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A return to making love, not war – Iraq and replacement fuels

Early on I wrote a column about an unanticipated Thanksgiving dinner conversation with a special operations soldier who had served in Iraq. His comment, in response to a question I asked about whether he and his buddies knew why they were sent to Iraq, was brief and blunt: “oil and U.S. security.” He would have none of what he thought was b.s. about “freedom and democracy” or “weapons of mass destruction.” Before I asked the question I actually already knew what his answer would be, but a glass of wine, a wonderful piece of turkey and good company suggested that my inquiry would lead to an opening for a longer repartee on the Middle East and U.S. policy. It did, and again oil and oil politics were the dominant theme.

I suspect that many of the writers of today’s headlines and op-ed articles anticipated Republican Eric Cantor would win. They are now arguing, in sometimes misleading reference terms concerning democracy, inter-sectarian harmony and morality, for a more aggressive U.S. policy toward the invasion by Sunni radicals of parts of what once on a map called the nation of Iraq.

But the real issue for many “experts,” I again suspect, is oil — a fear, whether factual or not, that if Iraq collapses, the world oil supply (already close to equilibrium concerning demand and supply) will relatively quickly reflect shortages and much higher prices per barrel of oil ($150 a barrel) and oil’s product, gasoline ($5 and more).

Should we be sending kids to fight for our apparent God-given right to Middle Eastern oil? Although I think a lot about the ethics of public decision making, I am not an ethicist. But as long as there are alternatives to supply, my hard-nosed policy advice would be against war or the steps that might lead to war. Iraq has not been the noble state that welcomed America in to rescue it ostensibly from Saddam Hussein. Its form of democracy has been limited, corrupt and sectarian.

What should our calculations be, concerning alternative supplies of oil? First, we ought to really think through whether a full or partial shutdown of Iraqi oil wells will mean a damn. Iraq alone supplies a small share of U.S. oil imports. Most of the often-shrill economic coverage of the radical Sunni invasion and its potential impact on U.S. oil seems to relate more to perceptions, not empirical evidence, about shortages and prices. Commentators “perceive” what the oil markets might or will do — really what oil speculators and investors will or will not do — based on what is currently happening in Iraq, not on facts on the ground. Neil Cavuto of Fox Business said, “Oil is a commodity, a global commodity, and like any stock in almost any market, it often trades on issues having little to do with basic fundamentals, and more to do with simple fear.”

Assuming, however, there is a real worldwide shortage of oil as a result of a closure of Iraqi wells, or that fear drives the prices up so much that there is a strain to the economy, the Saudis, probably, among all the OPEC nations, are the only ones with sufficient oil in the ground to make an immediate difference concerning supply. But will they? They have shown some flexibility in the past to U.S. petitioning. They have also, at times, despite their security relationship to the U.S., turned us down. This time around the Saudis could well be more than a bit sensitive, particularly if it looks like the radical Sunnis might win. The Kingdom is vulnerable with respect to a radical brand of Sunniism. I bet they also fear a potential Shiite effort to push the radicals back, particularly one led by Iran. Life is never simple for the House of Saud.

Okay, where are we? Oil is sold in an international marketplace. No matter which side you are on regarding the Keystone XL pipeline, if approved and completed, it will not have a major impact on U.S. gas supply or prices. Ask your friendly oil refinery or oil company executive where he or she believes Keystone-supplied oil will be going. Most of the assumed supply will be traded internationally for the highest global price. The predicted increased supply of U.S.-produced gasoline will probably help diminish price increases slightly, but don’t make a bet on how much. Today, a price of a gallon of regular unleaded gasoline is well over $4 in California and U.S. production is at a very high level.

What would likely help keep gasoline prices from spiking significantly and, at the same time, lessen the amplitude of the cycles is a commitment to competition in the fuel marketplace. Let Adam Smith reign! Allow safe, cheaper, environmentally better replacement fuels, particularly natural gas-based ethanol (and someday soon, methanol) to compete with gasoline. Encourage the conversion of older vehicles to flex-fuel vehicles! Push for renewable fuels and related vehicles that appeal to a larger market than at present, given costs and design constraints! Reduce our dependence on imported oil! Make love, not war! Drive (excuse the pun) for strategic solutions!

Japan bets big on hydrogen fuel cells

Remember when Japan’s Ministry of Economy, Trade and Industry (METI) used to sit atop the Japanese industrial complex, steering it like some giant Godzilla hovering over the entire world?

Those were the days when Japan’s government-industry partnership was supposed to represent the future, when Michael Crichton wrote a novel about how Japan would soon devour America, when pundits and scholars were warning that we had better do the same if we hoped to survive – before, that is, the whole thing collapsed and Japan went into a 20-year funk from which it has never really recovered.

Well those days may be returning in one small part as METI prepares to direct at least half the Japanese auto industry into the production of hydrogen-powered fuel-cell cars.

