Bravo, Robert!

In the long run I can see only 4 currently viable energy generation schemes. These are hydro, nuclear, solar, and wind. Hydro is about maxed out for all practical purposes and the remaining expansion of hydro can come nowhere near our collective needs. Nuclear, while the largest in installed base currently, has multiple issues attached that range from successfully managing waste to proliferation of weapons to safe operation of dangerous facilities and others as well.

That leaves solar and wind as the possible safest and most responsible energy gathering solutions we have and solar is, again in my personal opinion, going to be more reliable than wind.

This is it, people. The world goes down the electric road or the world doesn't go at all. Biofuels are either a pipedream or for very limited specific applications only.

"The greatest shortcoming of the human race is our inability to understand the exponential function." -- Dr. Albert Bartlett
Into the Grey Zone

Solar energy panels do not use water. You can plant them in a desert. They don't even require soil, so you can plant them in a stone desert. Half the deserts on earth are stone deserts, deserts that don't even have sand that you could irrigate even if you did have water.

This article is great! But it neglect to mention biodiesel from Algea, the most realistic of all biodiesel option. Consider these facts:

1) Algae produce 100 times more oil per acre than traditional food oilseed crops (i.e. corn, soy, etc.).

2) Algae eat CO2, the major Global Warming Gas, and produce oxygen.

3) Algae require only sunshine and non-drinkable (salt or brackish) water.

4) Algae do not compete with food crops for either agricultural land or fresh water.

5) Algae can reproduce themselves and their oil every 6 hours, while it takes Mother Nature millions of years to produce crude oil in the ground.

Robert, you have grabbed the brass ring once again! :-)

I think that a confluence is building around the solar idea for one simple reason: It is the only large scale source that gets us loose from an endless seasonal "depletion chase".

I have been a fan of the biofuel idea in my youth, but once you see that it involves multiple industries, and conversion after conversion...it becomes what I finally began to see as "death by one thousand conversions"...providing the land, providing the seed, getting the seed in the ground...fertilizer, pest control, energy consumed in harvesting, energy consumed in process and distilling, transport to point of use...it finally begins to look like one of the old Rube Goldberg cartoons, like a steam engine used to power an automatic coffee pouring machine or something!

The path has to be much more direct than that, much fewer steps to usable energy. And it has to be scalable, and production more easily installed at or close to point of use.

Now the debate on what type of solar capture works best for the application....the old silicon chips, the newer generation of CIGS (Copper Indium Gelinium) or a thermal system (concentrating mirror or possibly Frensel Lens of some type)

Things are just now starting to get interesting, as we refine our options down to the ones that have the most bang for the buck! Thanks for your ideas, look forward to your high level of analysis and math applied to the various solar options! :-)

Roger Conner Jr.
Remember, we are only one cubic mile from freedom

Great work Robert...couldn't agree more.

Came to the same conclusion last year...now working on it.

My company has turned our efforts to Solar and Electric vehicle technologies. The whole last 10 months have been reorganizing the company and prototype development. Should have something to show everyone late fall.

The whole GW thing is helping our situation with certain organizations...most not ready to consider the energy problem.

Here's hoping we can hold it all together long enough to make a difference.

One thing I haven't seen ANY comment about on The Oil Drum is Professor George Olah's book "The Methanol Economy":
http://www.amazon.com/Beyond-Oil-Gas-Methanol-Economy/dp/3527312757/ref=...
Here's one of the better reviews of the book (saves me typing, watching spinning beach balls in firefox):
By B. Pankuch (Cranford, NJ USA) - See all my reviews
(REAL NAME)
Olah (1994 Nobel laureate carbocation chemistry, director of the Loker Hydrocarbon Research Institute) and his coauthors do an excellent job going over fossil fuel(coal, natural gas, oil) resources, how close we are to running out of each, the vast number of uses for these resources, and the likelihood of climate change due to their burning. It is assumed that in the future we will have abundant energy available from nuclear and alternative sources. Methanol would then be one of the prime carriers of this energy, and an alternate source for all petrochemicals.

They also cover alternative renewable energy sources, compare using hydrogen versus methanol as a carrier of energy from new renewable energy sources and nuclear energy plants. The authors do a thorough job pointing out the enormous use of hydrocarbons throughout the industrial world for a huge array of products. Not only do we need vast new renewable sources of energy we also need to be able to use this energy to change new carbon sources into useful products. The new source of carbon, methanol from CO2 and H2! Olah, et al shows in great detail how methanol can be changed chemically into the precursors for just about anything and at very high efficiencies. We would use energy from nuclear and new renewable energy sources directly where we can, such as powering our factories and homes' electrical systems. We would use some of this new energy to change CO2 from emissions and hydrogen from electrolysis of water, into methanol to run our cars, trucks, etc., and provide feedstock for all the products now produced from petroleum. Note that methanol formed this way adds no new CO2 since CO2 from the surroundings is used to make it. This is very similar to using ethanol produced from corn or other biomass, except it involves more chemistry.

