Exploring Microalgae as Solutions to Global Fuel Issues

In summary, Algae can be used to produce biodiesel, ethanol, and hydrogen, as options to the use of petroleum based fuels.
  • #246
hmmm... How much of Death Valley lies below sea level? And how much would a canal cost to the Pacific?
Hey! That's almost the same route as the Vegas to L.A. bullet train.

Lets see...
Pump Pacific water and all the L.A. poo into one end of the lake feeding the algae, and at the same time pushing it to the other end of the lake where it's harvested and the slightly saltier water is pumped back to the Pacific.
7800km2 = ~ 2,000,000 acres (wiki...)
yielding 2E10 gallons per year.(10k/acre yr)
@$2/gal diesel that comes to $40 billion dollars in algae oil per yr.

But what is the water to oil ratio?
If it's 10:1, we'll need to be pumping 500,000 gpm 24/7.

Well, I imagine if we're generating 50,000 gallons of fuel oil a minute, we could afford to run a couple of big pumps, not to mention pay for them in about about 10 minutes. :smile:
 
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  • #247
Typically, one harvests when the algae-water is about 1% algae by weight [at that point it looks like pea soup!]. If we assume a 50% oil yield by weight, we need about 200 lbs of water for every lb of oil. However, the water consumed is a different matter.
 
  • #248
Astronuc said:
...
Perhaps the goal is to identify the photochemical (basic chlorophyll-based photosynthesis?) process and scale it up to an industrial process. That could make carbon (CO2) capture more feasible/practical in a more or less closed cycle.
That's not the Exxon/SGI goal, but it is an interesting question: Why can't we simply create a large scale chlorophyll based chemical reactor, a big macro vat of green goop sitting in the sun? With out lifting a finger to jog my biology course memories, I believe the answer is something like this: the chlorophyll based photosynthesis process doesn't work at a macro scale because it requires small concentrated 'islands' with lots of surface area per island to allow controlled diffusion of only particular molecules, also know as a 'cell'. Once we've identified that we need cells, there's likely no beating a biological factory using reproduction via DNA for creating cells in large numbers.
 
  • #249
Ivan Seeking said:
Typically, one harvests when the algae-water is about 1% algae by weight [at that point it looks like pea soup!]. If we assume a 50% oil yield by weight, we need about 200 lbs of water for every lb of oil. However, the water consumed is a different matter.
Perhaps that is one of benefits of Venter's claim in this announcement that he has created a strain that directly ejects the lipids into the solution instead of self containing the lipds inside the cell. Once in the solution the lipids should be separable from the water without destroying the crop, that is, the water and algae stays in place while the energy containing lipids are siphoned off.
 
  • #250
OmCheeto said:
hmmm... How much of Death Valley lies below sea level? And how much would a canal cost to the Pacific?
Hey! That's almost the same route as the Vegas to L.A. bullet train.

Lets see...
Pump Pacific water and all the L.A. poo into one end of the lake feeding the algae, and at the same time pushing it to the other end of the lake where it's harvested and the slightly saltier water is pumped back to the Pacific.
7800km2 = ~ 2,000,000 acres (wiki...)
yielding 2E10 gallons per year.(10k/acre yr)
...:
To replace the total world oil production of ~85 mbbl/day w/ a 2000gal/acre-yr process hoped for by Exxon, one needs about one million square miles of algae farm, or collectively 1000 miles on a side, and a very large source of concentrated CO2. That decreases by 10-20% if most of transportation is moved to electric power, and the algae oil is used to make electricity. Difficult, but at least there would never be a 'peak algae' problem.
 
  • #251
mheslep said:
To replace the total world oil production of ~85 mbbl/day w/ a 2000gal/acre-yr process hoped for by Exxon, one needs about one million square miles of algae farm, or collectively 1000 miles on a side, and a very large source of concentrated CO2. That decreases by 10-20% if most of transportation is moved to electric power, and the algae oil is used to make electricity. Difficult, but at least there would never be a 'peak algae' problem.

In closed systems, in principle one doesn't need any CO2 except for the first batch.

2000 gal/acre-yr is a pretty conservative number.
 
  • #252
mheslep said:
To replace the total world oil production of ~85 mbbl/day w/ a 2000gal/acre-yr process hoped for by Exxon, one needs about one million square miles of algae farm, or collectively 1000 miles on a side, and a very large source of concentrated CO2. That decreases by 10-20% if most of transportation is moved to electric power, and the algae oil is used to make electricity. Difficult, but at least there would never be a 'peak algae' problem.