“Japanese Government Bets the Farm on Fuel Cell Vehicles” ran one headline earlier this month and indeed there’s plenty at stake for everyone. The tip-off came at the end of May when Jim Lentz, CEO of Toyota’s North American operations, told Automotive News that electric vehicles are only “short-range vehicles that take you that extra mile…But for long-range travel, we feel there are better alternatives, such as hybrids and plug-in hybrids, and, tomorrow, fuel cells.” The target here, of course, is Tesla, where Elon Musk appears to be making the first inroads against gasoline-powered vehicles with his $35,000 Model E, aimed at the average car buyer. Toyota was originally in on that deal and was scheduled to supply the batteries until it pulled out this spring, ceding the job to Panasonic.

But all that was only a preview of what was to come. In early June, METI announced it would orchestrate a government-private initiative to help Toyota and Honda market fuel-cell vehicles in Japan and then across the globe. Of course that leaves out the other half of Japan’s auto industry, Nissan and Mitsubishi, pursuing their version of the EV, but maybe the Japanese are learning to hedge their bets.

The hydrogen initiative will put the fuel-cell vehicle front-and-center in the race to transition to other forms of propulsion and reduce the world’s dependence on OPEC oil. Actually, hydrogen cars have been in the offering for more than twenty years. In the 1990s soft-energy guru Amory Lovins put forth his Hypercar, a carbon-fiber vehicle powered by hydrogen fuel cells. In 2005, California Gov. Arnold Schwarzenegger inaugurated the “Hydrogen Highway,” a proposed network of hydrogen filling stations that was supposed to blanket the Golden State. Unfortunately, only ten have been built so far, and there are still no more than a handful of FCVs (hydrogen fuel cell vehicles) on the road. Mercedes, BMW, Audi and VW all have small lines but none are marketed very aggressively in the United States.

This time, however, there may be a serious breakthrough. After all, Toyota, Honda and METI are not just in the business of putting out press releases. Toyota will begin production of its first mass-market model in December and Honda will follow with a 5-passenger sedan next year. Prices will start in the stratosphere — close to $100,000 — but both companies are hoping to bring them down to $30,000 by the 2020s. Meanwhile, GM is making noises about a fuel-cell model in 2016 and South Korea’s Hyundai is already unloading its hydrogen-powered Tucson on the docks of California.

What will METI’s role be? The supervising government ministry promises to relax safety standards, allowing on-board storage of hydrogen at 825 atmospheres instead of the current 750. This will increase the car’s range by 20 percent and bring it into the 350-mile territory of the internal combustion engine. Like the ICE, hydrogen cars can “gas up” in minutes, giving them a huge leg up on EVs, which can take anywhere from 20 minutes with superchargers to eight hours with household plugs. METI has also promised to loosen import controls so that foreign manufacturers such as Mercedes-Benz can find their way into Japan. And, of course, it will seek reciprocal agreements so Toyota and Honda can market their models across the globe.

So will the one-two punch of government-and-industry-working-together be able to break the ice for hydrogen vehicles? California seems to be a particularly ripe market. Toyota is already the best-selling car in the state and the California Energy Commission is promising to expand the Hydrogen Highway to 70 stations by 2016. Still, there will be stiff competition from Elon Musk if and when his proposed Gigafactory starts turning out batteries by the millions. Partisans of EVs and fuel-cell vehicles are already taking sides.

In the end, however, the most likely winners will be consumers who will now have a legitimate choice between hydrogen vehicles and EVs. It may be a decade or more before either of these technologies makes a significant dent in our oil consumption, but in the end it will be foreign oil providers that will be feeling the pain.

Can supercapacitors replace batteries?

The electric car depends on batteries, and before EVs become a large chunk of our automotive fleet, there are probably going to be some changes.

Right now, Elon Musk is betting he can produce millions of small lithium-ion batteries not much bigger than the ones you put in your flashlight and string them together to power a $35,000 Tesla Model E over a range of 200 miles at speeds of up to 70-80 mph. The Model E also will also need an infrastructure of roadside “filling stations” and home chargers, although the best superchargers still take more than 20 minutes to achieve 80 percent capacity.

But there is another way to store electricity, long familiar to the designers of electrical circuits. It’s the capacitor, a device that stores a small current by static electricity rather than a chemical reaction. Capacitors sit in all of your electrical devices, from radio circuits to the most sophisticated laptops, and are essential to providing the steady electric current needed to run such electronics. But what if the concept of capacitors could be scaled up to the point where they could help power something as big as an electric vehicle? Granted, it’s a long, long way from the 1.5-volt capacitor in your iPad and powering a 4,500-pound Tesla along the Interstate, but researchers are out there probing and are already thinking in terms of a breakthrough.

Right now there’s a huge separation between the things that batteries can do and the things that capacitors can do. In a way they are complementary — the strengths of one are the weaknesses of the other. But researchers are working toward a convergence — or perhaps just a way of using them in tandem.

