to Bioenergy: committee/sc-opinions/opinions-on-scientific-issues/ Image: 10
11
Context for biofuels and key facts Photosynthesis and carbon fixation Feedstocks Fuels Recap 12 Outline
Photosynthesis: Overview 13 Image: Oxidation/reduction (Redox) reactions – CO 2 gets reduced to glucose – H 2 O gets oxidized to O 2
Photosynthesis: Inside a Chloroplast 14 Image:
Photosystems convert light energy into reducing equivalents 15 Image:
The Calvin Cycle uses those reducing equivalents to turn CO 2 into sugar 16 Image:
17
Typical efficiency of photosynthesis 18 Figure based on statistics listed here: 100% Sunlight 47% Non-Bioavailable Photons 53% (in nm range) 30% Not Absorbed 37% (Absorbed Photon Energy) 24% Wavelength Mismatch 28% (Energy Captured in Chlorophyll) 68% Loss in Conversion of ATP and NADPH to glucose 9% (Collected as sugar) 40% Loss in Dark and Photo- Respiration ~5% Net Leaf Efficiency
Context for biofuels and key facts Photosynthesis and carbon fixation Feedstocks Fuels Recap 19 Outline
Feedstocks 20 Image: Two categories of photosynthetic organisms: 1)Those that capture light energy into non-fuel biomass - Chemical conversion still required 2)Those that capture light energy and produce a fuel - Only physical separation required
21 Image: Source of facts: EIA – Biofuel Trends and Issues – Oct 2012 Estimated corn use for ethanol production (2011): 4.9 billion bushels or 279 billion pounds
Drawbacks of Corn as a Feedstock 22 Image: Used for food Grows slowly Grows only on arable land Provides low energy per acre Is an annual crop
23
Can grow up to 8 feet in 6 weeks 24 Image:
25 Source: “Biodiesel from microalgae.” Energy yield per acre does not favor corn ?
Bioreactors/ponds used to grow algae 26 Images: ; Bioreactors required to cultivate high cell densities
27 Images: both from -Algal cells make up very small fraction of pond -Dewatering and processing is cost-prohibitive Bioreactors/ponds used to grow algae
28
Cellulose 29
30
31 I Gelfand et al. Nature 000, 1-4 (2013) doi: /nature11811
Cellulosic biofuel – a reality? 32
Context for biofuels and key facts Photosynthesis and carbon fixation Feedstocks Fuels Recap 33 Outline
Pathway to ethanol 34 Glycolysis (~10 enzymatic reactions) Image: Pyruvate decarboxylase Alcohol dehydrogenase Under anaerobic conditions (no O 2 ):
Drawbacks of ethanol 35 Hygroscopic Miscible with water Low energy density Requires different distribution system than gasoline Limit to how much can be added to conventional engines
36
37 The E10 “Blend Wall”
Alternative fuel options Longer, branched alcohols Biodiesel Methane – Methanogens – CO 2 + 4H 2 CH 4 + 2H 2 O – Important for waste-to-energy 38 Image:
39 Images: (Left) time/Weber/Microbiology%20Majors/Chpater5/chapter5sub/figure_05_30_labeled.jpg
Context for biofuels and key facts Photosynthesis and carbon fixation Feedstocks Fuels Recap 40 Outline
Overview of BioEnergy 41 Energy Photosynthesis Chemosynthesis Photons Inorganic Molecules -Plants -Algae -Cyanobacteria -Chemolithotrophs (in deep oceans, isolated caves, etc) Fuels or Chemicals Biomass + CO 2 Enzymatic -Same organism -Different organism Thermochemical -Pyrolysis -Gasification -Ethanol -Biodiesel -Jet Fuel -Methane Energy Capture Chemical Conversion
Recap and take home points Traditional biofuels have several drawbacks When evaluating a biofuel process, consider: – Carbon lifecycle – Food versus fuel – Land (or water) required – Feedstock transportation – Desired end fuel Research efforts directed toward production of advanced and cellulosic biofuels make most sense (just my opinion!) 42
Thank you for listening! 43 Questions?