My. That's a big pond.
Divided by the world population, that means everyone needs a 64' x 64' pond.
Still a big pond by my standards.

mheslep said:
Perhaps that is one of benefits of Venter's claim in this announcement that he has created a strain that directly ejects the lipids into the solution instead of self containing the lipds inside the cell. Once in the solution the lipids should be separable from the water without destroying the crop, that is, the water and algae stays in place while the energy containing lipids are siphoned off.

Algae that poops oil? Now why didn't I think of that?
That's as good as my bacteria that eats algae and then farts methane idea, that was thought of 6342 times in the last 6 months by various people. :smile:
 
  • #253
OmCheeto said:
Algae that poops oil? Now why didn't I think of that?
That's as good as my bacteria that eats algae and then farts methane idea, that was thought of 6342 times in the last 6 months by various people. :smile:

Having the idea is the easy part. :wink:
 
  • #254
Ivan Seeking said:
In closed systems, in principle one doesn't need any CO2 except for the first batch.
Eh? Did you mean H2O? If carbon is continuously removed in the form hydrocarbon oils from the closed system, then it must be continuously inserted mole for mole via CO2 or other forms of hydrocarbon.

2000 gal/acre-yr is a pretty conservative number.
Yes, I know you have cited other sources in this thread w/ larger numbers. 2k is Exxon's number.
 
  • #255
mheslep said:
Eh? Did you mean H2O? If carbon is continuously removed in the form hydrocarbon oils from the closed system, then it must be continuously inserted mole for mole via CO2 or other forms of hydrocarbon.

When the oil or biomass is burned, the CO2 is returned to the system in the form of exhaust gasses to be absorbed by the next batch of algae.

In principle we have a closed system with only sunlight going in, and electrical power going out.

Yes, I know you have cited other sources in this thread w/ larger numbers. 2k is Exxon's number.

I know. It is still a conservative number. The aquatic species program obtained yields of 5000 gallons per acre-yr in open ponds, which is probably a practical upper limit. Note that "other sources" are citing ten and even twenty-thousand gallons, and more in some cases, per acre-year. However, simple energy calculations show this [the high numbers] to be impossible. The only exceptions to this may be the approaches that involve the introduction of other energy sources, like sugar, into the system.
 
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  • #256
Ivan Seeking said:
When the oil or biomass is burned, the CO2 is returned to the system in the form of exhaust gasses to be absorbed by the next batch of algae.
Oh that system, the big system, sure.
 
  • #257
mheslep said:
Oh that system, the big system, sure.

Hey, we only think big around here! :biggrin:

To me the idea of using algae for the remediation of coal gasses is a bit ironic considering that we might be able to replace the coal with algae and close the loop.
 
  • #258
mheslep said:
Perhaps that is one of benefits of Venter's claim in this announcement that he has created a strain that directly ejects the lipids into the solution instead of self containing the lipds inside the cell. Once in the solution the lipids should be separable from the water without destroying the crop, that is, the water and algae stays in place while the energy containing lipids are siphoned off.

If true, that is huge because it would not only eliminate the step of separating the algae from the water, but also removing the oil from the algae. Separating oil from water is relatively easy. Also, depending on the doubling time of the algae, it could drastically improve the rate of production per acre. Some of the best oil producers are also slow growing. For example, the "Algae 101" strain, Botryococcus Braunii, which has reportedly been measured at 80% oil by weight in one case, has a doubling rate of something like once every two or three days. Other strains with low oil yields - say 15% oil by weight - can have a doubling rate of one every few hours.

Interestingly, one scientist claims that no matter what strain is considered, the rate of oil production [for good oil producers] is nearly a constant, which may make sense from an energy standpoint. But there is no doubt that growing the stuff from a pure culture is a limiting factor for continuous production.
 