The new process involves using electrochemical or photochemical reduction of CO2, which forms methanol, formic acid and formaldehyde, CO2 + 2H2 -> CH3OH with additional products which are also changed to CH3OH,
HCHO + HCO2H -> CH3OH + CO2
They don't give a lot of details, because they have a patent pending on the process.

In the interim, while we are developing and building alternative renewable energy sources, we can change coal, natural gas, biomass, etc., into methanol. This is already done to a small degree and existing infrastructure for gas and oil can be used with small adjustments. The authors also compare using hydrogen and methanol, as storage and transport media.

It was a surprise to me that there is more hydrogen in a liter of liquid methanol (98.8 g of hydrogen) than in a liter of liquid hydrogen (70.8 g at -253?C), water for comparison has 111g of hydrogen. Methanol would store and transport much more easily than liquid hydrogen.

The first sources of CO2 would be exhaust gas from utilities and big factories, which generate a lot of CO2, hydrogen would come from water being electrolyzed, CO2 + 3H2 -> CH3OH + H2O. Then as our CO2 capture methods get better it would be captured directly from the air. Anyone in the world would with access to energy, would then have a source for a vast array of chemicals! Note that if CO2 becomes a useful commodity people and nations will compete to pull it out of the atmosphere, and prevent it from being released since it has value. This has much greater appeal than other proposals such as sequestering of the CO2. A lot would depend on how efficient the process is. It would be useful if they would give some information on this, but Olah replied to me that `...we have of course extensive patent coverage filed for and in process. For obvious reasons in our book we could not go into any details.

The driving force for the Methanol Economy is new energy from nuclear and alternative renewable energy sources, which we don't have yet, replacing hydrocarbons as fuel. Olah, et al has great confidence that the many problems facing these new energy sources are solvable. The authors are quite negative on the safety of hydrogen, but don't seem to see a major non solvable problem with nuclear. Nuclear as we know certainly has its problems, and most of us are wary of nuclear. Scientific American had an article (December 2005 issue) on the latest nuclear plant design which uses 99% of the fuel rather than 1% in current plants. It would also have proportionally less radioactive waste, with a much shorter halflife. One of the hookers is using two separate liquid Na (at 600?C) loops as a coolant. Not a minor engineering feat. Another recent Scientific American article Sept 2006, instead sings the praises for 3rd generation nukes with improved technology, but with the same problems we currently have.

A fuel cell is being developed which uses methanol directly.
Anode: CH3OH + H2O -> CO2 + 6H+ + 6e-
Cathode: 1.5O2 + 6H+ + 6e- -> 3H2O
Overall: CH3OH + 1.5O2 -> CO2 + 2H2O
It has a theoretical efficiency of 97%, so far 34% has been achieved, while using H2 and O2 in a fuel cell has a theoretical efficiency of 83%. Of course methanol produces CO2 (which would eventually be used as feedstock) as compared to H2 which just produces water, a great advantage.

Anytime we contemplate huge installations for generating energy, whether they are nuclear or renewable we face the problem of transporting the energy to the user. Methanol, since it can use existing infrastructure of pipelines, trucks, gas stations with few changes would appear to be far cheaper than hydrogen. A July 2006 article in Scientific American `A Power Grid for the Hydrogen Economy' pointed out that our nation's electrical grid is experiencing problems and a possible solution would be to create a new national grid which would carry electricity from distant plants-renewable, nuclear, coal fired etc., by a superconductor cooled by liquid hydrogen. You would have the electricity almost resistance free (about 10% is currently lost in transmission) and the hydrogen for chemical uses. The economics of all these proposals is very hazy.

Some further food for thought is a 1998 study that indicates that the unsubsidized price of gasoline was between $6- 15/gal. A number of other studies place it at $3-11. If their methodology is close to correct then the current subsidy is much higher now, and if this subsidy were available to alternative energy sources they would be much more competitive.

You could create methanol for fuel cells by gasifying biomass.
Corn stalks, wheat and rice straw, switch grass and lots of different feed stocks from forest and agriculture can be gasified to producer gas, then processed to synthesis gas and then methane and then methanol.

There are an estimated 1 billion tons of usable biomass in the U.S. indicated in a Department of Energy study. With 100 gallons of methanol per ton that would make 100 of the 140 billion gallons of liquid fuel that we use for transportation. Combine that with fuel cell efficiency and you have a CO2 neutral form of transportation.

