More uses for biofuel byproducts on the way

Researchers, entrepreneurs, and venture capitalists nation-wide are looking for potential uses for the byproducts from large scale biofuel production. Researchers hope to achieve an industry similar to the traditional oil refinery industry where as the raw material is processed, a multitude of products are produced in addition to the primary product (fuel). Researchers believe that as more value is obtained from these byproducts, the economic viability of biofuels such as ethanol will increase.

One company, Purevision, is working on a way to convert lignin so that it can be used in glues, sealants, and detergents. “Most plans for cellulosic ethanol processing call for burning the lignin to generate steam and heat to run the process. As a fuel, lignin is worth around $40 a ton. PureVision has devised a way to make a different form of lignin–one with a molecular composition that could make it an attractive material for a variety of industrial products like glues, sealants and detergents. Ed Lehrburger, PureVision’s founder and chief executive, said he thought his lignin could sell for $300 a ton or more. Lehrburger said his company was collaborating with a wood and paper products manufacturer that is interested in using the lignin for a biobased glue for its laminates, plywoods and other products.

Lignin makes up roughly 25% of the total mass of most plants.  Suppose that by 2017 we achieve Bush’s goal of 35 billion gallons of ethanol per year.  Since many experts put the maximum corn ethanol production for the US at around 15 billion gallons, this means that roughly 20 billion of these gallons will need to come from cellulosic sources.  At 100 gallons of ethanol per ton of switchgrass (a huge simplification): 20 billion gallons/100 g/t*.25t lignin/t biomass = 50 million tons.  50 million tons *300 dollars per ton= 15 billion dollars/year.  Say that the only half of this lignin is able to be obtained, it is still a 7.5 billion dollar per year industry.  This is huge.  Of course this all depends on how much it costs to convert a ton of lignin from being worth $40/ton to $300/ton and the details in the article seem to be lacking here.

“Lin and his colleagues are trying to turn the resulting glycerol into a substance called 1,3 propanediol, or PDO, the base material for a substance used in upholstery, carpets, clothing and other applications. DuPont uses PDO to make its Sorona line of fabrics.  “For every gallon of biodiesel you make, you make a pound of glycerol,” said George Kraus, a professor of chemistry at Iowa State, where he is director of the Center for Catalysis and a collaborator of Lin. “A lot of people have been contacting us about burning it, and we say there have to be better uses.”  The price of glycerol, now 20 to 50 cents a pound, could drop as low as 5 cents a pound as biodiesel production increases.  Kraus said the higher quality glycerol made with the new process could command a much higher price. “What we see,” he said, “is an opportunity to make something that might cost 80 cents a pound.”  This isn’t exactly relevant to this site but it is interesting none the less.

Many believe that as more uses are found for what are currently waste streams from biorefineries, the economics of biofuels will improve.  Anyway, the article goes through many other examples like the ones I quoted and is definitely worth a read.

KL Group Turning Wood Waste into Ethanol

A newly built plant in Upton Wyoming is grinding wood waste into fine particles that can then be turned into ethanol. The plant, which is operated by KL process design group produces 1.5 million gallons of ethanol per year and once the plant is in full operation will employ 13 workers. The key to the KL process is the way that they finely grind the wood waste which leaves it vulnerable to enzymatic attack. “The way we grind the feedstock is what separates us from other cellulose plants” More information on fine grinding advantages can be found here.

One of the problems that is often brought up regarding corn derived ethanol is that it requires almost as much energy to make as one is able to get out of it. This is not the case with wood waste derived ethanol, KL estimates: “the process at the Upton plant requires less than 20,000 British thermal units to produce a gallon of ethanol, which has about 80,000 BTU of energy.” Since the waste is there anyway and likely would have been burned just to get rid of it, there seems to be very little negative side effect to this process. The only cost of the feedstock is transporting it to the plant. “Bill Baker of Baker Timber Products in Rockerville has agreed to be a supplier of wood waste for the new plant.”