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  • #259
Here's only blurb available on the SGI site regarding the synthetic strain:

Current methods to produce fuel from algae include processes that resemble farming. Algal cells are grown, harvested, and then bioprocessed to recover the lipids from within the cells. In contrast, in one of our solutions, SGI has engineered algal cells to secrete oil in a continuous manner through their cell walls, thus facilitating the production of algal fuels and chemicals in large-scale industrial operations. Our first product in this area is a biocrude to be used as a feedstock in refineries.
http://www.syntheticgenomics.com/what/renewablefuels.html [Broken]
 
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  • #260
Here's a particularly articulate http://www.xconomy.com/seattle/2008/10/23/vinod-khosla-speaks-at-seattles-algae-biomass-summit/2/" [Broken] of the state of algae technology and barriers to exploitation from the venture capitalist guru Khosla:

General business model goals for any tech business:
—Relevant cost. Energy technologies are only scalable if they’re competitive without subsidies in places like China and India (what he calls the “Chindia price”)

—A scaling model. The technology’s growth has to be exponential and highly distributed (”we saw this in the Internet,” he says).

—Low adoption risk. “The only thing that solves the carbon-reduction problem in transportation is a liquid fuel-based solution,” he says. Something like hydrogen fuel requires too much development in infrastructure to make it go mainstream.

And algae specifically:
So why hasn’t he invested in algae yet? Khosla first gave his broader “venture rules of investing.” First, a company should “attack manageable but material problems.” Second, its technology should achieve “unsubsidized competitiveness”—which in the case of algae, would be prices competitive with oil prices of around $50 per barrel. Third, the tech has to scale to large numbers of users, and have declining costs with scale. And fourth, it should have “manageable startup costs and short innovation cycles. He pointed out that algae satisfies all of the above (”I can do a new strain of algae in 6 months”), except for the cost competitiveness.

Looking ahead, Khosla said, “To predict the future, invent it. It’s not what it is, it’s what it can be.” He proceeded to give a detailed reality check for algae, in that it is competing with things like biomass methods for producing ethanol and oil. Calculating a theoretical maximum output of 2000 to 6000 gallons of oil per acre per year for algae (based on solar energy availability and current conversion systems), he said, “Algae clearly has the potential to have very high miles driven per acre, but today it’s pretty low.”

Adding up the production costs for algae-based fuels—carbon dioxide, harvesting, containment, and energy, as well as systems to move, mix, and add light to the plants— he concluded, “I think algae can get above biomass in total gallons per acre, but the reason we haven’t invested is we haven’t believed the plans we’ve seen so far meet the [cost] criteria.”

To break through, Khosla advised pursuing “black swans,” technical approaches from outside the realm of traditional experience, with game-changing impact. “The strategy is more at-bats, more shots on goal,” he said. “Most of your approaches will fail, but a few will succeed. You will build from each others’ experience, and get better and better.” The examples of possible black swans he gave were companies like Algenol Biofuels (ethanol-producing algae) and Sapphire (oil-producing algae), and the idea of ocean farming for algae.

As for advice to startups in the space, Khosla said, “Don’t try to get to market quickly with a small improvement. Even a good process isn’t good enough, you have to be truly great to compete. That’s the right vein to build an algae company. I’d say we need to work on more fundamental breakthroughs in algae…Take your time, don’t be in a hurry where you’ll reduce your technical risk, but increase your market risk. Take two more years and do the research. The day you have good fuel out of algae that’s cost-effective, it’ll get into the market.”
 
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  • #261
Obviously Exxon sees it a little differently.
 
  • #262
While there were and are a good number of practical engineering challenges for algae-fuel production, as far as I know, there is one and only one reason why we didn't do this long ago: The price of crude was too low.

When the Aqautic Species Program concluded, http://www.nrel.gov/docs/legosti/fy98/24190.pdf it was estimated that biodiesel from algae might be competitive when diesel was over $2 per gallon. At that time, diesel was about $1 per gallon. Now that the price of crude has a floor near or above the critical threshold for biodiesel to be competitive with petrodiesel, we are seeing a growing interest in viable alternatives to crude oil.

I have yet to see any alternative that offers the range of benefits found in using algae derived biodiesel as our primary energy source. After studying this option for about six months, I began to see that it is truly the elegant solution to our energy problems:

