Energy Resources of the Future
An accomplished author who happens to be a fine friend is writing a novel set in the future, and asked for my take on various forms of energy that may compete with solar and wind 50 years hence. I thought I’d publish my responses to the prompts he gave me.
Let me begin by quoting a colleague who happens to be one of our “2GreenEnergy Associates,” Dr. Peter Lilienthal, who once told me, “If you don’t care how much you pay for it, I’ll find you all the clean energy you want.” The point is that the comments I’m about to make are all rooted in dollars and cents. The only thing we care about is how much it costs to push electrons through wires, and what if any premium we’re willing to pay to have that happen without ruining the environment and human health in the process.
Biomass: I really don’t see it, or its cousin, biofuels. The real problem is thermodynamics; plants didn’t evolve on this planet to store any more energy than they need to grow and reproduce. The enterprise of planting, raising, harvesting and processing life forms is doomed to failure. If there is any possibility here at all, it lies in algae, since it has 30 – 50 times more gravimetric energy density, i.e., Joules/kilogram, than any terrestrial plant. But we’ve all seen the unmitigated disaster this has been over the last half-century, which seems to imply that it’s not going anywhere over the next half-century. The oil companies themselves have sunken fortunes in this arena in what I believe is a sincere effort to get this done, and have by and large given up.
Geothermal: This could go either way. Of course, places that have huge geothermal resources and a poor choice of competitors (like Iceland) will probably be big geo consumers for a long time to come. But in the main, this technology is inherently risky and unpredictable. The main issue is that there is currently no technology analogous to oil exploration to see what’s down there before drilling, and drilling is a real beast, because, unlike oil and gas, you’re going through the hardest parts of the Earth’s crust. Needless to say, the potential is enormous; the amount of energy (caused largely by radioactive decay and the friction of materials moving past one another as the planet continues to coalesce due to its own gravity) is huge.
Hydrogen: Hydrogen is an energy storage medium, rather than an energy resource. To the degree it has value in the energy equation of the future, it lies in its portability, i.e., it’s a replacement for oil and gas. But it has almost no chance of success, for a few different reasons, any one which by itself would be lethal to the so-called “hydrogen economy”–a term coined in the early 1970s that, for some reason, is still “a thing” today. A) We’re not going to rebuild the fuel infrastructure. B) Fuel cells are expensive and their price isn’t falling. C) They’re fragile and don’t last long before requiring replacement. D) The processes (methane reformation and the electrolysis of water) are very inefficient. Toyota and Honda offer hydrogen fuel cell cars, but they’re expensive to the consumer, and the OEMs are clearly losing money on each one they sell; I believe we’ll see them give up when battery EV become mainstream over the next 10 years.
Hydropower: The term “hydropower” means several different things, but none of them is going to be important outside of niche applications. Obviously, we have the hydro-electric dams that have been around for 80 years, but they have a huge eco-footprint, and we’re loathe to build more. From the perspective of clean and sustainable energy, there is tidal, ocean current, wave, and run-of-river hydro, but none of these is even close to keeping pace with solar and wind. Evidence of this is the fact that one of my favorite energy conferences, the “Ocean Energy Show,” no longer exists.
Likely Sites for All These: As explained above, the likely sites for all these are places that have huge natural resources and poor competitors. Places like rural Alaska have power at almost $1/KWh, and hydro resources coming out its ears. Equatorial islands ship in bunker diesel at great financial and environmental expense, and they can use OTEC (ocean thermal energy conversion). All lands near oceans at extreme latitudes have huge tidal resources. The southeast part of the U.S. has relatively poor wind and solar resources, but they have huge forests, so I suppose biomass is a possible option, but for the reasons noted above, I’m betting against it.
You didn’t ask about it, but the real wild card in all this is advanced nuclear. There are a couple of different kinds of fusion that may work, notably TriAlpha, and the fission of thorium is another possibility. If you’re interested in more stuff on this, please ask. If you happen to have my most recent book, Bullish on Renewable Energy, there’s a chapter on the subject. I’ll send it to you when I get home later.
