backtop


Print 35 comment(s) - last by Paj.. on Sep 2 at 5:53 AM


Grad student Phong V.V. Le stands with Professor Praveen Kumar in front of a stand of grass. The pair found a potential downside of switchgrass as a biofuel stock -- decreased soil moisture and increased humidity.  (Source: L. Brian Stauffer/University of Illinois)

A new study created a strain of yeast more efficient at turning red algae to fuel via fermentation. The new strand requires only half the time of its predecessor to produce biofuel.  (Source: Antibiotics for)

Algae/seaweed-based biofuels may be the ideal solution for sea-bordering arid regions, such as the Middle East.  (Source: Google Images)
Water usage is a potential concern for using switchgrass as a cellulosic biofuel feedstock

You can ferment it in bacteria.  You can subject it to outlandish temperatures and pressures.  But however you produce biofuel, one thing is constant -- you need a supply of carbon, the "feedstock".

I. Switchgrass == Environmental Threat?

One leading candidate for widespread use as a biofuel feedstock is switchgrass.  Fast-growing and hardy, switchgrass quickly produces a great deal of biomass.  But a new study by the
University of Illinois reveals a potential downside -- switchgrass' growth comes at the cost of soil moisture.

Switchgrass is apparently so effective at sucking water out of the ground that it could cause adverse affects to other human crops, as well as local ecosystems.  
Praveen Kumar, the Lovell Professor of civil and environmental engineering at the University of Illinois states, "While we are looking for solutions for energy through bioenergy crops, dependence on water gets ignored, and water can be a significant limiting factor.  There are many countries around the world that are looking into biofuel energy, but if they are adopting these (large grasses) into their regular policy, then they need to take into account the considerations for the associated demand for water."

The study examined transpiration -- the loss of water through plant pores.  Ultimately
switchgrass and another fast growing grass, Miscanthus, transpire at a higher rate than corn (the most widely used ethanol biofuel crop) and thus pull water from the soil at a faster rate.  This dries the soil and increases humidity.

The researchers also used a predictive model to study what would happen if the predictions of global warming
 were realized.  What they found was that while higher carbon dioxide levels decreased the transpiration rate by allowing the plant to open its pores to the air less frequently, higher temperatures negated this affect by increasing the rate of water loss while the pores were open.  Overall, the predicted affect was even higher rates of water loss.

Regardless of whether the warming scenario occurs, however, the study raises concerns for the viability of switchgrass and Miscanthus as biofuel feedstocks, particularly in drought-prone regions.

The study was published
 [abstract] in the peer-reviewed journal PNAS (Proceedings of the National Academy of Sciences).

Of course, the pro-corn, anti-grass bent should be taken with a grain of salt.  The University of Illinois has a long-standing relationship
 with the corn ethanol community, which would be displaced in a move to switchgrass cellulosic ethanol.  While this particular study was funded by a National Science Foundation grant, given the overall financial situation, it's possible that researchers at the University of Illinois could feel incentivized to find downsides of switchgrass and the upsides of corn.

II. Algae Could be the Cream of the Crop

That said, the University of Illinois, in a separate study, is promoting a fascinating biofuel alternative
 to both corn ethanol and switchgrass -- seaweed.  Recent efforts by the U.S. Marine Corps have heated up interested in algae- and seaweed-based biofuels.

The new study looks at how to speed up the slow process of fermenting red seaweed biomass to produce biofuel.  Currently Saccharomyces cerevisiae -- commonly named yeast -- is the leading candidate for fermentation as it has genes which code for proteins capable of digesting both galactose and glucose -- the two primary sugars in red seaweed.  However, wild-variety yeast "eats" glucose before it will eat galactose, making the fermentation process slow, and thus, ultimately, more expensive.

By introducing a new sugar transporter and enzyme that breaks down cellobiose at the intracellular level via a bit of gene splicing, the team was able to create a strain of yeast that simultaneously digests galactose and glucose, cutting the production time of red seaweed-derived biofuel in half.