1). Does not need to compete with food crops
2). Does not need to use fresh water
3). Highest energy conversion rate of any plant [with qualifer stated earlier]
4). Greatest yield per acre-yr of any biofuel option
5). About 1.6 times the energy density of ethanol, and as good as gasoline
6). High lubricity of biodiesel allows for more efficient operation of engine [as seen in the Boeing test flight]
7). Diesel engines are about 1.4 times more efficient than internal combustion enginers
8). CO2 neutral
9). Clean diesel cars are already sold in Europe. The Honda diesel gets better mileage than the Honda hybrid. The proof in in the pudding!
10). Compatible with existing energy infrastructure.
11). The conversion to a biofuel economy can be implemented relatively quickly
12). Algae can be used to produce diesel, ethanol, and Hydrogen. So the development of algae technologies could be a stepping stone to a Hydrogen Economy.
13). Having a value of ~ $600 Billion annually - money sent to foreign oil suppliers - a domestic algae program would eliminate at least 60% of the trade deficit [depending on the current price of crude].
14). Can be used to remediate CO2 as well as toxic and other waste products from agriculture, industry, and municipalities.
15). While not necessary, it could be scaled-up to provide 100% of the required energy for the world.
 
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  • #263
Ivan Seeking said:
Obviously Exxon sees it a little differently.
Now. The Khosla speech was last October. Khosla said earlier in that same talk that he'd looked at 100 algae plans, so he clearly recognized the potential, but had yet to find anybody to carry the ball across the finish line, a line he defines clearly. No one else was giving money to Algae either last year. But this summer, we suddenly have the algae bloom of Dow Chemical, Solazyme, etc, and now Exxon/SGI.
 
  • #264
The problem that I saw that led to my own efforts was that far too many people were taking high-tech, high-cost-per-unit-area approaches in the form of exotic bioreactors. In some cases it was nothing more than a scam. In others, the people developing the systems didn't have even a fundamental understanding of the limits on production as determined by the solar energy input. In others, it was impossible to know because the information was proprietary. The bottom line is that the cost per unit area for the bioreactor must be very low. In my own plan, I was driven to a price of less than $1000 per acre with a three-year life for the hardware, in order to be competitive at around $3 per gallon [retail]. But this was for a fresh-water, land-based system, and assumed only traditional methods of production and the known strains of algae at that time. Needless to say, this required some very innovative approaches to bioreactor designs.

I think there is little doubt that closed, batch systems, are the way to go. At the least, we know that contamination problems in open systems are generally prohibitive to that approach. The only exception may be when indiginous and dominant strains are acceptable oil producers. But even then, there is no way to be certain that an existing strain, say in a lake, won't be replaced by another or simply die off. Also, strains can mutate quickly. Apparently there are effectively algae wars in the wild, in which each strain mutates until one has an advantage and displaces the other.

Probably one of the best ideas that we came across was that of using batch bags, if you will, that are suspended in water; say for example, in the ocean. This all but eliminates the problems of temperature regulation and contamination.
 
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  • #265
Ivan Seeking said:
...The bottom line is that the cost per unit area for the bioreactor must be very low. In my own plan, I was driven to a price of less than $1000 per acre with a three-year life for the hardware, in order to be competitive at around $3 per gallon [retail]. But this was for a fresh-water, land-based system, and assumed only traditional methods of production and the known strains of algae at that time. Needless to say, this required some very innovative approaches to bioreactor designs. ...
Yes, needless to say. I can't imagine a material or method of any kind that could enclose an acre for $1000. Perhaps there's something that amortizes out to $1000 per year over its lifetime.
 
  • #266
It is possible, but just barely. It took months to come up with something that might be mangeable. Part of the solution was to recognize the value of innovative land preparation. Would it have worked? It worked well at small scale, but things fell apart [financing] before we got any farther. My best hope for a major investor just went bankrupt due to the economy - he was heavily dependent on the auto industry.

Some designs out there can't even hope to be competitive until the price of fuel reaches $15 to $25 per gallon, retail.

However, if the processing costs can be reduced as in the example you gave [no need for dewatering or oil extraction], the cost per unit area can be increased signficantly. This because there are both high startup costs as well as high operating costs for the processing equipment.

One real advantage to using ocean-based systems, beyond the issue of water, is that the cost of land evaporates!
 
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  • #267
Why not just harvest kelp and other natural occurring algaes in open ocean or tideland areas and process in land based plants. Use solar energy to dry the kelp then process to extract the oils and other combustible components. I grew up in Southern California and saw kelp harvesting all the time. I think they were after Iodine and soda ash, but I'm sure there are a good source of energy products even methane. This would solve the land and water problem.
 
  • #268
PRDan4th said:
... but I'm sure there are a good source of energy products even methane. This would solve the land and water problem.
Why are you sure? Do you have a rough estimate as to how much a mass produced barrel of kelp oil or ethanol would cost to make?
 