Solar + Wind + Tidal + EVs + PLHVs = the answer.

Intermittent renewable energy stored across the land in vehicle batteries vis a vis V2G technology. (Oh oh - I said that word).

At scale, forget biofuels.

Oh -the rigs no longer looking for oil can mine lithium from the ocean. Once out, it, like all other non-radioactive elements, is recyclable.

Great work, Robert, and to Euan's article also.

Robert,

I agree with you conclusion, solar is the way to go. I would stand up though for photsynthesis. It is not that inefficient. It does about as well as current PV which is why algae can be turned into fuel with about the same energy harvest. (You still lose because the fuel then goes into a heat engine.) But, plants are evolved to be eaten not burned. The rotting of forest mulch, the grazing of cattle, and the predations of insects all provide CO2 for further plant growth. From an ecological point of view, photosynthesis is just a means to fill out a niche, not the be all and end all of existance. It is useful for making structures that bring leaves into sunlight or nectars to tempt fertilizers of fruit to help spread seeds. It is pretty efficient, but it is not the only thing plants do. We can pick crops, like algae, which do little more than photosythesis, and this gets us close to our current liquid fuels consumption, but it seems to me that it makes much more sense to sprout our own silicon leaves, keep the efficiencies involved with this specialization and make liquid fuel use a relatively rare practice. It makes sense in some places, but not here where we can jump past most of that.

"the petroleum equivalent yield from planting all of the world's arable land in one of the more popular biofuel options is just under 30 million barrels per day."

Robert, your analysis of biofuels is wrong because you are considering the world as one unit and that's not the way it works. Present and potentially arable land as well as liquid biofuels usage intensity are NOT evenly distributed around the world. The countries with more biofuels production potential (e.g. Brazil, Argentina, Paraguay) have much lower liquid fuel (and energy in general) usage per capita than OECD countries. Therefore if they maximize the allocation of their agricultural potential into biodiesel production (plus sugar cane to ethanol), they will be able to run their current infrastructures FOR EVER, and it is just not reasonable to expect they will forego that possibility. So the people in countries that today depend on agricultural exports from these countries will have a problem.

Please bear my repeating the conclusions from a previous post:

- Once significant biodiesel production capacity has been built, land arbitraging based on farmers' profits per acre will drive the allocation of land to biodiesel crops (soybean, sunflower and rapeseed, SSR for short) or to grain crops.

- From that moment onward, fuel arbitraging will make the price of diesel fuel (however high it goes) set the floor for the price of SSR oils. Land arbitraging in turn will set the floor for the price of wheat and corn.

- There is a food Export Land Model, where food exports will be falling not because rising internal consumption, but because of ever increasing feedstock and land diversion into biofuels production.

- Poor food importing countries, and poor people in general, will be priced out of food.

- The world is NOW at peak food.

- Demographic scenarios of 9 billion people don't stand a chance.

- To minimize future (next decade?) starvation, people should be encouraged to:

Stop building, particularly suburban houses that imply a loss of farmland.

Stop procreating at higher than the replacement rate.

Robert,
Thanks for your hard work and scientific honesty, plus your bull dog Aggie tenaciousness. The efficiencies seem to win the debate-the fellows with the methanol or alge suggestions still have to contend with the efficiencies of solar vs. photosynthesis.

Another thing, solar, and its cousins, wind,hydro,and tidal are non-polluting. There is no disposal of waste problem. The only hang-up is the storage, which can be handled with pumped water storage and batteries. Any internal combustion engine produces waste in the atmosphere, particulates and CO2.

There will always be a market for liquid fuel for aviation and possibly for some long distance transportation, and bidiesel and alcohol might be suitable there. But its clear that if we want personal transportation, electric is the way to go. Its nuts to use hydrocarbons any longer-we need them for petrochemical products.

Robert,

Thanks for your report.

Woudn't it be better if we take into account only the barrels requiered for transportation? I mean, from those 85 millions only a part is used for that purpose and biodiesel won't be used to generate electricity, obviously.

Fernando

Robert,
Are you putting a chapter in your book on PRT? The cost of implementation is about 3x cheaper than replacing the fleet with electric cars. It could be built in 10 years compared with the 15-20 years it will take the auto and battery industry to crank out 200m new cars. Do we even have a battery yet?

I hear that PRT has a faster average speed than airplanes between SF and LA. Local commutes in electric cars will only get slower as the population grows.

The other advantage is that it requires 3x fewer solar panels to run it.

The third advantage is that it frees up parking lots and side streets for dense housing which encourages walking and bikiing.

http://www.solarevolution.com/PRT/

I have to admit that I have come to the same conclusion as you. The problem is that you have to spend some time looking at it, and running numbers before you can reach that conclusion.

