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Challenges for Biofuels: Not Just Technical Hurdles To Overcome

By Lynn Yarris, Lawrence Berkeley National Laboratory
February 10, 2011 | 16 Comments

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Berkeley, California, USA -- A combination of rising costs, shrinking supplies, and concerns about global climate change are spurring the development of alternatives to the burning of fossil fuels to meet our transportation energy needs. Scientific studies have shown the most promising of possible alternatives to be liquid fuels derived from cellulosic biomass. These advanced new biofuels have the potential to be clean-burning, carbon-neutral and renewable. Some could also be delivered through existing pipelines and used in today's engines, replacing gasoline on a gallon-for-gallon basis with no loss of performance.

That is the promise of advanced biofuels and the focus to date has been on the technological challenges of producing high quality biofuels in a way that is both sustainable and economically competitive with gasoline. In addition to the technological challenges, however, there are also important social, economic and environmental challenges that must be addressed.

“These challenges include constraints imposed by economics and markets, resource limitations, health risks, climate forcing, nutrient cycle disruption, water demand, and land use,” says Thomas McKone, an expert on health risk assessments who holds a joint appointment with the Lawrence Berkeley National Laboratory (Berkeley Lab) and the University of California (UC) at Berkeley. “Responding to these challenges effectively requires a life-cycle perspective.”

McKone is the lead author of a report titled “Grand Challenges for Life-Cycle Assessment of Biofuels,” which was funded by a grant from the Energy Biosciences Institute (EBI), a partnership between UC Berkeley, Berkeley Lab, the University of Illinois, and the BP energy corporation. This report summarizes seven grand challenges that “must be confronted” to enable life-cycle assessments that effectively evaluate the environmental footprint of biofuel alternatives.

Co-authoring this EBI report with McKone were William Nazaroff, Peter Berck, Maximilian Auffhammer, Tim Lipman, Margaret Torn, Eric Masanet, Agnes Lobscheid, Nicholas Santero, Umakant Mishra, Audrey Barrett, Matt Bomberg, Kevin Fingerman, Corinne Scown, Bret Strogen and Arpad Horvath. McKone and Horvath are the co-leaders of EBI’s Life-Cycle Assessment Program.

A life-cycle assessment (LCA) is typically used to evaluate the potential impact of a product or activity on human health and the environment over the entire cradle-to-grave life cycle of that product or activity. In applying the LCA approach to advanced biofuels, McKone, Horvath and their co-authors identified the following seven grand challenges.

Understanding farmers, feedstock options, and land use Biomass production for biofuels could displace existing products from land currently used for food, forage and fiber, which could increase the price of these goods in global markets. It could also induce deforestation that would exacerbate global climate change.

Predicting biofuel production technologies and practices – Many options exist for biofuel production processes and final products. Much of the variability among LCA results for biofuels arises from lack of knowledge about how these different possible production and operation processes will evolve.

Characterizing tailpipe emissions and their health consequences – Credible and reliable impact estimates for biofuel combustion are needed, but few studies of the health impacts from transportation fuel use have extended beyond air pollutants. Those that included an explicit metric for health damages emphasized mortality rather than morbidity and the overall disease burden.

Incorporating spatial heterogeneity in inventories and assessments – The health consequences of pollutant emissions vary depending upon where the pollutant is released, with factors such as proximity to large populations looming large. Geographical variability also influences other factors, including soil carbon impacts and water demand consequences.

Accounting for time in impact assessments – Air emission impacts from tailpipes and production facilities accrue within years and can be allocated to the year of emissions without discounting. GHG emission impacts are distributed over decades and even centuries using integrated assessment models, and are often discounted. Decisions about discounting can strongly influence the outcome of impact assessments, yet there is not a clear rational basis for making these decisions.

Assessing transitions as well as end states - In addressing transitions, emerging technologies could profoundly change the assumptions that underlie biofuel LCAs. For example, changes in protein production and consumption patterns or in urban land-use policies could open up substantial agricultural land for biofuel production, an action that would fundamentally change a biofuel LCA.

Confronting uncertainty and variability - Addressing uncertainty is among the greatest of LCA challenges, not only for biofuels, but for other LCA efforts as well. To confront uncertainty and variability, the “doable” and “knowable” must be separated from assumptions that are conditional components of the LCA.

In their report, the authors of the EBI study say that confronting these seven grand challenges for a biofuels LCA requires a good balance between the needs of technology momentum and adaptive decision making, something, they say, that has not always been well-articulated among practitioners of LCA.