  • #269
To the best of my knowledge, as for kelp, there is absolutely no evidence that would work. Also, as stated earlier, most wild algae strains tend to be poor producers of oil. This in turn means that the processing costs [dollars and energy] would be exceedingly high for each gallon of oil. While it may be possible to use wild strains of algae as biomass for the generation of electrical power [burned directly], this has yet to be demonstrated. Only in very rare cases would an indiginous and dominant wild strain be appropriate for oil production.
 
  • #270
About the Exxon numbers: I just noticed in another news release that they claim corn ethanol produces 250 gallons per acre-year. This is almost certainly a net yield - includes the energy required for processing - not the gross yield, which is normally cited as being 400 gallons per acre-year. If we assume the same is true for their number for algae - 2000 gallons per acre-year as a net yield - then that is about what I would expect as well. While I think there is reasonable hope for higher numbers over time, for now, 2000 GPAY net is probably reasonable.

All in all, an order of magnitude better than corn is a good start.
 
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  • #271
Thank you for keeping on these developments Ivan!
 
  • #272
According to the calculations by Dr. David JC MacKay in his book "Sustainable Energy – without the hot air", it looks like CO2 enriched algae is about 20 times better than corn based ethanol per square meter. The numbers were:

Bioethanol from corn: 0.2W/m2
Bioethanol from sugar cane: 1.2W/m2
CO2 Enriched Algae Biodiesal: 4W/m2

The calculations are on pages 284-285

You can download the whole book here:
http://www.withouthotair.com/download.html" [Broken]
Or go straight to the html page here:
http://www.inference.phy.cam.ac.uk/withouthotair/cD/page_284.shtml" [Broken]

The printed version actually says 0.02 for corn but there is a errata entry in the html version that says:

Page 284 Bioethanol section: "0.02 W/m**2" should be "0.2 W/m**2".

To make this section more informative I would rewrite
it thus:

1 acre produces 122 bushels of corn per year, which makes
122 x 2.6 US gallons of ethanol, which at 84000 BTU per gallon would
mean a power per unit area of {0.2 W/m^2}; however, the energy
inputs required to process the corn into ethanol amount to
83,000 BTU per gallon; so 99% of the energy produced is used up by
the processing, and the net power per unit area is about
{0.002 W/m^2}. The only way to get significant net power from the
corn-to-ethanol process is to ensure that all co-products are
exploited; including the energy in the co-products, the net power per
unit area is about 0.05 W/m^2.
 
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  • #273
joelupchurch said:
1 acre produces 122 bushels of corn per year, which makes
122 x 2.6 US gallons of ethanol, which at 84000 BTU per gallon would
mean a power per unit area of {0.2 W/m^2}; however, the energy
inputs required to process the corn into ethanol amount to
83,000 BTU per gallon; so 99% of the energy produced is used up by
the processing, and the net power per unit area is about
{0.002 W/m^2}. The only way to get significant net power from the
corn-to-ethanol process is to ensure that all co-products are
exploited; including the energy in the co-products, the net power per
unit area is about 0.05 W/m^2.

The net-net yield of the corn-ethanol process is hotly debated. Many people argue that the efficiency of the complete process is zero or worse - meaning [as you know] that we derive no benefit whatsoever, or we are even losing energy! Most standard sources seem to place the processing efficiency at about 30%. But one has to be careful about which number is being cited. I tend to refer to the "net yield" as the yield after including energy for processing. Then there is what I tend to refer to as the net-net yield, which includes the fuel for tractors and land management, hidden energy costs in the fertilizers, soil supplements, pesticides, antifungals, or whatever else might be used, the energy for pumping water, etc.
 
  • #274
When I applied MacKay's numbers of 60 grams of CO2 per square meter and multiplied by the 10,000 tons of CO2 per day produced by a 500MW coal plant and came up with 17SqKm of Algae. That comes out to a Algae field 4km on the side, which doesn't sound too bad, if you assume a sunny climate with cheap real estate.

Of course, sunny and cheap usually means a desert, so the water consumption situation needs to be analyzed.

Anybody want to calculate how much biodiesel 17 SqKm of algae would produce?