I even have a "powered by biodiesel" license frame, and a biodiesel vanity plate. I will give up the plate when the tags are up for renewal (next month, actually).

The algae thing is about the only hope for biodiesel to be anything other than a niche, and even there things are far from certain.

Electric on the other hand seems to make much more sense to me. People talk about battery performance and all that, but I guess my reaction is that if fuel prices get high enough, that folks will gladly accept whatever limitations of electric cars that may remain.

Informative analysis, RR.

As I'm sure you are aware, an additional issue must be that of batteries. It is beyond dispute that attaching a PV to a stationary electric motor (or to an electrified rail line) is clearly preferable to using a diesel or biodiesel engine. The problem, as we all know, is with mobility. Mobile applications need a mobile power source - either a tank of fuel, or a battery. When you add batteries to the PV side of the scale, the balance might still be on the side of PV, but not quite so favorable. Batteries are still something much in need of further R&D.

Some of the battery problem could be mitigated by a simple ground-up re-think about the way we do things. For example, because we refuel motor cars, we think in terms of plugging in electric vehicles to recharge them. Consider an alternative approach. Suppose that electric vehicles are designed with standardized battery packs that can be changed out in a matter of a couple of minutes. One would drive in to a service station, and instead of having one's battery pack recharged, one would just have it changed out with a freshly charged one. The service station could be located uner a huge PV panel array, with a bank of battery packs recharging and ready for swapping. This model (the interchangeable swap-out part, anyway) is similr to that utilized for smaller propane tanks for recreational use. (I use this approach already on a smaller scale. I have some cordless outdoor equipment. Rather than try to power them with a huge, weighty battery pack, I have several small battery packs. While using one, the others are on the recharger. This is SOP for most people using cordless tools.)

Obviously, we have a huge installed base of gasoline & diesel fueled vehicles. Even disregarding the private passenger vehicles and long-haul trucks (for which other & better transport alternatives have been identified), there remain a large number of service vehicles that must be kept running. As many of these are heavy duty equipment with long service lives, we may not have the time to wait through normal replacement cycles. So the question thus presents itself: How many vehicles could feasibly be retrofitted with electric motors and battery packs? I think it is this issue that gets us back around to biodiesel. If we can't get all of the essential mobile equipment electrified quickly enough, then we may still have to be looking at a small quantity of biodiesel purely as a transitional strategy to tide us over until electrification of transport becomes universal.

One final little side comment: I hate to pick nits, but I should mention that the energy content of the oil produced from oilseeds does not exhaust the potential energy to be harvested from the crop. The oilseed meal often has an energy value as livestock feed, and the crop residues could be fed into an anaerobic digester along with manure to produce biogas (methane). I believe that were you to take these factors into account, the overall energy balance for biodiesel feedstock crops would look quite a bit better. Perhaps still not enough to tip the balance in their favor and away from PV, though.

Land for growing oilseed may cost just a few dollars per square metre while PV panels costs hundreds. So upfront that cuts out most of the world's population from serious use of PV. While biodiesel is a storable medium solar electricity is for a practical purposes a 'use it or lose it' form of energy. Biofuel production may disappoint due to drought or disease. The clouds that reduce PV may be the same ones bringing rain to crops.

Methanol enthusiasts should realise it is quite a nasty chemical. I thought spiral vision was a gimmick in Photoshop until I inhaled some.

So what's my conclusion from practical experience of both solar PV and biodiesel?...bring on nuclear.

Thanks Robert! I've long thought the same thing, basically since seeing how low the returns are on Corn ethanol, and how much land it takes. The rapeseed oil example scales my overall concerns to the world's demand for oil.

I believe bio-"liquid" fuel can't be a major solution to our energy demands, even if biofuels in general have long term value in storing solar energy.

Electricity production from solar power for immediate ongoing use is always going to be superior source of energy. Its rather sad we need this FIRST on transportation, while we can't even generate a fraction of our existing electricity from solar power.

Even if we get a high enough solar electrical capacity, storage of surplus energy is the question that must be addressed.

Storage solutions depend on the time scale of interest - 1 minute, 1 hours, 1 day, 1 month, 1 year, or even 1000 years! I mean for instance tree wood seem a pretty dense stable chemical storage system for even 1000 years, and you can build nice things out of it while you're saving it!

Maybe someday liquid fuels can be "manufactured" more directly from air, water and electricity? I suppose a worthy question for the famed "Hydrogen economy" is how much land do you need to produce hydrogen from solar generated electricity? (thinking wind turbines, but could be solar boilers, or whatever.)

Lemmie jump on the 'hate algae' train for a bit here.

I firstly refer you to the Dead Zone in the Gulf of Mexico.

The DZ:GOM is 22,000 sq km large.