“The U.S. Forest Service and other Black Hills land managers want to thin the forest of its small-diameter trees and other low-value wood materials. A thinned forest is less susceptible to catastrophic fires. It’s also less susceptible to pine beetle infestation.” Plants like these will allow the Forest Service an easy way of disposing of dangerous and excess forest material.

On such a small scale (1.5 million gallons per year is very small for an ethanol plant), the economics of the plant are questionable. KL believes that as larger plants are developed, the costs associated with production will decrease. It will be important to remember though that while the costs of production should decrease as scale increases, the average cost/ton to transport waste to the plant will increase since the average travel distance will increase (the plant will have to pull from a far larger “sphere of influence”). From the Article: “The issue we will need to deal with is purely a transportation cost issue,” Kramer said. He admits that the small scale of the Upton plant makes wood a less cost effective feedstock. “However, on a scaled-up version to 20 million gallons per year, the economics are certainly in favor of the wood waste as a feedstock.”

Rep John McDonough on Cellulosic Ethanol in Maine

Rep. John McDonough has written a piece for the Portland Press Herald about how he believes Maine needs to invest heavily in technology to create cellulosic ethanol from wood.  He believes that Maine due to it’s large forested areas can become the “Saudi Arabia” of ethanol.

As to why he believes that Maine should invest in cellulosic ethanol, he says:

“For one, it takes much less energy to grow trees. Fertilizer is not required, and Mother Nature takes care of irrigation. Trees also are available year-round and do not come and go with the growing season.

Wood is not a food source and it has a higher energy yield than corn. Unlike with corn-based ethanol, you get more energy out of the process than you put in.

Rising fuel prices are not the only reason this development is critical and timely. In the age of terrorism, we find ourselves reliant on foreign oil from countries run by hostile regimes, giving them the power to manipulate — or cripple — our economy. Energy independence isn’t just about price security, it is about national security.”

What so many people don’t seem to understand is that it is all about economics.  Wood is expensive.  Most trees (excluding poplars and the like) grow extremely slowly compared with other potential energy crops.  When you include the opportunity cost of the land’s value and taxes etc. it is expensive to own land to grow trees and this is why wood is so expensive as a feedstock (and will only continue getting more expensive as demand rises).

Trees are also a carbon “sink” (see my article on carbon flux), which basically means that they are storing carbon that would otherwise be in the atmosphere contributing to global warming.  If a tree gets replanted, this would seem irrelevant, but this becomes problematic when trees do not get replanted.  Also when trees get replanted, it often leads to a monoculture which is obviously bad for biodiversity.

I am not saying that ethanol from wood is necessarily a poor idea, just that it’s potential is limited.  People often think of the huge amounts of trees that we have in this country and think, what an amazing source of fuel.  It is not nearly that easy, there are a lot of negative consequences to cutting down a lot of trees thus it needs to be done in a sustainable way.  It will certainly be one piece in the cellulosic ethanol puzzle, although it seems extremely unlikely that Maine will become the new “Saudi Arabia” of ethanol.

One more noted section of the article: “Our paper mills can use the leftover wood they usually burn or send to landfills for ethanol creation instead.”

Paper mills burn the leftover material in order to generate power for the plant.  If the wood is instead converted to ethanol then the plants will need to spend millions of dollars more per month on electricity.

Cellulosic Ethanol from Rice Straw Plant Being Built in California

Ron Kotrba has written an incredibly interesting article for Ethanol Producer Magazine about a company which hopes to soon be making ethanol from rice straw in California.  Currently, California rice farmers must pay $25 to $45 per acre to have the rice straw baled and removed from their fields.  Colusa Biomass Energy Corp. (CBEC), the company which is currently in the process of building their first plant to process rice straw, has offered to take it off their hands for a mere $15.  There is a general understanding that once the plant is built CBEC will be removing the straw at no charge.

Rice straw has limited other uses since it has a very high sodium silicate content which is not palatable to livestock and is very abrasive for machinery.  CBEC intends to separate the silicate and use it as an extra revenue stream, selling it to a range of manufacturers.