“We must recognize that LCA is not a product but an ongoing process for organizing information and prioritizing information needs,” McKone says. “LCAs should be viewed as tools for building scenarios from which one can learn, rather than truth-generating-machines. We do not see the grand challenges outlined in this report as hurdles to be cleared, but rather as opportunities for the practitioner to focus attention on making LCA more useful to decision makers.”

The “Grand Challenges for Life-Cycle Assessment of Biofuels” can be viewed and downloaded from the publications section of the EBI Website.

Mr. Lynn Yarris is a senior science writer with the Lawrence Berkeley National Laboratory.

Bioenergy

16 Reader Comments

Comment
1 of 16

GideonRichards

February 11, 2011

This is something the international community are working on to develop standards (ISO) for the Sustainability of Bioenergy (In its broadest of senses).

While this looks interesting, it would appear that the social and Indirect Effects (not just ILUC) are not being looked at, which makes me wonder why?

The non technical issues that this article starts to look at appear to be still from a technical stance, i.e. the likes of Air Emissions. However, the softer understanding of the social and indirect effects are often more difficult to come to a common ground on. Acceptance at that level is probably going to be as key to the uptake of biofuels and bioenergy generally as the overcoming the technical hurdles, I would suggest.

Gideon Richards, Consulting With Purpose Ltd.
Chairing the Technical Committee for the UK mirroring the Sustainability of Bioenergy and sitting on the European (CEN) and ISO development committees.

Comment
2 of 16

JimW

February 11, 2011

How long are you going to talk and think about options?
Biofuels will work if using a waste product that is central to a processing facility, but the numbers are just not enough to take over for fossil. Shell walked away from algae last week. GreenNH3 is a working technology scalable enough to take over for oil, if we start today. They do need some financing but the fuel is working and ready. Scientific American says peak 2014. What fuel are you going to use??

Comment
3 of 16

christopher-lee-166032

February 11, 2011

The article seems to lack imagination and vision, perhaps because it is rather brief.

For example, there is only one passing reference to crops grown both for food and for fuel. Surely, we should be discussing "reverting" to growing long-stemmed grain crops. No doubt, enterprises that have been working for decades on the development of short stemmed varieties will be applying their subtle but considerable lobbying skills to limit discussion of the subject.

Nobody seems to mention highways, roadsides, parks and other open spaces (even private gardens) which are - in a sense - wasted if regarded from the engineering viewpoint taken by the article(cf. GideonRichard's post). It ought to be possible to come to a compromise between fuel value, attractiveness harvesting and maintenance costs, bearing in mind that these areas need looking after whether or not they are used for biofuel. Of course, in some places (France, perhaps ;-) one would not attempt to discuss the subject for fear of drowning in the cultural and administrative complexities.

Comment
4 of 16

les-blevins-174452

February 11, 2011

Roadside areas offer a substantial amount of free or low-cost feedstock material for conversion to electric power or biofuels. Baled weeds and grasses with scrap tires and other roadside trash is exactly the type of material our novel fuels conversion system is designed for. See our prototype at http://aaecorp.com/ceo.html or email for more information at info@aaecorp.com or call 785-842-1943.

Comment
5 of 16

william-bradley-49466

February 11, 2011

I have several reservations about biofuels. To the extent that biodiesel and ethanol are truly made from waste substances, they may be good. However, with looming world wide food shortages, I believe that it is unethical to divert food crops for energy use when other alternate energy sources such as wind and solar are available. Also, land that could grow food should not be used for energy crops.

Some people in this area have tried to sell wood burning power plants as carbon dioxide neutral. At least in the short run, this is definitely not true. Perhaps if you wait about 70 years while the tree is growing back, it will sequester enough CO2 to make the process neutral but we can not afford to wait.

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6 of 16

Erich

February 11, 2011

Carbon-Based Religion
My holy grail is the establishment of soil carbon as the universal measure of sustainability for all biofuel systems.

A perfect cradle to cradle recycling, biotic carbon should never be combusted and destroyed, be revered, as life is revered, be returned to the cradle of terrestrial life the Soil

The Ag Soil Carbon standard is in final review by the AMS branch at USDA. Both Congressional Ag Committees have asked for expansion of Soil Carbon Standard to ISO status.
Read over the work so far;
http://www.novecta.com/documents/Carbon-Standard.pdf

Recent NATURE STUDY;
Sustainable bio char to mitigate global climate change
http://www.nature.com/ncomms/journal/v1/n5/full/ncomms1053.html

Soil Carbon Dream

I have a dream that one day we live in a nation where progress will not be judged by the production yields of our fields, but by the color of their soils and by the Carbon content of their character.

I have a dream today.

