Thanks for reporting on this. In Europe, biofuels are becoming common in road transport, and are about to enter usage in air transport. Although the US is behind Europe on such efforts, it's good to know we're at least getting started.
I guess it depends on the source of the feedstock, as usual. There are numerous species of algae, and according to http://oakhavenpc.org/cultivating_algae.htm (which draws its info from NREL studies conducted during the first oil crisis, back in the 1970s), the following table is representative of average yields based on species:
Therefore, your yield/acre/year should range from 5000-15000 US gal.
All of these are aquatic algae, and since the apparatus for growing them is fairly simple, it's a sustainable process that uses very little energy in itself. The electricity required to run the apparatus can be solar-generated onsite.
Furthermore, since the growing facility a) does not produce environmentally harmful effluent, and b) is essentially self-contained, it can be replicated in and around environmentally-sensitive areas of the southwest with very little impact.
I agree that human-engineered technology has some impact. However, I would argue that technology such as algae production has a far lower impact than, say, tar-sands petroleum extraction.
At the very least, it should be added to the mix of energy-sources - that's all I'm saying.
Good point about algae production. It does appear that it is a far better choice than most. However, I haven't seen the yield as high as you indicate. According to "Renewable Energy from Algae Biomass", depending on technology, the yield ranges as follows:
Low end: 1,800 gal bio-fuel/acre-year High end: 9,000 gal bio-fuel/acre-year
This is far lower than the 100,000 gal/acre-yr that you state. However, at the high yield range algae appears more doable:
Additional acres under cultivation to produce algae bio-fuel to replace oil: (170.3x10E6 algae acres/year)/(320.9x10E6 total acres planted in 2009) = 53.1% (34.1x10E6 algae acres/year)/(320.9x10E6 total acres planted in 2009) = 10.6.1%
So, adding 10% agricultural land for algae production is a far better prospect than the others. However, that still has consequences for wildlife in the areas that would be used and there are other considerations for algae production that I don't know at the moment, such as energy requried to produce bio-fuel and other resource requirements. Of course, if we reduce our energy requirement, then the acreage required would drop and producing oil already requires resources, so the analysis is more complicated than what I show here.
This is an article on the use of biofuels. The article states "The flight from Boeing's Delivery Center in Everett, Wash., to Tokyo Haneda Airport brings the airline industry a step closer to environmentally friendly and fuel-efficient long-haul flights", which brings up environmental issues, such as global warming and sustainability.
Environmentalism and sustainability is part of engineering, as is the economics of use. We, as engineers, must take into account all factors involving whatever we are designing, and that includes aspects not necessarily obvious at first glance.
You know, I enjoyed the article, and felt some hopeful reassurance in the successful trial flight.Then, I read the increasingly turbulent comment threads, and was actually saddened by the extremist pontifications of some of the moderators.I'm not impressed by the long-winded list of "supporting evidence", on either side of the alleged argument because this was not an article on Global Warming.
Whether we're impoverished or not, perhaps we should be smarter about what feedstock we use.
Algae produces far greater BTU/acre energy density than any of the feedstocks so far discussed in this forum. Not only that, but also produces waste methane that can be used to aid pyrolysis in the transesterification process.
100,000 gal. (or 13B BTU/acre - yes, that's Billion) trumps the other alternatives so far suggested, and it can be hydroponically grown in otherwise unarable desert.
I guess that's why the DOE is spending a cr*pload of money trying to develop this tech.
I am curious if you have done any research on the increased corn production in the U.S. in conjunction with the ability to grow corn after corn. From the limited bit I hear from the news. There is a concern of dropping corn prices due to the largest surplus in history. It doesn't sound to me like we are running out of this resource. Again, maybe I am missing something.
If you don't believe that overpopulation is a problem then you have to understand that currently the US uses about 20 million bbls of oil/day, which means that the per capita use is 0.064 bbl/person. Using the world's population of 7 billion, that means that for all people to attain a standard of living equal to ours, oil production needs to be 448.7x10E6 bbls/day or 5X the current production of 86.27x10E6 bbls/day. Also, as my previous calculation shows, that the US that has 5% of the world's population and uses 25% of its resources, we would need more than one earth to provide all people alive today with our standard of living, which is impossible.
As for reducing human population, all that's needed is to not create people who already do not exist.
With regards to the global warming debate, what evidence do you have that refutes the theory of anthropogenic causes? Please list these valid scientific articles. As for "There seems to be so little respect or consideration for the principles of the scientific method today", where is this applicable to climatology?
While I agree on your remarks about concerns about biofuel, about the loss of food production to a less-efficient subsidized biomass fuel, I'm not a convert to the overpopulation/anthropogenic global warming scenario.