The plant will be relatively small, processing “35,000 acres of rice straw into 12.5 MMgy of ethanol and 33 million pounds of sodium silicate.”  This is not necessarily a bad thing however as it will cut down on average transportation costs to the plant.  Generally 3.5-4 tons of rice straw can be collected per acre.

The amazing thing is that CBEC will be doing this with no federal or state money.  They have generated enough investor interest to fund their project via investment capital.   CBEC has been doing small scale research for years, it is only relatively recently that they hired Harris group, a respected engineering firm to do an analysis to see whether their research can be scaled into an economical, large scale, continuous process.  Harris group seems to think that this is doable, so the project is moving forward.

The actual process is described by the article to work as follows:

“We wash it, then introduce a mild solution of a strong acid then [which] hydrolyzes out the lignin and the hemicellulose,” Bowers says. “Then a second hydrolysis process occurs where we extract the cellulose from the remaining substrate.” He says the process whereby CBEC hydrolyzes the substrate, removing most of the lignin and all of the silica, is proprietary. “We have designed the hardware and the software to propel a reverse osmosis custom filtration device that we built to do the extraction,” Bowers says. “Through filtration, we separate the silica out and precipitate it as silica sodium oxide, and from the other side we pull out the lignin.” Once the lignin is dried down, CBEC plans to use it as boiler fuel. The company’s sales forecasts indicate the ability to retrieve 34-cents a pound from the more than 33.5 million pounds of sodium silicate, a versatile compound used to make everything from micro-electronics to toothpaste.  Once the cellulose and hemicellulose are separated from the lignin and silica, fermentation begins. “Our fermentation will look just like the corn guys’,” Bowers says.”

I hope that they don’t look exactly the same, if CBEC tries to break down the cellulose like corn starch (using amylase), they are going to be sadly mistaken.  They will be needing to use cellulase which as far as I know still acts more slowly than amylase and will be considerably more expensive.  I wonder whether they are going to just take on the cost of the cellulase or if they have figured out a plan for this expensive item too.  I would be extremely interested in the details of how exactly their second hydrolysis process works as well.

“We’re considering separate five-C and six-C lines”–and how do they propose to enzymatically break down the hemicellulose? I could be very mistaken but as far as I know there is not yet an economical way to break down hemicellulose since hemicellulose consists of so many different sugars.  You would need a multitude of enzymes each being unique to the sugar that they attack.  They could break down the hemicellulose via acid hydrolyis however but that is questionably economical.

Anyway, the company hopes to expand to 11 refineries by 2012 located in California, Texas, and Arkansas.   In the long term they see a lot of potential for global expansion since rice is such a staple crop world wide.  Whether they succeed or not, I guess we will have to wait and see.

Senate Farm Bill Might end up Different from the House Version

The US house of representatives last week passed a farm bill which seems to be very generous to those who produce crops for ethanol.  Currently farmers who on average earn less than $2.5 million per year are eligible for crop subsidies.  The senate bill may reduce this limit to $1 million a year.  Some senators also want to reduce the maximum payment to farmers from $360,000 to $250,000.  The senate bill will also likely include a similar loan guarantee program for cellulosic ethanol plants to the $2 Billion which has already been passed by the house.

“Sen. John Thune, R-S.D., said Tuesday he supports plans to aid farmers in the cellulosic ethanol movement, saying incentives will be necessary to encourage farmers to grow certain crops.

“We have to have an economic driver for this thing,” Thune said.”

Unfortunately the problem with providing subsidies as incentives is that it will put the government in the position of picking winners and losers.  A carbon tax would be more fair, cheaper, provide less opportunity for loopholes, and would be a more efficient mechanism for transitioning to biofuels since the transition would be market driven.

In general, it looks as if the Senate is trying to write the bill to be more in the interest of small farmers than the house version.  Whether this is a good thing or not is a matter of personal opinion.