A battery employs chemistry by splitting ions in the electrolyte so that the negative ones gather on the cathode and the positive on the anode, building up a voltage potential. When they are connected externally an electric current flows. Batteries have a lot of energy density. They can store electricity up into the megawatt range and release a flow of electricity over long periods of time. The process can also be reversed, but, because the reaction is (once again) chemical, it can take a long time.

Capacitors store electrons as static electricity. A thundercloud is a great big capacitor with zillions of electrons clinging to the almost infinite surface area of individual raindrops. And as everyone knows, this huge stored capacity can be released in a “bolt of lightening.” Capacitors can be recharged almost instantly but also they release their energy almost instantly, rather than the even flow of a battery. One of their major uses is in flash photography. But their capacity for storing power is also limited. On a pound-for-pound basis, the best capacitors can only store one-fifth to one-tenth the equivalent of a chemical battery. On the other hand, batteries can start to wear out after five years, while supercapacitors last at least three times as long.

Back in the 1950s, engineers at General Electric, and later at Standard Oil, invented what have come to be called “supercapacitors.” Basically, a supercapacitor changes the surface material and adds another layer of insulating dielectric in order to increase storage capacity. Surface area is the key and engineers discovered that powdery, activated charcoal vastly increased the capacity of the storage plates. Dielectrics were also reduced to ultra-thin layers of carbon, paper or plastic, since the closer the plates can be brought together, the more intense the charge. Since then they have begun experimenting with graphene and other advanced materials that may be able to increase surface area by orders of magnitude. All of this means that much more electricity can be stored in a much smaller space.

But the problem of low energy density remains. Even supercapacitors can only operate at about 2.5 volts, which means they must be strung together in series in vast numbers in order to reach voltage levels required to power something like an electric car. This creates problems in maintaining voltage balance. Still, some supercapacitors are already being employed in gas-electric hybrids and electric buses in order to store the power siphoned off from braking.

Researchers in the field now see some possibility for convergence. Most exhilarating is the idea that the frame of the car itself could be transformed into a supercapacitor. Last month, researchers from Vanderbilt University published an online paper entitled, “A Multifunctional Load-Bearing Solid-State Supercapacitor,” in which they suggested that load-bearing materials such as the chassis of a car or even the walls of your house could be transformed into supercapacitors to store massive amounts of electricity on-site. Combined with advances in evening the flow of electrons from supercapacitors, this opens up whole new avenues of approach to the electric car.

All of these developments are a long way off, of course. Still, supercapacitors support the possibility of pulling out of your driveway in the morning and returning at night in your EV without needing to gas up with foreign oil at your nearest filling station.

DME poses a challenge to CNG

If there’s an Achilles’ heel to the efforts being made to introduce compressed natural gas (CNG) into the country’s vehicles, it is that somebody is going to come along with a liquid fuel that works much better.

CNG has many things going for it. Natural gas is now abundant and promises to stay that way for a long time. That puts the price around $2 a gallon, which is a big savings when gas costs $3.50 and diesel costs $3.70 per gallon. Trucks — mid-sized delivery trucks and big 18-wheelers — are the target market. Delivery vans usually operate out of fleet centers where a central compressor can be installed to service many vehicles. Meanwhile, pioneering companies such as Clean Energy Fuels are busy building an infrastructure at truck stops along the Interstate Highway System to service long-hauling tractor-trailers on their cross-country routes.

But there is a weakness. As a gas, CNG requires a whole new infrastructure. Compression tanks must be built at gas stations, much stronger than ordinary gas tanks and tightly machined, so gas does not escape. Even under compression, CNG has a much lower energy density than gasoline. This requires special $6,000 tanks that must still take up more space. In passenger vehicles they will devour almost all the trunk space, which is why vendors are concentrating on long-distance tractor-trailers.

As a result, there always seems the chance that some liquid derivative of methane is going to come along and push CNG off the market. Methanol has been a prime candidate since it is already manufactured in commercial quantities for industrial purposes. M85, a mixture of 85 percent methanol and 15 percent gasoline, is legal in the United States, but has not been widely adopted.

Now a new candidate has emerged in the long-distance truck competition — dimethyl ether or “DME.” Two methane ions joined by a single oxygen molecule, DME is manufactured from natural gas and has many of the same properties as methanol. It is still a gas at room temperature but can be stored as a liquid at four atmospheres or -11o F. It can also be dissolved as a gasoline or propane additive at a 30-70 percent ratio. In 2009 a team of university students from Denmark won the Shell Eco Marathon with a vehicle running on 100 percent DME.

So is it practical? Well, we’ll soon find out. Volvo has just announced it will release a version of its D13 truck in 2014 that runs on DME. At the same time, Volvo pushed back the launch of its natural gas version of the same line, meaning it may be changing its mind about which way the technology is going to go. In case you haven’t been keeping abreast, Volvo is now the largest manufacturer of heavy trucks in the world, having acquired Mack, America’s oldest truck company, in 2000.