It is full of algae and more algae. It is a man made problem. The light penetration depth in water is probably 10m. The density of algae would preclude growth below those depths!

Now for some cool calculations(feel free to fix)

Ghawar

280kmx30km in size. It has roughly 50-60 m of oil bearing rock in that region(i dunno i just guessed from the size and from the Ghawar posts indicating Arab D depths)

Ghawar therefore has ~5.4E11 cubic m of oil bearing rock

the DZ:GOM has 2.0E11 cubic m of plant bearing sea.

Assuming that the GOM waters has 1% plant material (not sure about this number) you get a 2 km to a side cube of plant material! (which mostly grows back every year!!)

hmmm... if the DZ:GOM cannot be harvested, where the material has already been grown, then what chance does land based solutions have? (again like always, i attempt to illustrate an easier way of extracting algal oil than current, and if the easy way does not work, then the harder way has no chance.)

the GOM fishing industry is hurting right now, so someone invest in some hydro-clones and fine mesh nets and harvest that plant matter. It's quite simple. A new reserve roughly the same size as Ghawar is being produced and it's not being exploited. Use solar powered driers and then feed the biomass into whatever for somethings production!!

note: you can send the finders-fee (i just found a reserve roughly 40% as ghawar with probably 80% of it being capture-able) to me in fine gold or silver coins.

... the future should be electric...

Another excellent post. Thanks, Robert.

If I may share with you one of my favourite commercials, two thirds down this page you'll find PG&E's "Live Better Electrically" ad (and since you're in the neighbourhood, why not check out the one for Texaco).

http://www.tvparty.com/comjing.html

Cheers,
Paul (who purchases 100% wind power through NSP)

Robert;
Thanks once more for a thoughtful and dispassionate topic.
( SI? Is that 'Standard International' units?)

Two more advantages I see with Solar and other forms of Home-generation..

1. This independence seems to me a natural tool to democratize our economy, as long as those invested in it are (edit) NOT JUST the wealthy. While it may seem this is the case, there is a whole sector of off-gridders who have bought into PV (thereby spending much of what wealth they may have had), and are not 'amongst the elite'..

2. A little goofy, but with their durability, I would think you could simply use PV - AS your outer roofing material. You'd have sheathing and a skin layer for weather/moisture proofing, but why not have an entire rooftop using whatever energy is hitting it? (Some for Heat, some Electric), and not spend the thousands every decade or so for Asphalt, etc.

Anyway, on the 'yeah,but' side, we had a great spat start up a few days ago in Southern Maine, where 'the hood' got up in arms about a guys five new Tracked Eyesores...

"SCARBOROUGH � All Laurence Gardner wanted to do was help protect the environment, but residents of the Grondin Pond and Woodview subdivisions say he created a "monstrosity."

http://business.mainetoday.com/story.php?id=122743&ac=PHbiz
"Solar panels in your house are one thing. That would be wonderful," said Jill M., who lives on Woodview Drive, just down the street from five free-standing solar panels that Gardner installed in his yard. "But this looks just like the movie with Jodie Foster in it. You know, with the aliens and such."

"Walter L., whose house on Clearwater Drive looks across the lake at the solar panels, said he spoke with a real estate agent who said the solar panels could devalue his property as much as 50 percent.

"It's just unbelievable that something like this could be constructed in such a beautiful neighborhood," he said.

Yes, the Hardy, Independent and Practical people of 'The Rugged Coast' ... aaagh!

And yet, I still have hope. Actually, the RealEstate comment reminds me of a study done in California about how much your home value goes up with the addition of Solar Panels.. of course, that's California, and today may not be the day to get into home prices, eh?

(There, that's at least TWO cans of worms I've opened up.. Thank me later!)

Bob

It's 2007, and people in the state of Texas, which is possibly one of the most sun drenched in the entire country, are still having to fight homeowner associations in order to install solar panels on their rooftops.
The homeowner associations are winning.
People are more concerned about how perfectly their exurban mansionettes comply with some absurd cornucopian fantasy they dreamed up while listening to neocon apologists for the peak oil denial crowd.
Solar continues to be regarded as some sort of expensive novelty or a plaything for tie-dye wearing hippies who worship compost piles while humming a mantra to Ben and Jerry.
Even Al Gore, the newfound wunderkind for the enviro gurus, has set the movement back at least twenty years by virtue of his conspicuous lack of solar awareness in his own spacious Tennessee home.
We can't even BUY a decent small and efficient diesel car or light truck unless we submit to the old adage:
"You can have any model you want, as long as it's a Volkswagen".
Meanwhile nearly ALL of the models we know and see every day on American roads are available in the rest of the world with a diesel option.
Our soldiers fight insurgents in the Middle East who use indestructible Toyota and Nissan diesel minitrucks as troop carriers and yet these same hardy beasts aren't certified to get the groceries in Anytown, USA.
As cynical as I think I am, I just can't keep up.
The world isn't going anywhere. We're going to just run out the clock until it stops ticking.