I have a dream that one day, a suite of earth sensing satellites will level the playing field, giving every farmer a full account of carbon he sequesters. That Soil Carbon is given as the final arbiter, the common currency, accountant and Judge of Stuartship on our lands.

I have a dream today.

I have a dream that one day every valley shall be exalted, every hill and mountain shall be made forest, the rough soils will be made fertile, and the crooked Carbon Marketeers will be made straight, and the glory of Soil Sequestration shall be revealed, and all flesh shall see a Mutually assured Sustainability.

This is our hope.

My apologies to Dr. King, but I think he would understand my passion

Since we have filled the air, filling the seas to full, Soil is the Only Beneficial place left.
Carbon to the Soil, the only ubiquitous and economic place to put it.

2010 US Biochar Conference at ISU
http://www.biorenew.iastate.edu/events/biochar2010/conference-agenda/agenda-overview.html

Comment
7 of 16

jajagabor

February 11, 2011

I remember Jean Shepperd (in Car & Driver) writing (back in the 70's) that the oil crisis was the world's biggest hangover after it's biggest and longest-lasting party. (I love Car & Driver, but don't always agree with them -- but they have had some classic writers and comments!)

The main problem in transportation I see is that no matter what we use for fuel, if we don't start learning how to conserve, nothing is going to work very well in the end . . . or now.

Another interesting thing I notice is the way our political system is fundamentally stagnant, and has been ever since I can rememeber. If we'd legalized industrial hemp thirty years ago, for example, we could have gotten (and still get) a lot of our feedstock for combustion (and with very fast replenishment) for biomass electrical generation (and a lot of paper too!). But like so many helpful solutions, this one isn't even being discussed anymore, much less implemented.

I could bring up a lot more, but the incredible inertia of the entire mind-set of the population, despite the rapid growth of many renewables, is somewhat disheartening. I mean, even with the internet and the ability to do a lot of research in a short period of time, most people still seem completely ignorant of say, the huge state subsidies that have always existed for nuclear power (including, but not reserved to, the granting of enormous limited liability). One still hears the endless chorus of those criticizing solar, wind etc. for getting subdies! Amazing! Astounding! Unreal!

Comment
8 of 16

coenraad-pretorius-176946

February 11, 2011

We already have HUGE piles of renewables waiting for somebody to figure out how to turn it into liquid fuel (for a profit, of course), called LANDFILLS. The bulk of what goes into a landfill is PAPER (only 50% of wastepaper gets recycled). If there is a batter feedstock for biofuels than wastepaper, I'm having a hard time thinking of it.

Start with the landfills, and let's see what can be done. Eventually we may need more feedstock, but by then we'll at least have a good idea about how to use it efficiently...

Comment
9 of 16

jonathan-chance-166185

February 12, 2011

Article 27.

Treasurynet.US

27.1 - The production, distribution, and utilization of cellulosic ethanol fuel and organic vegetable oil, including hemp, shall be preserved in the public domain as open-source intellectual property expressly exempt from any monopolistic control or prohibitive taxation....

Treasurynet.US

Comment
10 of 16

fred-linn-151968

February 12, 2011

coenraad----comment 8

Methane. Natural decomposition already converts biowaste in landfills to methane. CH4, natural gas---and it can be mixed with fossil natural gas in any proportion, it is exactly the same stuff.

Methane can be used in any application we need---it can even produce electricity directly with catalytic fuel cells.

And capturing methane from landfills that would have escaped into the atmosphere anyway---means that we are taking a gas out of the atmosphere that has 17X the GHG effect of CO2. Mixing biomethane with fossil methane means that just a 6% mixture has 0 GHG effect on the atmosphere compared to doing nothing.

Utilizing biomethane is the fastest--surest, least expensive and lowest tech and most effective thing we can possibly do reduce the effects of GHG on the atmosphere.

We are often at odds---but this time I completely agree with you.

Comment
11 of 16

fred-linn-151968

February 12, 2011

jajagabor---" The main problem in transportation I see is that no matter what we use for fuel, if we don't start learning how to conserve, nothing is going to work very well in the end . . . or now. "------

The key to thermal efficiency and power with internal combustion engines is compression ratio. The higher the compression ratio, the higher the efficiency. The higher the octane rating of the fuel---the greater the resistance to preignition---so the higher the compression ratio achievable.

Biofuels are well suited to high compression ratios---ethanol has an octane rating of 115 and natural gas has an octane rating of 120.

Diesel engines are already high compression ratio engines---and can easily double the thermal efficiency compared to a low compression ratio gasoline engine.

We already have diesel engines that can run on ethanol, Scania has been doing it for years in Sweden and UK with a fleet of over 1,000 buses. We also have diesel engines that are multifuel---they can run on either liquid or gaseous fuel(methane)---we've been doing that for over 90 years.