So does that mean that CNG may turn out to be a dead end and Clean Energy Fuels is going to get stuck with a lot of unused compressor pumps? Well, hold on a minute. Technology does not stand still.

Last week at the Alternative Clean Transportation Expo in Long Beach, Calif., Ford and BASF unveiled a new device for the Ford F-450 CNG fuel tank. It’s called a Metal Organic Framework (MOF), a complex of clustered metal ions built on a backbone of] rigid organic molecules that form one-, two-, or three-dimensional structures. Lots of surface area is created, making MOFs porous enough to hold large amounts of gaseous material such as methane.

MOFs create the possibility that on-board CNG tanks will not have to operate under extremely high pressure or extremely low temperatures. Like a metallic sponge the high-surface material soaks gas right up, where it can be easily dislodged as well. According to BASF and Ford, the same amount of natural gas that requires 3,600 pounds per square inch (PSI) can be stored in an MOF tank at close to 1,000 PSI. That makes a big difference when it comes to designing an automobile.

So does that mean natural gas is going to be able to hold its own against DME and other liquid competitors? Well, wait a minute, there’s still more. Not only is MOF technology good at storing methane, it also works with hydrogen! That means the hydrogen-fuel cell — still the favorite among Japanese manufacturers — may be able to work its way back in the game as well.

In fact, Ford isn’t playing any favorites. Equipped with its new MOF tanks, the F-450 will offer drivers a choice of seven — that’s right, seven — different fuel options using the same internal combustion engine. “Ford has no idea which of these fuels will make the most sense,” Ford’s Jon Coleman told Jason Hall of Motley Fool. “So we need to build vehicles that have the broadest capability and the broadest fuel types so our customers can choose for themselves.”

That’s the name of the game. It’s called Fuel Freedom.

An oil-drilling sing along, to the tune of “Politics and Polka”

Correlation or causation, correlation or causation
Misleading numbers, mistaken assumptions. Who will be the joker?

Okay, I am neither poet nor composer. I can’t even sing. But Fiorello Laguardia was an early hero from the time I met him in my sixth grade history books, and the musical Fiorello! was good fun.

Mayor Laguardia would be amused and bemused by recent articles suggesting that the Monterey Shale isn’t what it was cracked up to be a year or two ago. The story lends itself to his famous encounters with comic books. Despite earlier media hype, its development will not lead to economic nirvana for California and could well lead to real environmental problems.

Why were the numbers that were put out by the oil industry just a couple of years ago wrong? Maybe because of a bit of politics and polka! The articulated slogan concerning oil independence from foreign countries mesmerized many who should have known better.

Similarly, why, while once accepted by relevant federal agencies, have the production numbers concerning the Monterey Shale been recently discounted by the same agencies (EIA) and independent non-partisan analysts? Quite simply, they now know more. Succinctly, it’s too expensive to get the oil out and the oil wells, once completed, will have a comparatively short production life.

Drilling an oil field that is located under flat land is easier than drilling for very tight oil — oil that lies underwater or under a combination of flat as well as hilly, rolling, developed, partially developed or undeveloped areas known for their pervasive, pristine, beautiful environment. Further, the geological formations in the Monterey Shale area are a victim of their youth. They are older than Mel Brooks, but at 6-16 million years, the Monterey Shale is significantly younger than The Bakken. Shale deposits, as a result, are much thicker and “more complex.” According to David Hughes (Post Carbon Institute, 2013), existing Monterey Shale fields are restricted to relatively small geographic areas. “The widespread regions of mature Monterey Shale source rock amendable to high tight oil production from dense drilling…likely do not exist…” “… While many oil and gas operators and energy analysts suggest that it is only a matter of time and technology before ‘the code is cracked’ and the Monterey produces at rates comparable to Bakken and Eagle Ford,” this result is likely is not in cards…the joker is not wild. “Owing to the fundamental geological differences between the Monterey and other tight oil plays and in light of actual Monterey oil production data,” valid comparisons with other tight oil areas are…wishful thinking. Apart from environmental opposition and the costs of related delays, the oil underwater or underground in the Monterey Shale is just not amenable to the opportunity costing dreams of oil company CEOs, unless the price of oil exceeds $150 a barrel. According to new studies from the EIA, the recoverable reserves, instead of being as it projected earlier from 13.7 to 15.4 barrels, will be closer to 0.6 barrels.

If you believe in “drill, baby, drill” as a policy and practice, the cost/price conundrums are real. Low costs per barrel for oil appear at least marginally helpful to consumers and increases in oil costs seem correlated with recessions. Increased production of tight oil depends on much higher per barrel prices and, in many instances, increased debt., Neither in the long term is s good for the economic health of the nation or its residents.