Disproving “The great biofuel fraud”

Someone by the name of F William Engdahl has recently written an article for the Asia Times. This however is not just any article, it is probably THE IDEAL example of an article based on faulty data and misinformation about ethanol. Here I am going to go through a lot of his arguments against ethanol and disprove them one by one. I will quote his statements and then provide a rebuttal with a source (most of the sources can actually be found in previous articles that have been discussed on this site). Don’t get me wrong, there are some valid and descent reasons to be against the mass production of ethanol, Engdahl however seems to get almost everything wrong.

” The center of Bush’s program, announced in his January State of the Union address, is called “20 in 10″, cutting US gasoline use 20% by 2010. The official reason is to “reduce dependency on imported oil”, as well as cutting unwanted “greenhouse gas” emissions. That isn’t the case, but it makes good PR. Repeat it often enough and maybe most people will believe it. Maybe they won’t realize their taxpayer subsidies to grow ethanol corn instead of feed corn are also driving the price of their daily bread through the roof.”

The most often repeated and first major argument of Engdahl’s is that corn ethanol competing with food increases the price of food and that is why food prices have increased so much in the past 18 months. In fact the main reason that the cost of food has gone up so drastically as of late is because of the rising cost of oil. This is because the cost of the actual corn is only a tiny percentage of the total cost of the food that we consume. To confirm this assessment I would refer interested readers and Mr. Engdahl to this report.

“The late American satirist Mark Twain once quipped, “Buy land: They’ve stopped making it.” Today we can say almost the same about corn, or all grains worldwide. The world is in the early months of the greatest sustained rise in prices for all major grains, including maize, wheat and rice, that we have seen in three decades. Those three crops constitute almost 90% of all grains cultivated in the world.”

When the cost of corn (the main ingredient in corn flakes) accounts for a mere 5% of the total cost of the box of cereal, even if the cost of corn doubles again next year it would still only increase the cost of your box of cornflakes by roughly $.20. This is not going to break anyone’s bank. The 90% figure is sensationalist and doesn’t matter even a little to basic supply/demand as anyone who has taken econ 101 can tell you.

“No advocate of the ethanol boondoggle addresses the huge social cost that is beginning to hit the dining-room tables across the US, Europe and the rest of the world. Food prices are exploding as corn, soybeans and all cereal-grain prices are going through the roof because of the astronomical – US Congress-driven – demand for corn to burn for biofuel.”

Correlation does not imply causation.

“Biofuel – gasoline or other fuel produced from refining food products – is being touted as a solution to the controversial global-warming problem. Leaving aside the faked science and the political interests behind the sudden hype about dangers of global warming, biofuels offer no net positive benefits over oil even under the best conditions.”

This is actually almost true, certain studies indicate that there is close to no net positive benefits from corn ethanol, others indicate slight benefits (generally no more than 30% however). Here is a study which likely is close to the truth. “For GHG emissions, E85 produced by dry milling achieves a 19% reduction, and E85 produced by wet milling achieves a 14% reduction.”

You also completely (and conveniently) neglect the expected carbon emission reductions associated with cellulosic ethanol:”Under the near-future case, for E85, woody cellulosic ethanol reduces petroleum use by
70%, GHG emissions by 102%, and fossil energy consumption by 79%.”

GHG = Green House Gas.

“Big Oil is also driving the biofuels bandwagon. Professor David Pimentel of Cornell University and other scientists claim that net energy output from bio-ethanol fuel is less than the fossil-fuel energy used to produce the ethanol. Measuring all energy inputs to produce ethanol, from production of nitrogen fertilizer to energy needed to clean the considerable waste from biofuel refineries, Pimintel’s research showed a net energy loss of 22% for biofuel – they use more energy than they produce. That translates into little threat to oil demand and huge profit for clever oil giants that re-profile themselves as “green energy” producers. “

Joke: What happens when you use crop yield and conversion efficiency data from the 70s when trying to do a life cycle analysis for today?

Punchline: You get data today that would have been a useful argument against ethanol during the 70s!