Great post Robert

Succinctly reduced all the BS to a couple of lines. I hadn't thought of it like that before, but the numbers really are hugely compelling for personal car transport.

With 50% of the world now city dwellers, some liquid fuels will be required for farming and food haulage to the city. Aviation will get some as well, but the sooner we begin our Manhattan project to maximise non-carbon/low carbon electricity the better.

There was a tv talkshow here last night. People ere still seriously discussing hydrogen, the most common misconception being that a (single?) solar panel will generate sufficient hydrogen from water to run the car. Knowledge and understanding of energy is almost nil among the general population.

Yes, batteries seem to be progressing well - with massive FF inputs. Also, where are all the exotic materials for new technologies going to come from?
Same goes for new multi-wavelength PV panels.
(Let's hope the next leap forward in batteries doesn't need Rhodium!)
Is the threshold of a solar panel factory powered by solar panels achievable?
Could the workers live nearby growing as much of their own food as possible?
Maybe, I hope so...
If so, then the next step must be a battery factory powered by solar panels and running 24/7 with battery back-up and electric trucks to deliver the materials.
The "peak oil/peak technology" discussion probably weighs in here.

Hello R-squared,

Thxs for the info. In regards to the lack of power-storage problems: some other TODer said that 'we need to learn how to make hay when the sun shines'. I might add also: 'when the winds blow, or the tide is running'.

Is it possible to restructure our lifestyle so that we can relax and consume beer during the slack times, but work when Nature is being generous with her energy slaves? =)

Bob Shaw in Phx,Az Are Humans Smarter than Yeast?

Robert,

Since you seem to have a good handle on biofuels, why not discuss biomass gasification vs. silicon PV cells for generation of electricity. That would seem to be an obvious direction to head from here.

Biomass gasification systems have an obvious advantage over PV cells as there is no exotic technology needed to manufacture and maintain them. No clean rooms requiring rivers of water, no huge companies requiring massive amounts of capital and minimal transportation.

2 peasants working in a grass hut in Africa can build a gasifier and run an ICE for electricity generation. They can maintain this indefinitely. Its a very local industry. Rather than focusing strictly on liquid fuels, since you've made the jump to electrification, it makes sense now look at all the issues biomass solves in that arena.

I personally am very negative on PV cells. They are not cost competitive today. However, biomass gasification already is cost competitive given a low cost of labor. That should be telling us something. Ash is mixed with compost and recycled back to the land, thus negating your concerns about exporting the biomass.

The only negative is people in the West don't like gasifiers because it means manual labor to make it cost effective. Automating it in an industrial fashion pushes up the cost too much. That'll change soon enough though as the economy crashes.

Scale, scale, scale, scale.

If we don't get the scale right, nothing else matters. If we can't figure out the right scale, we will never get it right and it really won't matter if The Restaurant At The End Of The Universe is runs on biofuels or PV arrays.

John Howe has suggested we might aim for an economy using 1/8 the energy we use now and that we embark on a crash program to build that largely in solar. It seems like a gargantuan task - both to build 1/8 and to cut down to 1/8.

At 1/8 the energy, what scale of economy and society can we support?

cfm in Gray, ME

What is the sound of Peak Oil falling in a $90 Trillion Dollar World Bond Market?

What is the sound of Peak Oil falling in a $90 Trillion Dollar World Bond Market?

The Future is Solar

The past was Solar. What's new? Want to discuss the socil co
social consequences of Peak?

It may be true that the near future "is solar," but are we sure that any kind of agriculture (let alone solar-panel-culture) is sustainable at all?

Far as I can tell, there may exist a few small pockets of sustainable agriculture worldwide, but culturally speaking it's the huge, unsustainable (profitable) operations that generate the kind of large-scale profits which confer strategic power. By unsustainably extorting Earth's resources more than the other guys can, faster and cheaper.

Nobody can really afford to go sustainable, because then the unsustainable guys can unseat you with their "surplus energy?" But, nobody can afford to remain unsustainable forever, because then evenetually the environment is burned out and the surplus is gone?