Breaking the strong link between transportation and oil (and its derivative, gasoline) would make it easier to weave wise policy and private-sector behavior through the perils of extended periods of high gasoline prices and oil-related debt. Expanding the number of flex-fuel vehicles (FFVs) through inexpensive conversion of older cars and extended production of flex-fuel vehicles by Detroit would provide a strong market for alternative transition fuels and put pressure on oil companies to open up their franchises and contracts with stations to a supposedly key element of the American creed-competition and free markets. The result, while we encourage and wait for renewable fuels to reach prime time status, would be good for America, good for the environment and good for consumers.

Clean Energy Fuels sees daylight ahead

Wall Street was abuzz last week as Clean Energy Fuels, the leading supplier of natural gas for use in delivery and heavy-duty trucks, jumped 11 percent in one day after a long slump in which investors were questioning its business model.

“We’re at the very beginning of a major shift to natural gas for trucking – a shift that could take a decade before the growth slows – and Clean Energy Fuels is the leader in the market,” added Jason Hall of Motley Fool, who had been skeptical of the company in the past but is now turning enthusiastic.

“Natural gas vehicles are here to stay,” added James E. Brumley on SmallCap Network, in one of the many enthusiastic endorsements the company received last week. “So Clean Energy Fuels is very much a right-time, right-place idea. It’s not just that the company is the biggest and the best at what it does. There’s a market of scale for what it has to offer.”

It hasn’t been easy. The company, the brainchild of legendary oilman T. Boone Pickens, seemed poised for growth last year but suddenly hit a sudden downdraft in January. Skepticism grew over whether compressed natural gas (CNG) or liquid natural gas (LNG) would be the best substitute for diesel in heavy-duty trucks. The debate is really inconsequential since the two are interchangeable – LNG for large-scale storage and transport with some use in the biggest rigs and CNG for fueling smaller commercial vehicles. Nevertheless, the controversy drove down CEF’s stock price 25 percent since the first of the year.

“Much of the conversation in the investor community over the past six months has been dominated by the false idea that CNG and LNG were competing fuels,” wrote Hall in a recent evaluation. “But while we’ve been arguing, Clean Energy Fuels has been opening stations for trucks across the country. And the company is a leader in both.”

Once again, it seems to have been a case of investors becoming absorbed in short-term focus while ignoring the long-term prospects of the company. True, Clean Energy Fuels has not yet delivered a profit but its progress in building infrastructure to enable us to use significant portions of our natural gas resources as a substitute for diesel fuel has been significant. Here’s what the company has accomplished so far:

  • Clean Energy Fuels has delivered 800 million gallons of CNG and LNG to light and heavy-duty trucks.
  • The company has built approximately 500 fueling stations across the country.
  • It has installed over 1,500 compressors for delivering CNG to vehicles worldwide.
  • It has two LNG production plants.
  • It has 60 LNG tankers making 5,000 deliveries every year.
  • It has two renewable natural gas plants producing bio-methane.
  • It has 39 major airport fueling stations.
  • It now fuels over 35,000 trucks, large and small, with CNG each day.

As you can see, this is no fly-by-night operation. Whether the company is profitable or not right now, Pickens is obviously in it for the long haul.

Clean Energy Fuels’ long-term goal is a “CNG superhighway” that will offer fueling stations to long-haul trucks along all the major interstates that crisscross the country. But its major success to date has been in servicing fleet vehicles for delivery companies and municipalities.

  • CEF currently services 230 trucks a day for UPS with big plans for expansion.
  • CEF has contracts with Owens-Corning, Lowe’s, Proctor & Gamble and other commercial establishments’ fleet owners for their delivery vehicles.
  • Garden City Sanitation of San Jose has converted 23 refuse trucks to natural gas using CEF’s services.
  • CEF will be fueling Kroger’s new 40-unit fleet of LNG trucks later this year.

Analysts believe that refuse and delivery fleets, especially those that are garaged overnight and can be refueled at a central CNG station, will become one of the company’s major markets.

CEO Andrew Littlefield just announced a loss in revenues for the first quarter of 2014 but said this was because of the expiration of the federal volumetric excise tax credit (VETC), which had provided $26 million in 2013. Overall, the trend is definitely upward:

  • LNG fuel deliveries increased 22 percent to 16.7 million gasoline gallon equivalents.
  • CNG deliveries increased 16 percent.
  • When the VETC is excluded, overall revenues were up 43 percent. 
  • Sales of Redeem, the company’s renewable bio-methane product, increased 45 percent.

Sean Turner, COO for Gladstein, Neandross & Assoc., a leading consulting firm for the development of alternative fuels, notes that the NGV market in the United States is actually larger than in countries such as Argentina and Pakistan, which have been at it for a longer time. “While North America might lag behind in the adoption curve of other countries, natural gas usage per vehicle is actually near the top worldwide,” he said. “This is because other countries have tended to employ NGVs for passenger cars, whereas the U.S is now concentrating on medium-sized and heavy-duty trucks.” And as T. Boone Pickens likes to point out, natural gas will be unrivaled in this marketplace since electric vehicles cannot produce the torque needed to power those long-haul vehicles.