I find this interesting, since if the law starts requiring CCS for coal and natural gas plants, then the biodiesel would offset part of the capture cost and avoid the sequestration part entirely. There was a recent Harvard study, "Realistic Costs of Carbon Capture", that estimated $35 to $70 per ton of CO2 capture.

http://belfercenter.ksg.harvard.edu/publication/19185/realistic_costs_of_carbon_capture.html


Since the Algae only need 10% CO2, it isn't clear what you need to do to the output of the coal plant before you feed it to the algae if you have stack scrubbers. I should point out that the biodiesel produced isn't technically renewable, since it is produced using the carbon from the coal and not from the atmosphere.

I don't think CCS is practical, or that the continued use of coal is desirable, but I always like to check the math.
 
  • #275
Ivan Seeking said:
The net-net yield of the corn-ethanol process is hotly debated. Many people argue that the efficiency of the complete process is zero or worse - meaning [as you know] that we derive no benefit whatsoever, or we are even losing energy! Most standard sources seem to place the processing efficiency at about 30%. But one has to be careful about which number is being cited. I tend to refer to the "net yield" as the yield after including energy for processing. Then there is what I tend to refer to as the net-net yield, which includes the fuel for tractors and land management, hidden energy costs in the fertilizers, soil supplements, pesticides, antifungals, or whatever else might be used, the energy for pumping water, etc.

It seems to me MacKay's numbers are pretty close to 30%. He assume a gross of .2 w/m2 and a net of .05w/m2 which is a 25% net yield.

I would like to point out that from a climate perspective corn based ethanol makes little sense, even if the economics are better than break even. It can only offset the CO2 going into the corn, not the CO2 produced by the infrastructure to raise the corn. It seems to me that we would come out ahead on CO2 if we switched more of our vehicle fleet to compressed natural gas, since it produces much less CO2 per KWH.
 
  • #276
joelupchurch said:
When I applied MacKay's numbers of 60 grams of CO2 per square meter and multiplied by the 10,000 tons of CO2 per day produced by a 500MW coal plant and came up with 17SqKm of Algae. That comes out to a Algae field 4km on the side, which doesn't sound too bad, if you assume a sunny climate with cheap real estate.

Of course, sunny and cheap usually means a desert, so the water consumption situation needs to be analyzed.

Anybody want to calculate how much biodiesel 17 SqKm of algae would produce?
See up thread per Ivan: conservatively 2000 GPAY . 17 sq km = 4200 acres, or 8.5 million gallons per year.

I find this interesting, since if the law starts requiring CCS for coal and natural gas plants, then the biodiesel would offset part of the capture cost and avoid the sequestration part entirely.
As you noted, many of those coal plants are located where there isn't good sun.
 
  • #277
Maybe you could use some concentrators to get more sunlight for the algae.

Down here in Florida we have plenty of sun. Will algae work in saltwater? How about partially processed sewage?

Here is a new announcement from a company called Origin Oil about a method to "milk" the oil out of the algae without harvesting it.

http://www.originoil.com/company-news/originoil-announces-breakthrough-process-for-live-algae-oil-extraction.html" [Broken]
 
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  • #278
joelupchurch said:
Maybe you could use some concentrators to get more sunlight for the algae.

My impression is that this can be done in areas that are low on light. But more significant is the length of the day, and temperature. Keeping the algae cool in full light is one of the challenges for bioreactor designs. In the Aquatic Species Program, the winter temperatures are what killed the blooms [one example of why open systems can't work, imo]. There was plenty of light, but it was simply too cold.

As for the length of day, obviously the energy input to the system is reduced by having shorter days. IIRC from reading the literature current a couple of years ago, algae can be productive for up to about sixteen hours a day if light is available. Of course this led many of the fringe developers to provide artificial lighting, which is obviously a losing proposition!

Down here in Florida we have plenty of sun. Will algae work in saltwater?

Yes. There are many varieties of salt-water algae, and there are some known to be good producers of oil.

How about partially processed sewage?

Yes. Algae has the potential to treat many types of waste including industrial, municipal, and agricultural waste products. In the case of agriculture, the controlled growth of algae could be used to remediate runoff that creates dead zones in the ocean. The runoff is typically high in nitrogen, which algae love. In fact it is the uncontrolled growth of algae that depletes the oxygen needed for aquatic life. We could control this, solve the problem, and produce fuel as a consequence.
 
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  • #279
Looks like the algae phase may be entirely unnecessary.
http://www.cbsnews.com/stories/2009/07/27/tech/cnettechnews/main5190810.shtml
The Cambridge, Mass.-based company on Monday is disclosing its technology and business plans for making ethanol and other liquid fuels from genetically-manipulated microorganisms that have been fed only sunlight and carbon dioxide.
 