The technology you want is on the shelf, and it has been for years.

Comment
12 of 16

david-doty-31004

February 12, 2011

Another worthless study.

Apparently no one noticed that the world food commodity price index has nearly doubled in less than a year.

Nice poetry, Erich.

Comment
13 of 16

Anumakonda

February 13, 2011

The main drawback for wider application of Biofuels is input. There was a big moment for biofuel from Jatropha in India but in reality not much has been achieved. Agave(Americana),Sisal Agave is a multiple use plant which has 10% fermentable sugars and rich in cellulose. The fibre is used in rope making and also for weaving clothes in Philippines under the trade name DIP-DRY. In Brazil a paper factory runs on sisal as input. A Steroid HECOGENIN is extracted from this plant leaves.
Here is an excellent analysis on Agave as a biofuel:

Agave shows potential as biofuel feedstock, Checkbiotech, By Anna Austin, February 11, 2010:

"Mounting interest in agave as a biofuel feedstock could jump-start the Mexican biofuels industry, according to agave expert Arturo Valez Jimenez.

Agave thrives in Mexico and is traditionally used to produce liquors such as tequila. It has a rosette of thick fleshy leaves, each of which usually end in a sharp point with a spiny margin. Commonly mistaken for cacti, the agave plant is actually closely related to the lily and amaryllis families. The plants use water and soil more efficiently than any other plant or tree in the world, Arturo said. "This is a scientific fact—they don't require watering or fertilizing and they can absorb carbon dioxide during the night," he said. The plants annually produce up to 500 metric tons of biomass per hectare, he added.

Agave fibers contain 65 percent to 78 percent cellulose, according to Jimenez. "With new technology, it is possible to breakdown over 90 percent of the cellulose and hemicellulose structures, which will increase ethanol and other liquid biofuels from lignocellulosic biomass drastically," he said. "Mascoma is assessing such technology."

In India the sisal agave is put for fencing to prevent cattle from grazing. This is a regenerative plant. It is hoped in India Biofuel from Sisal agave will be promoted.

Dr.A.Jagadeesh Nellore(AP),India

Comment
14 of 16

hurryup

February 20, 2011

The only problem in the US will be getting people comfortable with clean diesel technology and getting more of those vehicles here......

Comment
15 of 16

etcgreen

February 22, 2011

There are 14 comments here and I would like to address the issues for each, but fear I might be labeled a "Blog-Hog", so I will provide the high-lights.

The radical food price increase is the result of the price of petroleum for agriculture and food transportation.

Please take the time to learn the difference between 1st generation feedstock vs. 2nd generation feedstock. The large scale planting of 2nd generation feedstock (maybe 28M acres in the US) will directly motivate the return of 55M acres of prime US farmland to food crops.

Any biofuel process that requires distillation does not result in a sustainable energy return (ethanol and most all cellulose processes). Hemp yields less than 100 gallons/acre/year - better than soy, but dismally low compared to yellowhorn.

There are hundreds of companies all over the world planting millions of acres of yellowhorn and jatropha for biodiesel production. At 850 gallons/acre/year and costs in the $38 barrel equiv., yellowhorn is a great start to off-set our petroleum use. Verifiable yields from jatropha range wildly from 200-1,400 gallons/acre/year.

Micro algae bio-oil is already in production at large scale - just not for ground transportation fuels. A solution such as Joule Unlimited has great potential in the future and we need to establish the infrastructures for 2nd generation feedstock such as yellowhorn to prepare for a Joule type system or micro algae in the future.

We need to move to more efficient engines immediately and that is advanced diesel. US drivers can achieve the same number of miles with 1/3rd less fuel by simply eliminating all gasoline powered vehicles. If you have not test driven an advanced diesel vehicle - give it a try.

http://etcgreen.com Article: Are you driving your last gasoline powered car?

By the way, the author of this article may want to do more research on the issue - she does not seem to be aware of the major biofuel efforts in the US.

Comment
16 of 16

Anonymous

February 24, 2011

I am interested in the clause in the first paragraph, "Some could also be delivered through existing pipelines". The technical issues (e.g. stress corrosion cracking)and the cost of steel pipeline make it a non-viable option for providing efficient and cost-effective ethanol transport from the plant to the retailers. Clearly the existing modes (rail, truck, barge) cannot support the mandate for increased biofuel usage. And the carbon footprint is significant.

Is there interested in developing a new supply chain infrastructure to support an ethanol-based biofuel network? Mabye plastic is a cheap, sustainable, and technically acceptable solution?

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