Whether all this makes Clean Energy Fuels a hot stock again is something Wall Street will have to decide. But in terms of moving America toward greater reliance on homegrown natural gas, the news is all favorable.

Let freedom ring: Oil companies, capitalism and fuel choice

It’s a free county, ain’t it? Americans have many choices that are denied to citizens of other less-fortunate nations. But we forget how many decisions are made for us, sometimes out of necessity, such as paying taxes; sometimes out of greed, such as the monopolistic actions of oil companies in denying many Americans the ability to purchase alcohol-based fuels at their corner gas station. Try it someday! On your way home from work, on your shopping trip to your friendly supermarket or on your way to see a movie at your favorite theater, make a stop for fuel at a gas station. Make sure to have some gasoline in your tank, because it likely will take you a lot of time to find a gas station that sells E85 or even E15.

Now, I went to Harvard Law School for four days, before I decided that there were too many lawyers around and memorizing case studies was not my forte. But Harvard provides significant value added, apart from being near Harvard Square and Boston. I was exposed to terms and content related to antitrust, restraint of trade, collusion and monopolies. Now, I didn’t stay long enough to know whether those concepts applied to oil companies that restrict consumer choices of alternative fuel. Probably not, because I am sure, by now, one of my Harvard colleagues would have filed a well-reimbursed case to break open the fuel market to options like ethanol, methanol and more. But whether legal or not, oil companies deserve their comeuppance for limiting many of us who, too often, are required to use more expensive, environmentally harmful gasoline, instead of existing, safe, alternative fuels.

How do they do this? Well, if you are a gas station owned or franchised by an oil company, your contract and rules related to behavior often prevent you from adding a pump or adding to an existing pump to sell E15 or E85. As relevant, since oil companies generally require the stations they own to buy fuel from them, and since they don’t sell E15 or E85, adding a pump would be akin to waiting for the hereafter (and acting on faith that you will get there).

Wait, there is more! Every now and then an oil company wants to publicly show it is a bit beneficent (for image purposes), but don’t hold your breath with respect to proof that image and reality are the same. Sure, you might find an alternative-fuel pump near the rear side of the garage proximate to the men’s room, or, if you are lucky, on the side of the station near the air pump. Most oil-company-owned stations and franchisees are generally precluded from putting an alternative-fuel pump under the covered island or space out front. They also face restrictions on advertising alternative fuels as an available product and oil-company pricing limits competition from alternative fuels.

Congress has refused to enact open fuels legislation, which would require oil companies to open up their gas stations to other fuels. Ongoing efforts by public and private sector advocates, as well as nonprofit groups, to encourage policies that would convert older cars to flex-fuel vehicles and to encourage Detroit to build more FFVs could well lead to a large consumer market for alternative fuels and generate a positive market reaction among independent gas companies and, perhaps, even some smart oil companies. While I have been wading through the pros and cons of allowing oil companies to increase exports to other nations, I do believe that if increased exports are in the nation’s future, they should be approved only if the oil companies agree to require their stations and franchises to offer alternative fuels in a primary space alongside gasoline. A bit of tat for tat is in the public interest. Let freedom ring for consumer! Let capitalism mean competition for gasoline and alternative fuels at your nearby gas station! Oh, I forgot, alternative fuel station!

Right, wrong and indifferent — the AAA, oil and alternative fuels

My favorite automobile service group — the AAA — has once again treaded without fear or trepidation into analysis. Remember earlier, when it suggested that E15 harms engines, based on what looked like an oil-industry-generated study? The AAA’s methodology was weak and its conclusions suspect, a judgment supported by the EPA’s response. According to the agency, AAA’s conclusions were erroneous and based on a limited sample. EPA’s own findings were generated from a relatively large sample of cars, indicating that E15 is safe for most engine types and reaffirmed the wisdom of its approval of E15 usage.

I was surprised to find an article in Oil Price by blogger Daniel Graeber, based to a large degree on comments from AAA’s Michael Green suggesting that the oil shale boom has prevented gas prices from going higher than they are now. Graeber approvingly quoted Green, who said, “Sadly, the days of cheap gasoline may never return for most American drivers despite the recent boom in North American crude oil production.” Assumedly, Green meant that the cost of drilling tight oil will remain high and the costs per barrel of oil will follow suit.

Green apparently went on to indicate that political leaders, particularly, members of Congress who argue for a drill-baby-drill policy, are wrong to link more wells to significant price relief for folks who find gas costs a real problem.

The AAA is right when it suggests that, despite the oil shale boom and signs of increasing demand in America, refineries are sending increased amounts of oil-based products overseas. Understandably, their patriotism doesn’t extend to accepting a lower price for oil in the U.S. when they can get higher prices overseas.

The article appears inconsistent, when at one point it mentions that crude oil inventories are running above average, and later blames current exports for low supplies and low supplies for preventing a drop in prices at the pumps.