Yong-Su Jin, an assistant professor of microbial genomics, compared the development "to a person taking first a bite of a cheeseburger, then a bite of pickle. The process that uses the new strain puts the pickle in the cheeseburger sandwich so both foods are consumed at the same time."

Professor Jin says that the pre-treatment process to break down seaweed into cellobiose -- glucose pairs -- and galactose is considerably less toxic than many of the potential processes to break down cellulose from terrestrial crops.  Furthermore, he says that red seaweed has several other advantage as well, including its higher biomass-per-unit-area density, its higher rate of carbon fixation than terrestrial biofuels crops, and its ability to grow in the sea, thus escaping land-space constraints.

The researcher selected the red variety (Gelidium amansii) of seaweed as it’s a fast-growing variety found in abundance in one very space-constrained region -- Southeast Asia.

The study on the work was published [abstract] in the peer-reviewed journal Applied and Environmental Microbiology
.  The study follows work earlier this year published [abstract] in PNAS, which saw Professor Jin's team introduce pathways for simultaneous digesting of xylose -- another plant sugar -- and cellobiose into a yeast strain.

Together the studies paint an interesting picture.  Switchgrass is potentially undesirable in arid regions and in space-confined regions.  However, many of these same regions border the sea.

So for regions like the Southeastern United States, Southeast Asia, the Middle East, and Japan, growing biofuels in the sea might be the wisest approach of all.



Comments     Threshold


This article is over a month old, voting and posting comments is disabled

Filed under "Irony"
By mattclary on 8/30/2011 12:30:23 PM , Rating: 5
quote:
Algae/seaweed-based biofuels may be the ideal solution for sea-bordering arid regions, such as the Middle East.




RE: Filed under "Irony"
By Jeffk464 on 8/30/2011 2:25:38 PM , Rating: 2
yup, as Ironic as Iran saying they need nuclear, or as some say nucular, to supply their energy needs. :)


RE: Filed under "Irony"
By michael67 on 8/30/2011 4:32:24 PM , Rating: 2
Actually I think Iran is not a top pick, as the red sea dose not have a constant stream of new water and nourishment like countries that located at the Ocean water streams.
I think it would be a disaster for the flora there, and kill the flourishing diving industry.

I am a diver and dived all over the world, country's like Ireland, Norway the US, and all other countries that are located at the warm streams are prime candidates for these project, at least if seaweed is a good candidate, as it literally grows any ware it can get a foothold.

So cheap floating frames would be perfect for growth and easy harvesting.

Still next to benefits for fish life as a habitat, I wonder if taking all these nourishment out of the water, is bad for sea live in general, but then on the other hand, the sea and Oceans are freaking big, and this will have little if no impact at all and would even create new habitats for sea live.

And everything is still better, then use crops for fuel, what imho should be outlawed!!!


RE: Filed under "Irony"
By Smartless on 8/30/2011 2:31:32 PM , Rating: 2
What's also ironic is that red algae looks alot like the edible type. So we're trading corn for seaweed. Albeit this type looks like the delicacy type we call Ogo in Hawaii.

In any case, I wonder if its possible to use secondary treated sewage water to supply the switchgrass. Health regulations prevent us from using reclaimed water for food even through drip irrigation but for this, I wonder if it would affect the production of ethanol. Not that I like ethanol as a fuel source but just wondering.


RE: Filed under "Irony"
By Raiders12 on 8/31/2011 7:24:06 AM , Rating: 2
LOLs...

America has like the most freshwater resources of the country, so hopefully the foreign countries have to count on us for fuel for a change.


RE: Filed under "Irony"
By Paj on 9/2/2011 4:17:47 AM , Rating: 2
Err... what good would freshwater do with seaweed?

And besides, Russia has more than America.


"I mean, if you wanna break down someone's door, why don't you start with AT&T, for God sakes? They make your amazing phone unusable as a phone!" -- Jon Stewart on Apple and the iPhone














botimage
Copyright 2014 DailyTech LLC. - RSS Feed | Advertise | About Us | Ethics | FAQ | Terms, Conditions & Privacy Information | Kristopher Kubicki