First, I looked up peak production of coal and oil. Since you liked citing Wikipedia, I also used it for sourcing. According to the sources cited by Wiki, there is an estimated 147 years of reserves-to-production ratio of 'proven' coal reserves. These 'proven' reserves are those that have been found and drilled to such an extent that they are determined to be 'proven'. (https://en.wikipedia.org/wiki/Coal). Wiki also has mentioned that there is a 120 years of 'proven' oil reserves at current usage (https://en.wikipedia.org/wiki/Crude_oil). While this is obvious not going to remain constant, this also applies only to 'proven' reserves. By 'peak oil' production (https://en.wikipedia.org/wiki/Peak_oil), I'm assuming that you are referring to the Hubbert peak theory (https://en.wikipedia.org/wiki/M._King_Hubbert). The belief that we have already reached 'peak oil' would be an assumption of the Low EURR (Estimated (World's) Ultimately Recoverable Resources) peak having already passed (assuming 2 trillion recoverable barrels total, while 1.2 trillion has been used, USGS 95% confidence level) as opposed to the Mean EURR (3 trillion barrels), which is close to Chevron's estimates, or the High EURR (4 trillion barrels, 5% confidence level) (http://gulfpetrolink.net/Peak_AlHusseini.pdf). To disagree with your statement that we can't engineer ourselves out of this one, I disagree. These numbers are based on 1) a current level of exploration and 2) current level of technology for oil extraction. In the U.S. our administration has all but ceased exploration on federally controlled lands and offshore leases by U.S. oil companies (although they freely allow Repsol and Chinese rigs to drill oil for Cuba off our leases) (http://www.time.com/time/world/article/0,8599,2105598,00.html; http://www.reuters.com/article/2012/02/02/us-cuba-oil-idUSTRE8111S620120202). There are reserves not found, and many wells that have been drilled but not 'proven' because they aren't as profitable for the large companies, so they'll cap them and lease/sell them to smaller oil companies to extract at smaller margins. The reexamination of current reserves, such as the Bakken formation, back in 2008, was only estimated to have 3-4.3 billion gallons recoverable & non-recoverable, but various estimates now place the number up to 24 billion barrels, although current estimates are at 18 billion (https://en.wikipedia.org/wiki/Bakken_formation). There are payoffs to be made in improving the efficiency of oil extraction/recovery... another improvement could also be made in refining, but we're closing down some of our inefficent refineries now due to the high cost of crude, let alone improving their efficiency (which is economically unfeasible given EPA regulation). There are also other avenues to further develop, such as CTL (coal to liquid), natural gas, etc. Even Hubbert was a proponent of solar and nuclear energy.
While I'm definitely open to global warming/climate change, I'm still not quite convinced its primarily anthropogenic. To suggest that anyone who disagrees with global warming/climate change may be 'deluded' or an 'ideologue', while deriding your debater diminishes your argument. There have been questions raised by CERN over solar emissions influencing cloud formation, which could have a bearing on global warming/climate change theories. I've heard questions raised about the correlation between CO2 & global warming/climate change, and the rate of increase, and whether trending is accurate or cherry picked. When I'd like to see source material, I'm more interested in scientific journals, such as this USGS article (http://volcanoes.usgs.gov/hazards/gas/index.php) and this (http://www.agu.org/pubs/pdf/2011EO240001.pdf), which are far more influential than ranting and raving, calling skeptics names, and citing political hack junk science rags like The New Scientist, or 'An Inconvenient Truth'. Not everyone that disagrees is a 'denier' or part of a conspiracy, just as not everyone who embracing climate change/global warming is a nutjob or part of a conspiracy.
I'm also curious about your take on overpopulation and its reduction... How do you suggest that we solve it? Why are you absolutely sure that we've already overpopulated the planet? Are you suggesting to go to Asia, home of 60% of the world's population and eliminating some, or are you on a eugenics crusade, wanting to pick and choose who lives and dies (U.N. Death Panel), or you simply suggesting that we eliminate the U.S. population as a starting point, since we're obviously the worst 'offenders' in resource management? I'd like to think that you are talking about reduction through attrition, but given your statements I'm not so sure. Do you have children? If so, aren't you contributing to the problem? How would you react to someone else saying that there are too many of YOU on this planet? I guess you already know, since you've said it yourself.
Maybe I'm alone in being disturbed, not by the subject of the argument, but the nature and statements of the debate. I agree with Warren on several points, but not all, but despite the calculations, which I haven't verified yet, I'm not overly keen to support you even if I agree with you because of your manner. There seems to be so little respect or consideration for the principles of the scientific method today... I've seen stories about climate change proponents wanting to hunt down 'deniers' and burn their houses and families to the ground... or believe that skeptics are suffering from a mental disorder. It seems that open debate is being squeezed out of our society, that mouths keep running but our ears are becoming closed... It seems that most, today, seem to have 'tolerance', but only for supporting thoughts and opinions. It doesn't seem that the climate change debate is over... it doesn't look like it was really ever allowed to begin.
Well I have never heard anything so STUPID in all my life! Getting along?
Thanks for noticing. However, we are an impoverished nation. Our government spends 3 times what it takes in, and that is the sign of a sick economy. And that is all the above board spending they tell us about.
So, my new friend, we do have to call ourselves impoverished, because if any of us did that, (a) our credit would run out, or (b) we would go bankrupt, or (c) we would be arrested. Or all three. We are living on our grandchildren's good credit.
In a bid to boost the viability of lithium-based electric car batteries, a team at Lawrence Berkeley National Laboratory has developed a chemistry that could possibly double an EV’s driving range while cutting its battery cost in half.
Using Siemens NX software, a team of engineering students from the University of Michigan built an electric vehicle and raced in the 2013 Bridgestone World Solar Challenge. One of those students blogged for Design News throughout the race.
Robots that walk have come a long way from simple barebones walking machines or pairs of legs without an upper body and head. Much of the research these days focuses on making more humanoid robots. But they are not all created equal.
For industrial control applications, or even a simple assembly line, that machine can go almost 24/7 without a break. But what happens when the task is a little more complex? That’s where the “smart” machine would come in. The smart machine is one that has some simple (or complex in some cases) processing capability to be able to adapt to changing conditions. Such machines are suited for a host of applications, including automotive, aerospace, defense, medical, computers and electronics, telecommunications, consumer goods, and so on. This discussion will examine what’s possible with smart machines, and what tradeoffs need to be made to implement such a solution.