Both are correct in indicating sales of oil products abroad probably do have an effect on costs-up to now probably marginal. Certainly, if Washington extends export privileges, increased sales of oil abroad may have a more significant impact on consumer costs. More relevant, however, concerning gasoline costs at the pump, will be economic recovery in the U.S., investor speculation and the oil sector’s ability to manage prices.

Cheap oil has been, recently, and likely will be in the future, a fantasy. The cost of oil per barrel has hovered at around $100 and upward for an extended period, and drilling in shale is relatively expensive. Continuous exogenous and existential (don’t you like those words — they create great passion and emotion) threats from the Middle East and Eastern Europe, also, will likely tilt oil prices upward in the near future.

I would commend the AAA, assumed by many to be the leading advocate for automobile owners in the nation, for grasping the fact that the behavior of producers is likely to lead to higher gas costs and create burdens, particularly for low and moderate-income groups. Now with this knowledge, shouldn’t the AAA argue for breaking oil’s near monopoly on fuel? If the AAA was really interested in helping vehicle owners lower their cost of fuel, it might take the lead in arguing for choice at the pump. Wouldn’t it be great if they really stood up for more open fuel markets as well as alcohol-based transitional fuels, such as ethanol and methanol? Competition at the pump from flex-fuel vehicles, combined with conversion of older vehicles to flex-fuel cars would, over time, mute increases in gas prices and, at the same, time generate environmental benefits for a better America. Support for alcohol-based fuels is consistent with support for renewable fuels, if one is concerned about the environment and GHG emissions. Let’s bring them on as fast as we can. But let’s acknowledge that renewable fuels are not really ready yet for prime time. They are too expensive for many Americans and their technical limitations, particularly concerning electric batteries, are not yet coincident with the desires of most Americans.

Rin Tin Tin, RINs and the price of ethanol

Is the son or daughter of Rin Tin Tin alive and well? For a while I thought he or she was, while catching up on my reading over the weekend. I kept reading articles about RINs (Renewable Identification Numbers), their possible impact on the ethanol market and relatively high ethanol prices, despite the apparent weakening of the ethanol market. There seemed to be RINs and more RINs on every page I turned! Because I hadn’t slept for two nights, I couldn’t really focus on the contents of the articles, but only on the dog Rin Tin Tin and his offspring. How many of you have done that? Come on, be honest. Don’t make me feel bad!

I felt guilty after it became obvious that my focus on Rin Tin Tin resulted from a tired brain and eyes. I am back to the complex world of RINs today. (I had a bit of sleep).

Okay, you ask, “What the hell are RINs?” They are sort of a pass at reflecting company fulfillment of government mandates concerning biofuels. For this article, think ethanol! They are issued at the point of ethanol production or the purchase of the fuel by companies. They are approved by the EPA. They reflect a credit that verifies that the required amount of ethanol has actually been blended into gasoline. Succinctly, the Renewable Fuel Legislation, now the law of the land, mandates that a Renewable Identification Number (RIN) must be attached to every produced or imported gallon of renewable fuel in the U.S. One more thing, RINs are separated from the batch of renewable fuel when it is blended with gasoline. This fact indicates compliance with the law and Renewable Volume Obligations (RVOs). Credits, at this juncture, can be used for trading purposes.

In 2012, before the EPA’s Nov. 2013 proposal to change RIN quotas and lower requirements for ethanol, the price of RINs was very volatile. Initially, they ranged around 1 to 10 cents a gallon. By spring of 2013, however, they were around $1.

Why the price increase and what does it bode for the price of ethanol in the future? Initially, the RINs were thought of as a way to encourage refiners to produce renewable fuels, like ethanol, and to “pay” for credits if they don’t “play” by  meeting fuel targets.

Part of the volatility and increase in costs of RINs, probably, has to do with speculation by banks and other financial institutions. Thomas D. O’Malley, chairman of PBF Energy, indicated in a recent New York Times article that financial institutions “helped transform an environmental program into a profit machine…These things were designed to monitor the inclusion of ethanol in the gasoline pool…They weren’t designed to become a speculative item. For the life of me, I can’t see the justification for it.” Interviews with members of the financial community, conducted by the New York Times, seem to suggest agreement with O’Malley.