It’s also worth noting that all this evolution is not happening in a vacuum. For instance, the presence of renewable energy makes the enterprise of electric transportation that much more appealing. Once we get rid of coal as our go-to resource for meeting incremental and predictable loads, electric vehicles begin to have enormous ecological benefits. EVs can also “soak up” generation that happens in excess of current loads, which is a very big deal in a world of variable sources like solar and wind.
And speaking of variable resources, we need to understand that this evolution is also occurring in the presence of energy storage that is steadily becoming more affordable. Obviously, the value of intermittent sources increases dramatically in the face of cheap storage, e.g., utility-scale batteries, which seem to be right around the corner. This is good for solar and wind, but it’s bad for geothermal and the others that produce baseload power.
I hope this has been helpful. Please feel free to ask for more detail; I’m always happy to help.
Craig,
I agree with most of your analysis, however why do you persist in attacking HFCV technology with the same inaccuracies despite having been supplied authenticated accurate facts?
A)” We’re not going to rebuild the fuel infrastructure ”
By “We” , who do you mean ? Although I’m sure you won’t be rebuilding anything, the oil industry is easily able to rebuild the necessary infrastructure, much of which already exists.
B) ” Fuel cells are expensive and their prices isn’t falling “.
The technology is undergoing considerable development and like most industrial products, prices will fall with mass production.(but you knew that already didn’t you?)
C) “They’re fragile and don’t last long before requiring replacement.”
Modern HFCV technology is neither “Fragile” nor does “not last long before requiring replacement ” !
D) “The processes (methane reformation and the electrolysis of water) are very inefficient”
There are at least 20+ known methods of producing Hydrogen. “Inefficiency” in production, isn’t really an issue for consumer or producers, only profit and convenience.
Craig, I’ve got a considerable vested interest in promoting EV technology, but until the limitations of EV technology are resolved and gasoline and diesel lacks viability, HFCV vehicles could be a practical alternative.
HFCV’s offer the same convenience and familiarity as ICE technology. HFCV technology can be used in a greater range of vehicles. For governments, these vehicles are a non-disruptive, zero emission alternative and I can see how that would be attractive.
You don’t need to attack HFCV technology with inaccuracies and distortions, the future of HFCVs will be decided by the speed of EV ESD development.
Still not convinced, try doing a “Benjamin Franklin” analysis, by writing down in one column (without distortions) the advantages and disadvantages of EV’s v HFCV and you may find yourself surprised.
Craig,
Giving a little more thought to problems of building a Fast Breeder Thorium Reactor in the US (or for that matter Australia).
India’s nuclear will complete an experimental 500 megawatts fast breeder nuclear reactor in Kalpakkam by 2018.
So what happened to the US ? After all, America is where the technology was invented.
The answer lies in the completely byzantine labyrinth of US regulations.
Although the reactor can be built in less than 5 years, it takes 25 years, that’s right 25 years, to get permission. That’s without any public hearings, objections, law suits etc.
All in all, about 40 years before producing the first Watt !
The NRC requires so much paperwork from the nuclear power providers that the average plant requires 106 full-time employees just to go through it all.
NuScale Power spent $500 million and 2 million labor hours over eight years to ask the federal government for permission to build an advanced nuclear reactor. The energy company had to file a 12,000-page application to build an advanced nuclear reactor.
NuScale paid 78 NRC officials $258 per hour to review the lengthy application.
A Thorium reactor would cost more since even though it’s not Uranium, the NRC insists Uranium specifications must be included because Thorium isn’t included in the standard forms !
So why hasn’t the industry complained ? Well, they have but the NRC is very stubborn and at an early stage in his Presidency Obama shut down a review process ordered by the Bush administration, without explanation.
Whether true or not, lobbyists from the Renewable Fuels Industry claimed this as a victory for their lobbying with Obama-Clinton.
Meanwhile in the land usually associated with red tape and slow bureaucracy, India, things are happening.
Japan is not far behind. The first of it’s mini thorium power plants is expected to start operating in 2003. These plants o only produce 350 megawatts but can be built on a very small footprint, and cost only $ 300-400 million each.
The Japanese concept could easily pay for itself from savings on transmission losses and infrastructure.
But who will invest in 25 year of Red Tape?