From the department of energy:

“The most official study of the issue, which also reviews other studies, concludes that the “net energy balance” of making fuel ethanol from corn grain is 1.34; that is, for every unit of energy that goes into growing corn and turning it into ethanol, we get back about one-third more energy as automotive fuel. That may not sound impressive, but bear in mind that while the gasoline that ethanol displaces is largely imported and a high-level pollution source, the mix of energy inputs for producing bioethanol includes much domestic and relatively cleaner energy. On the basis of liquid fuels alone, the net balance is 6.34 (USDA Office of Energy Policy and New Uses, The Energy Balance of Corn Ethanol: An Update).”

Also, the energy balance from sugar cane is between 8:1 and 10:1.

“The bio-ethanol architects did their homework, we can be assured. It’s increasingly clear that the same people who brought us oil-price inflation are now deliberately creating parallel food-price inflation. We have had a rise in average oil prices of some 300% since the end of 2000 when George W Bush and Dick “Halliburton” Cheney made oil the central preoccupation of US foreign policy. “

As I have already shown, the price of our food is far more dependant on the price of a barrel of oil than the price of a bushel of corn. Obviously as oil prices increase, food prices will increase (with a few year lag since the supply curve does not instantly correct itself).

“Environmental analyst Lester Brown recently noted, “We’re looking at competition in the global market between 800 million automobiles and the world’s 2 billion poorest people for the same commodity, the same grains. We are now in a new economic era where oil and food are interchangeable commodities because we can convert grain, sugarcane, soybeans – anything – into fuel for cars. In effect the price of oil is beginning to set the price of food.”"

The reason that people are starving isn’t because there is not enough food to feed the people of the world, it is because the people of the world can not afford to feed themselves due to lack of jobs. Yesterday I wrote about an article which highlights how a Chinese company is buying up millions of acres of Congo palm oil plantation with the intention of creating massive amounts of biofuel. The Congo people are absolutely thrilled about this as it will create jobs for those who are currently some of the poorest in the world and the money will trickle down throughout the rest of the economy so the people can actually buy some food. I would argue that biofuels are actually going to end up reducing world hunger, not increase it. The areas of the world with the largest starvation also tend to be areas where biofuel crops grow best.

” The green claims for biofuel as a friendly and better fuel than gasoline are at best dubious, if not outright fraudulent. Depending on who runs the tests, ethanol has little if any effect on exhaust-pipe emissions in current car models. It has significant emission, however, of some toxins, including formaldehyde and acetaldehyde, a suspected neurotoxin that has been banned as carcinogenic in California.”

You use hyperbole to the extreme: “Compared with gasoline, ethanol tends to produce less benzene and butadiene, but more acetaldehyde and formaldehyde, when burned.” Basically ethanol produces slightly less of some negative compounds and slightly more of other negative compounds. This isn’t even “dubious” and certainly not “outright fraudulent.”

Anyway, you ignored most of the valid arguments against ethanol usage and argued mostly for the bad ones which have already been invalidated on numerous occasions. For example, I would argue that the implementation by the administration has been relatively poor. The subsidies are depleting an already overreaching budget. A carbon tax and possible other taxes on gasoline and large vehicles would be far more effective.

In conclusion I would suggest that perhaps Mr. Engdahl spend more time researching facts and less attempting (and failing) to prove his slogan: “Just because you’re paranoid doesn’t mean they aren’t out to get you.”

Engdahl, F William. “The great biofuel fraud” Asian Times Online, August 1 2007. <http://www.atimes.com/atimes/Global_Economy/IH01Dj02.html>

University of Wisconsin Madison Undergrad Researches Techniques to Grow Algae as a Potential Source of Biomass

Jennifer Jackowski, a senior majoring in botany at the University of Wisconsin Madison is studying algae growth in local lakes. “This summer, she placed four, 30-foot fiberglass screens in Lake Mendota, which she hopes will act as floating beds for algal growth. Her primary goal is to devise a means for cleaning the lakes. But she also plans to study the algae to see if it holds any commercial value.”