According to the Times, speculation in RINs “could have consequences for consumers. In the end, energy analysts say, the outcome will be felt at the gas pumps — as the higher cost of the ethanol credits get tacked onto the price of a gallon of gasoline.” The Times reports that the “credits, which cost 7 cents each in January [2013], peaked at $1.43 in July, and [were] trading for 60 cents” in September. Jordan Godwin in the Barrel Blog indicated that like RINs in 2013, ethanol prices in 2014 are downright wacky. “In a matter of less than two months, ethanol prices went from six-month lows to eight-year highs.” Godwin and others blame delayed returning train cars during the winter and constraints on supply and production. I would add speculation by Wall Street and uncertainty as to the impact and longevity of EPA’s new regulations concerning the reduced mandates for ethanol and other biofuels. It’s a dilemma for proponents of alternative fuels. Less speculation regarding trading, sustained predictable production and refinement of the distribution system, (along with avoidance by some retailers and blenders to price ethanol well over costs) would facilitate more competition with gasoline at the pump. More predictable competition and larger sales at the pump of E15 and E85 would generate more private-sector fixes to the ethanol supply chain as well as likely stabilize prices and, over time, lower them. In light of ethanol’s benefits to the nation, wise folks might be asked to find policies and stimulate market behavior that permit the American people to have it both ways.

Is butanol the next big thing in biofuels?

Fuel Freedom recently learned about a man named David Ramey who drove his 1992 Buick Park Avenue from Blacklick, Ohio to San Diego using 100 percent butanol, without making any adjustments to his engine.

Ordinarily this wouldn’t be big news. But with the EPA now considering cutbacks in the 2014 biofuels mandate, some producers of ethanol are starting to turn to butanol as a way of getting around the limitations of the 10 percent “blend wall” that is threatening to limit ethanol consumption. This could be another breakthrough in our efforts to limit foreign oil.

Butanol is the alcohol form of butane gas, which has four carbons. Because it has a longer hydrocarbon chain, butane is fairly non-polar and more similar to gasoline than either methanol or ethanol. The fuel has been demonstrated to work in gasoline engines without any modification to the fuel chain or software.

Since the 1950s, most butanol in the United States has been manufactured from fossil fuels. But butanol can also be produced by fermentation, and that’s where another opportunity for reducing our dependence on fossil fuels exists.

The key is a bacterial strain called Clostridium acetobutylicum, also named the Weizmann organism for pioneering biological researcher Chaim Weizmann, who first used it to produce acetone from starch in 1916. The main use for the acetone was producing Cordite for gunpowder, but the butanol, a byproduct, eventually became more important.

Once set loose on almost any substratum, Clostridium acetobutylicum will produce significant amounts of butanol. Anything used to produce ethanol — sugar beets, sugar cane, corn grain, wheat and cassava, plus non-food crops such as switchgrass and guayule and even agricultural byproducts such as bagasse, straw and corn stalks — can all be turned into butanol. (Of course, not all of these are economical yet.)

Given the modern-day techniques of genetic engineering, researchers are now hard at work trying to improve the biological process. In 2011, scientists at Tulane University announced they had discovered a new strain of Clostridium that can convert almost any form of cellulose into butanol and is the only known bacterium that can do it in the presence of oxygen. They discovered this new bacterium in, of all places, the fecal matter of the plains zebra in the New Orleans Zoo.

DuPont and BP are planning to make butanol the first product of their joint effort to develop next-generation biofuels. In Europe, the Swiss company Butalco is developing genetically modified yeasts from the production of biobutanol from cellulosic material. Gourmet Butanol, a U.S. company, is developing a process that utilizes fungi for the same purpose. Almost every month, plans for a new butanol production plant are announced somewhere in the world. Many refineries that formerly produced bioethanol are now being retrofitted to produce biobutanol instead. DuPont says the conversion is very easy.

What are the possible drawbacks? Well, to match the combustion characteristics of gasoline, butanol will require slight fuel-flow increases, although not as great as those required for ethanol and methanol. Butanol also may not be compatible with some fuel system components. It can also create slight gas-gauge misreadings.

While ethanol and methanol have lower energy density than butanol, both have a higher octane rating. This means butanol would not be able to function as an octane-boosting additive, as ethanol and methanol are now doing. There have been proposals; however, the proposals are for a fuel that is 85 percent ethanol and 15 percent butanol (E85B), which eliminate the fossil fuels from ethanol mixes altogether.

The only other objection that has been raised is that consumers may object to butanol’s banana-like smell. Other than that, the only problem is cost. Production of butanol from a given substratum of organic material is slightly lower than ethanol, although the increased energy content more than makes up for the difference.

Ironically, the EPA’s decision to cut back on the biofuels mandate for 2014 is now driving some refiners to convert to butanol, since its greater energy density will help it overcome the 10 percent “blend wall.”

“Michael McAdams, president of the Advanced Biofuels Association, an industry group, said butanol was a ‘drop-in’ fuel, able to be used with existing gasoline pipelines and other equipment because it does not have a tendency to take up water, as ethanol does,” The New York Times reported last October. “‘It’s more fungible in the existing infrastructure,’ he said. ‘You could blend it with gasoline and put it in a pipeline — no problem.’

“Butanol would also help producers get around the so-called blend wall, Mr. McAdams said…With the 10 percent limitation, ‘you don’t have enough gasoline to put the ethanol in,’ he said. ‘You don’t have that problem with butanol.’”

So here’s to butanol. It will be yet another big step in reducing our dependence in foreign fuels.