Biomass as an Energy Source
John Deutch, "director of energy research and undersecretary of Energy in the Carter administration, ... director of the CIA and deputy secretary of Defense in the first Clinton administration, [and] professor of chemistry at MIT" is enthusiastic about cellulosic biomass as an energy source:
Biomass Movement, by John Deutch, Commentary, NY Times: President Bush has made the welcome point that the U.S. needs "to move beyond a petroleum-based economy," and has lent his support to the need to develop energy from biomass... This is popular with the public and also enjoys significant support in Congress. Unfortunately, congressional subsidies for biomass are driven by farm-state politics rather than by a technology-development effort that might offer a practical liquid fuel alternative to oil. ...
Biomass can be divided into two classes: food-crop and cellulosic. Natural enzymes can easily break down food-crop biomass such as corn to simple sugars, and ferment these sugars to ethanol. Cellulosic biomass -- which includes agricultural residues from food crops, wood and crops such as switch grass -- cannot easily be "digested" by natural enzymes.
Today, we use corn to produce ethanol in an automobile fuel known as "gasohol" -- 10% ethanol and 90% gasoline. Generous federal and state subsidies, largely in the form of exemption from gasoline taxes for gasohol, explain the growth of its use... Politicians from corn-states and other proponents of renewable energy support this federal subsidy, but most energy experts believe using corn to make ethanol is not effective in the long run because the net amount of oil saved by gasohol use is minimal.
In the U.S., ... a significant amount of oil and natural gas is used in growing, fertilizing and harvesting [corn]. Moreover, there is a substantial energy requirement -- much of it supplied by diesel or natural gas -- for the fermentation and distillation process that converts corn to ethanol. ... While there is some quarreling among experts, it is clear that it takes two-thirds of a gallon of oil to make a gallon equivalent of ethanol from corn. Thus one gallon of ethanol used in gasohol displaces perhaps one-third of a gallon of oil or less. A federal tax credit of 10 cents per gallon on gasohol, therefore, costs the taxpayer a hefty $120 per barrel of oil displaced cost. Surely it is worthwhile to look for cheaper ways to eliminate oil.
The economics are not the same in other countries. Brazil is a well-known example, where sugarcane grows in the tropical climate and conventional fermentation and distillation readily yields ethanol. Ethanol is said to provide 40% of automobile fuel in Brazil and compete with gasoline without government subsidy. Depending on the future world price of sugar and the lessening of trade restrictions on both sugar and sugar-derived ethanol, Brazil could become a net exporter of this biofuel.
The situation in the U.S. is quite different for cellulosic biomass, because much less petroleum is used in its cultivation. There are two paths to convert this material to liquid fuel. In the chemical approach the cellulosic feedstock is gasified with oxygen to produce synthesis gas... This "syngas" can be converted by conventional chemical techniques into liquid fuel suitable for transportation use. The cost, although uncertain and dependent upon local production conditions, is in the range of $50 to $70 per barrel of oil, which explains why, until now, it has not attracted a great deal of attention.
The biotech approach, by contrast, seeks to produce new enzymes that will break down the difficult-to-digest cellulosic feedstock into simple sugars... This approach merits genuine enthusiasm... Realizing this exciting prospect will not be easy... Success will require a sustained research effort; it is too early to estimate the production costs of this method, because process conditions are unknown. However, the expected fossil energy inputs for cellulosic biomass will be much less than that of gasohol, because the energy cost for cultivation is less, and because the portion of the cellulosic material not converted to ethanol can be burned to provide process heat -- thus substantially lowering the implied cost of federal tax subsidies per barrel of oil displaced.
I will be astonished, but delighted, if the cost of ethanol or other biomass-derived chemicals proves to be less than $40 per barrel of its oil equivalent, and if large-scale production can be accomplished in six years.
Critics of biomass argue that the conversion of sunlight into plant material is "inefficient," and that impractically large amounts of land would be required to produce significant amounts of transportation fuel. Both arguments are overstated. We should be humble about calling natural photosynthesis "inefficient" -- especially since we clever chemists cannot accomplish any artificial photosynthesis in the lab. At present, artificial photosynthesis is not an option, but it is an important basic research goal.
As for the land required to support significant biofuel production from a dedicated energy crop, switch grass offers a basis for estimation. ... [T]he land ... needed to displace one million barrels of oil per day (about 10% of U.S. oil imports projected by 2025), is 25 million acres (or 39,000 square miles). This is roughly 3% of the crop, range and pasture land that the Department of Agriculture classifies as available in the U.S. I conclude that we can produce ethanol from cellulosic biomass sufficient to displace one to two million barrels of oil per day in the next couple of decades, but not much more. This is a significant contribution, but not a long-term solution to our oil problem. ...
Posted by Mark Thoma on Wednesday, May 10, 2006 at 12:06 AM in Economics, Oil, Policy, Regulation | Permalink | TrackBack (0) | Comments (5)
There is a ready source of cellulosic biomass that would be essentially free on a marginal basis: grass clippings from the lawns of the tens of millions of American homes. Right now most of that goes into landfills where it eventually rots into methane gas. The city of Portland, OR has a power plant that burns methane gas generated by an old landfill that has been capped.
Posted by: Scott Peterson | Link to comment | May 09, 2006 at 10:36 PM
Scott - you mean Americans don't compost? Amazing.
Still I've often wondered if (genetic engineered?) algae grown in seawater on desert land is a potential solution. Saudi Arabia could rise again even after the oil is all gone!
Posted by: reason | Link to comment | May 10, 2006 at 01:35 AM
reason: Anything to do with sea water has the problem of salination that has to be taken care of, at some (energy) expense that has to be accounted for.
Posted by: cm | Link to comment | May 10, 2006 at 08:30 AM
Anything to do with sea water has the problem of salination that has to be taken care of, at some (energy) expense that has to be accounted for.
cm - not necessarily, lotsa alga are VERY salt tolerant and would easily grow in salt water 'aqua culture' farms... with the salt water being provided by the Red Sea & Persian Gulf in Arabia's case. In a similar fashion Baja California, Australia, North Africa, etc. might also find themselves equally 'well endowed'.
There is a LOT of work to be done before this is even close to a comic strip sci fi reality. I worked in bio-fuels once & they aren't that much farther along now from a 'technology' perspective than they were when I was in it... and that was in Reagan's FIRST term.
Still worth watching & waiting for. Just not unrealistically.
Posted by: dryfly | Link to comment | May 10, 2006 at 03:16 PM
cm,
I'm not sure that I worry too much about salination in deserts - but of course salination of ground water is another issue. You would need to consider your site carefully.
Posted by: reason | Link to comment | May 11, 2006 at 06:12 AM