Seth Keel, a researcher and co-founder of the Madison-based consulting and distribution company Great Lakes Bio-Fuels, is also looking into the potential of algae. Keel hopes to develop a commercial process to make biofuels from algae that will be competitive with traditional fuels. With the recent global surge in biofuel interest has come a lot of money in the form of investment capital. This will help speed the development of economically competitive biofuels as there will be more people available to work on making breakthroughs and they will have better equipment with which to make the breakthroughs.

“Both Keel and Jackowski envision a process in which algae is harvested from the lake — in Keel’s case, by pumps, and in Jackowski’s, via screens. This kind of cleaning would have a double effect — the algae is removed from the lake and future algae blooms would be diminished because the nutrients from the algae would not be recycled in the water to be used by following blooms.” Whether this is good for the lakes or not has yet to be determined.

Although algae is orders of magnitude more productive in terms of mass per acre per year than traditional bioenergy crops, the costs of the processes of obtaining and processing the algae are also currently magnitudes higher. More research is definitely necessary but from what I can tell we will be seeing mass production of other more traditional forms of cellulosic ethanol (wood, switchgrass, etc) far sooner than from algae simply because the algae process is far more complex and will require more time to engineer. With the enormous potential of algae it certainly is not an option to be overlooked however.

Popper, Ben. “Long green seen in algae in city lakes” Wisconsin State journal, July 30 2007, <http://www.madison.com/wsj/home/local/index.php?ntid=203326&ntpid=1>

Chinese Company Investing 1 Billion in 3 Million Hectacre Oil Palm Plantation

Biopact is covering ZTE International, a Chinese company’s 1 billion dollar investment in a 3 Million hectacre oil palm plantation in the Congo.  At one time, the Congo was the second largest palm oil producer.  The country has been experiencing a brutal civil war for most of the last 2 decades and most of the infrastructure has been destroyed or not maintained.  “Congo is only slowly waking up from the nightmare it experienced over the past decades. Everything has to be rebuild, from the state apparatus and the economy to social and health services, from schools and hospitals to roads and railroads. In this immense country the size of Western Europe there are only 300 kilometres of paved roads…”

Initially, ZTE plans to simply extract the oil from the palms.  It will be interesting to see how long it takes for them to begin using the biomass to create other forms of energy (such as cellulosic ethanol).  The potential for biofuels in Congo is huge, at the moment only 4.7% of the arable land is being cultivated.

While at the moment, Congo is a net oil importer, this will likely not last long.  Even before ZTE’s plantation begins fuel production(the trees take 5 years to mature), biofuel production is quickly rising in the country.  5 years from now when ZTE’s trees are mature, the country will become a net exporter.

Massive palm oil production has historically had a few negative consequences.  Often rain forest is destroyed to make way for an oil palm monoculture which significantly reduces biodiversity in the region.  Indigenous cultures are also destroyed as they are forced off of their land to make way for heavy machinery and oil palm trees.

Despite this, people in Congo are thrilled about the idea of having foreigners investing in their country as it will create jobs and could potentially lift the country out of the extreme poverty in which it currently resides.  There are sustainable ways of palm oil farming, it will be up to the legislature in the Congo to make sure that the world’s second largest rain forest isn’t completely destroyed and the Congo people are not exploited.  The government will likely need assistance figuring out what policies will need to be enacted to protect the people and the rain forest and the EU is already considering providing this analysis and guidance.

International Fuel Ethanol Workshop Hosts Record Attendees

Ethanol Producer Magazine reports that FEW, the International Fuel Ethanol Workshop which opened a month ago today hosted a record number of participants this year.  “You know, the first Fuel Ethanol Workshop was held here in St. Louis in 1984. I think there were between 38 and 40 people at that first Fuel Ethanol Workshop, and no exhibitors. This year we have about 5,200 registered … and nearly 700 exhibitors.”  Since 1984, the industry has gone from producing roughly 500 million gallons of ethanol/year to roughly 7 billion gallons of ethanol/year.