Bryan

A RECOMMENDATION, AND A PROJECT IDEA

Now that's luck! I am a late night worker, so when I get home, I often turn on the overnight PBS reruns while I fix a bite to eat and check out TOD....
Turned the set on tonight, and got this one hour documentary film on our local KET (Kentucky Educational Television) station.....
http://www.powerofthesun.ucsb.edu/

Hosted by John Cleese of Monty Python/Fawlty Towers fame, and with a nice assortment of folks, some Nobel Laureates, what an interesting and informative film, even for someone well versed in solar terminology and development, and what a great explanatory film for newcomers....$20 bucks for the 2 DVD set (the general one, and a more specialized film for students of science on silicon solar cell technology) I intend to have these two....a bargain education, very good work...:-)
----------

So, in other news, I am looking at a fascinating project and even beginning the planning on it....some old "partners" and other assorted tinkers I have known and myself were discussing an idea, and it is beginning to develop in to something we are going to have to do, just to prove to ourselves that it can, or cannot, as the case may turn out, be done:

If we agree that in an energy depleted world, there is going to be a need for diverse and well distributed infrastructure, we decided that a priceless asset would be a fabrication shop, outfitted with at least a metal lathe, drill press, sheet metal sheers, arc welder, cutting torch, and of course all the normal hand tools and small power tools, such as electric drill, chisels, taps, dies, etc.

Now, here's the trick....could a small shop of such design be built to be stand alone as far as energy goes, i.e., powered by some type of renewable, or locally available energy? Thus, the shop would be an example of what could be done....a nation that would have at least one or two of these types of small fabrication shops in every county, designed so that they could keep functioning even without grid power or imported energy....

It is said that the Brits survived the Blitz this way....that Hitler thought he could stop them by bombing London to the ground, but that the Brits were masters of the "small shop" system, and had fabrication shops scattered all over England, able to build/fabricate about anything....

If such a small shop could be built (we are right now thinking in terms of under 5000 square feet, but the floorspace amount has not yet been set) what type of energy would we use to power it.....

Options on the table are (a)Wood, driving heat and a steam or Stirling engine (b) Solar, either PV or concentrating mirrow mounted beside the shop or on the roof....(c) Wind turbine, or some variety of the above options.....more radical possibility would be some version of Canola/Rapeseed/soy/sunflower grown right beside the shop, and a section of the shop used to press out and use the oils.....(can bioDiesel work on that small local scale....?),

As you can see, this starts to become quite a mental chess game, and we have already come up with some fascinating options in our search for possibilities!

I will keep you folks posted on how this develops, my buddies and I are really getting out heart into doing this, with the limiting factor being (a)money and (b) time, with the first being more limiting than the second!

RC
Remember, we are only one cubic mile from freedom

Robert,

Excellent and incisive analysis, as always. In the context, here's something that might be interesting:

http://www.technologyreview.com/Biztech/19095/?a=f

RR

Here's something that is probably not so interesting.

Nonetheless, please consider as background thought for your chapter the idea that harnessing any forms of life for fuel should be valued against the alternative (you know - SUV - Home Depot - flowers - lots of space - whew - what work).

And to never confuse need (i.e. developing countries) with NEED (you know - SUV - Home Depot - flowers - lots of space - whew - what work).

If plants etc evolved with us (generally speaking), maybe we should think and think again about burning them for fuel unless it is absolutely necessary. Of course, absolutely necessary is quantifiable. Just a worthwhile thought we hope.

Good post. I point you to the small footprint of solar hydrogen production in terms of land use. The study is by Ludwig Bolkow Where will the hydrogen come from available at http://www.hyweb.de/Wissen/docs2007/EHA_WhereWillH2ComeFrom_2007.pdf

Fuel production per hectare is, in my opinion one of the fondamental issues in renewable fuels, as well as water use, of course.

The main alternative to H2 producion is the Bossel-vision of an electron economy, featuring Plug-in Hybrids as energy storage in a CONNECTED NETWORK
http://www.physorg.com/pdf85074285.pdf
http://www.hyweb.de/News/Bossel-Eliasson_2003_Hydrogen-Economy.pdf

This path don't seem feasible to me because a battery incorporates the fuel and the energy convertion in the same place, whilst the fuel cell does not (not considering performance and life cycle).

Regards,

Giancarlo

PS A post in italian was : http://www.locchiodiromolo.it/blog/?p=531#more-531
More references on http://www.locchiodiromolo.it

First off I want to state I love solar power, specifically PV. I was hooked when in the 70's, as a kid, during the oil shock (here in the US) I went to Radio Shack and purchased one of those 2.5 x 5 cm mono crystalline PV cells. I was amazed when I was able to power a small DC motor off it. I've built my own small panels in the past, ordering cells from Edmund Sci. These were small panels, no more than 20-30 watts.

I also agree that PV is likely much more efficient at harvesting sunlight than photosynthesis. I think a good argument can be made that electricity is the most anonymous and useful form of energy we've got, hence PV is a "good thing"

However I get annoyed when I hear people claiming that PV can somehow replace even a tiny fraction of our current capacity. If you run the numbers you'll see it simply cannot scale, especially this late in the game. I think we're looking at a cliff oil scenario - if we were to go the solar route we should have started in earnest decades ago.