  • #280
Skyhunter said:
Looks like the algae phase may be entirely unnecessary.
http://www.cbsnews.com/stories/2009/07/27/tech/cnettechnews/main5190810.shtml

Sounds great! We will have to see if the reality meets the hype. [a news release is a far cry from years of real testing, as we have with algae]

One issue that bothers me is that they make ethanol. When one considers the offset in energy and efficiency as compared to diesel, 25,000 gallons of ethanol is probably worth about 10,000 gallons of biodiesel. This means added distribution costs. There is also the problem of being incompatible with heavy trucks and aircraft. Recall that an algae-jatropha oil mix was recently tested in a 737. It passed with flying colors.
 
<h2>1. What are microalgae and how can they be used as a solution to global fuel issues?</h2><p>Microalgae are microscopic, single-celled organisms that are found in various aquatic environments. They are photosynthetic, meaning they can convert sunlight into energy. This energy can be harnessed and converted into biofuels, such as biodiesel and bioethanol, which can be used as an alternative to traditional fossil fuels.</p><h2>2. How do microalgae compare to other biofuel sources?</h2><p>Microalgae have several advantages over other biofuel sources. They have a much higher lipid (oil) content, making them more efficient for biofuel production. They also have a faster growth rate and can be grown in various environments, including non-arable land and wastewater, reducing competition with food production.</p><h2>3. What is the process of converting microalgae into biofuels?</h2><p>The process of converting microalgae into biofuels involves several steps. First, the microalgae are grown in large-scale cultivation systems, such as open ponds or closed photobioreactors. The algae are then harvested and undergo a process called "dewatering" to remove excess water. The remaining biomass is then processed to extract the lipids, which are then converted into biofuels through transesterification or fermentation.</p><h2>4. Are there any challenges or limitations to using microalgae as a fuel source?</h2><p>While microalgae show great potential as a solution to global fuel issues, there are still some challenges and limitations to consider. One major challenge is the high production cost, as the cultivation and processing of microalgae can be expensive. Additionally, scaling up production to meet the demand for biofuels may also be a challenge. There are also concerns about the sustainability and environmental impacts of large-scale microalgae cultivation.</p><h2>5. What are some other potential applications of microalgae besides biofuels?</h2><p>In addition to biofuels, microalgae have many other potential applications. They can be used as a source of high-quality protein for animal feed and as a natural source of pigments for food coloring. Microalgae can also be used for wastewater treatment and as a source of pharmaceuticals, such as omega-3 fatty acids and antioxidants.</p>

1. What are microalgae and how can they be used as a solution to global fuel issues?

Microalgae are microscopic, single-celled organisms that are found in various aquatic environments. They are photosynthetic, meaning they can convert sunlight into energy. This energy can be harnessed and converted into biofuels, such as biodiesel and bioethanol, which can be used as an alternative to traditional fossil fuels.

2. How do microalgae compare to other biofuel sources?

Microalgae have several advantages over other biofuel sources. They have a much higher lipid (oil) content, making them more efficient for biofuel production. They also have a faster growth rate and can be grown in various environments, including non-arable land and wastewater, reducing competition with food production.

3. What is the process of converting microalgae into biofuels?

The process of converting microalgae into biofuels involves several steps. First, the microalgae are grown in large-scale cultivation systems, such as open ponds or closed photobioreactors. The algae are then harvested and undergo a process called "dewatering" to remove excess water. The remaining biomass is then processed to extract the lipids, which are then converted into biofuels through transesterification or fermentation.

4. Are there any challenges or limitations to using microalgae as a fuel source?

While microalgae show great potential as a solution to global fuel issues, there are still some challenges and limitations to consider. One major challenge is the high production cost, as the cultivation and processing of microalgae can be expensive. Additionally, scaling up production to meet the demand for biofuels may also be a challenge. There are also concerns about the sustainability and environmental impacts of large-scale microalgae cultivation.

5. What are some other potential applications of microalgae besides biofuels?

In addition to biofuels, microalgae have many other potential applications. They can be used as a source of high-quality protein for animal feed and as a natural source of pigments for food coloring. Microalgae can also be used for wastewater treatment and as a source of pharmaceuticals, such as omega-3 fatty acids and antioxidants.

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