In that time the industry has come a long way, but still has a vast potential for expansion.  Currently, nearly all ethanol is made from corn.  This will be changing in the next 15 years or so as cellulosic ethanol technology becomes mainstream.  “The push to bring cellulosic ethanol from pilot and demonstration to commercial-scale production has been on the front burner for some time now.  The joke within the industry is that cellulosic ethanol has been “five years away” from reality for the past 25 years. Whether the next five years of research and development will deliver commercial-scale cellulosic ethanol is yet to be determined.”  I would like to point out that there has been a lot of progress into cellulosic ethanol in the last year.  Mascoma’s wood plant in Michigan, the citrus peel plant in Florida, and Poet’s corn cob project in Iowa are all innovative and will lead to increasing process efficiency through their mass production.  Once the process is relatively efficient and proven, there will be more players who enter the market and competition will increase further driving innovation.

Bob Dinneen, president and CEO of RFA responded to ethanol critics who are of the belief that ethanol production negatively impacts food supplies (and prices) by saying: “The food versus fuel discussion that we’re hearing today, we need to address head-on,” Dinneen said. “We need to be the ones to inform people that when we process corn into ethanol, we’re not taking food out of the mouths of babies. We’re borrowing the starch and we’re leaving behind a very high-value, high-protein feed product that is going to those food markets.”  Regular readers of THIS site however already know that rising corn prices have almost no impact whatsoever on food prices.

“All of this growth … has been in spite of a lot of negative newspaper articles, a lot of negative press, naysayers, the professor [David] Pimentels of the world who offer nothing but hollow criticism based on poor data, based on a lack of research,” he said. “I want you to ignore the naysayers. I want you to laugh at the negative news articles that may appear in the paper. And I want you to totally ignore the paid-for professors who claim to know more about this industry than you do, because you know what? They are wrong. You are doing the right thing. The more noise that these people make, the more I’m convinced that you are doing the right thing.”

While it is true that ethanol (cellulosic especially) is a very good start to solving our energy needs, completely ignoring naysayers probably isn’t the best approach.  Criticism can be useful if it is backed up by fact.  To completely disregard all criticism would be foolish and detrimental to our society.  If someone argues corn ethanol has a negative energy ratio, they are completely wrong and their criticism is foolish as there have been numerous studies that point to the contrary.  Someone who ignores total energy usage statistics and believes that ethanol is the end all solution to our energy problems while ignoring enormous evidence to the contrary however is also foolish.

“Dinneen summed up the current state of affairs this way: “Today, ethanol is blended in 50 percent of the nation’s fuel. Every single gallon of gasoline sold in New York is blended with ethanol. Every single gallon of gasoline sold in California is blended with ethanol. Every single gallon of gasoline sold in Houston, Texas, where big oil company executives have to drive to work every day on your fuel, is testament to how far we’ve come. But we certainly have a long way to go.”

Researchers and producers optimistic about sweet sorghum as biofuel feedstock

Sorghum, a plant genetically similar to sugarcane is being considered as a future biofuel feedstock.  Many researchers, funded by both government and industry are breeding sorghum for traits desirable in bioenergy feedstock.  There are hundreds of sorghum varieties throughout the earth.  They are being bred to increase per acre yields, to increase drought resistance, and increase sugar content.  The sorghum genome is being mapped which will help scientists understand which genes do what, which will allow them to better control sorghum breeding.

Sweet Sorghum is being especially looked at for a number of reasons.  It requires roughly half the water per acre when compared to corn.  By it’s nature, it has a high simple sugar content (like sugarcane) which makes processing into ethanol easier.  Current models are expecting sorghum to be produced at roughly 20 tons per acre. This exceeds even miscanthus which comes up at roughly 15 tons per acre.  This would be economically competitive with gasoline.  Sorghum is also naturally drought resistant which will allow it to be planted in areas too dry for corn.

A lot of work right now is going into changing sorghum from a seed crop, which requires replanting every year to a perennial.  Perennials are easier to grow since the relatively costly process of planting every year can be neglected.  This happened with sugarcane in Brazil, so it is not unheard of.

A lot of the sorghum research currently is going on in Texas since the climate in Texas potentially could be ideal for mass sorghum production.   A lot more research is needed into this promising potential biofuel however as there is still a lot of uncertainty about the plant.