This is from a PO thread, someone claimed:

A 10 mile x 10 mile square of desert in Nevada would supply us with most of what we need if we were to put conservation first (the first rule of solar is to not waste any of what is so expensive to produce). I think that 100 square miles wouldn't kill as many species as it would save.

To which I responded:

Not even close. Sigh. Force me to do the math.

100 square miles is about 2.59 * 10^8 square meters (according to google there's 2,589,988 square meters in a square mile).

Assuming panels with a 10% conversion efficiency (100 watts per square meter) this comes out to a peak capacity of ~26,000 megawatts. Of course this is optimistic as not every square inch is going be covered with panels, and this is only the peak capacity close to noon.

Know how much electricity is consumed every day, just in the US? It's about 11,108 GWh (that's gigawatt hours - according to this site). Shoot, you're only off by three orders of magnitude. That's some impressive conservation!

Then there's the problem of storing this electricity - it cannot be produced on demand as nearly all electric power currently is. This alone is a huge problem if you want to implement this large scale.

And then there's the cost. Assuming $4/watt for solar that's only about a 100 trillion dollars. Chump change. Bring the price down to $2/watt and it's a bargain 50 trillion dollars - just for the panels. That's 50 trillion dollars to get enough capacity to meet about 1/1000 of our current (and growing) needs. Is the scale of the problem starting to sink in yet?

Perhaps I made a mistake in my figuring.. but I fail to see how PV can replace a meaningful fraction of our electric use. Not even close.

Of course I'm talking about good old proven Si PV technology. Perhaps a newer tech, not yet proven, could substantially reduce the cost? Maybe.

Currently all renewable energy sources are heavily subsidized by cheap fossil fuels. A PV panel remains an energy sink until it's been in use for 2-5 years - and that's daily use. It takes that long to 'pay back' the energy that went into making it.

I just can't see it happening, much as I might wish.

I do not know if any of you has heard about this, but I talked the other day with a researcher that was working on artificial photosynthesis. He talked about it as a very experimental research, but that if successful it would make very cheap energy. ¿Can someone comment on this?

Robert, you referenced the Spectrolab solar panels that achieved 40.6% efficiency last year. Other manufacturers are evaluating similar technologies, which concentrates sunlight on silicon using mirrors to improve capture. However, theory and demonstrations are one thing; practical applications are another.

When do you reasonably think we'll see solar panels offered with 25-30% efficiency, let alone 40%? And when will our energy tranmission infrastructure be upgraded so as to minimize energy losses from generation site to the end user?

... The only easy day was yesterday ...

Robert, what you mean by an electric transport system?

Plug-in hybrids? Reasonably certain the proponents of such own homes. The logistics of getting this to work in the typical outdoor apartment lot seems tricky. Snowplows would bury outlets coming out of the ground if they or someone else didn’t run over them first. So from above? In large parking lots at least this means some means to retract/retrieve the cord. Individual metering would add to the cost. The cost of wiring will be high. For those who have to park on street things get even trickier. It would at best only work for cars and light truck or about 50% of the US oil usage. And I’ve not seen a detailed breakdown of how much oil goes into manufacturing the batteries. You’ve probably seen the study that concluded there is not enouth cheap Li to power our cars with such batteries. And I want to see just how far any battery will take you when it is -20 F outside.

Light rail personal vehicles? I love the idea. But again, logistics. Can’t seem to run them in parallel with the current roads due to space considerations. How to run them together? Stopping distance on rail is going to be much farther than rubber on asphalt due to the low coefficient of friction. Some reason rail won’t work on hills.

If someone knows of an elegant answer, or any answer for that matter, I would like to hear it

Thank You!

I agree that the future is electric but as I see it the challenge is not technological. I show people a picture of the countryside and ask "what man made things do you see?" and they are power lines and roads, I call it the longest metre (or foot) The distance between the line and the vehicle, What it requires is an intelligent rapid inductive link and power storage, This removes the necessity for carrying all your energy with you, an EV with a sub 10 mile range would be trivial, In cities it could be even less. I doubt it will happen though, because of the inertia of the installed systems

Neven MacEwan B.E. E&E

Try 'the waaay in the future is solar'. Even the best top-notch, state of the art solar cells have an effiency of about 43%. So a little more than half the sun's energy doesn't even get turned to power.

And this is disregarding the fact that if a few clouds roll over - poof! - no sun and no power.

Come back then you can turn *at least* two-thirds of the light into power and have a way to 'bank' massive amounts of it for a rainy day (literally). Then we can talk solar power.