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Arctic Leaf

A Big Year for Natural Gas Vehicles

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“The NGV market experienced a growth spurt in late 2013, and that is expected to continue in early 2014, with new engineers and vehicles coming to market.”

That’s the conclusion of a very optimistic report issued by Navigant Research on the progress of natural gas vehicles – particularly NG trucks and buses – in the United States and the world.  (The report, sorry to say, costs $4000 but the executive summary can be seen online at http://www.navigantresearch.com/research/natural-gas-trucks-and-buses.)

“As the cost of oil climbs and emission from large diesel and gasoline engineers garner more scrutiny, fleets and governments are increasingly looking for alternative to fulfill their needs at lower costs and with lower emissions,” says the study.  “At the same time, new drilling techniques and new pipelines make natural gas a significantly more competitive vehicles than a decade ago.  The result is growing markets for medium duty and heavy duty NG trucks and buses.”

Indeed, the Navigant report does not anticipate an expanding market for natural gas vehicles in general but sees growth concentrated in the area of trucks and buses, particularly fleet vehicles for large corporations and municipalities.  The great advantages here are: a) vehicles can be bought in bulk; b) they can be fueled at central depots, and c) fleet vehicles tend to pile up the mileage, which means a quicker payback period from savings over gasoline.

In Palmdale, California, AT&T has converted its utility trucks to compressed natural gas in an effort to save money on fuel and cut down on carbon emissions.  “The vans are large enough to accommodate bulky gas canisters hidden beneath the floor,” reports Robert Wright in the Financial Times.  [http://www.ft.com/intl/cms/s/0/9f06bea8-69ea-11e3-aba3-00144feabdc0.html#axzz2osEhWAna]  The conversion costs $6,000 but operating costs will be reduced 10 cents per mile, meaning the initial investment will be recouped after 60,000 miles.  Most utility fleet vehicles hit that number within two years.

Some municipalities are even finding it worthwhile to switch to natural gas in smaller vehicles.  In Conway, Arkansas, the police department’s Chevy Tahoes are being converted to run on natural gas.  The effort is being promoted by Southwestern Energy, which will be building two CNG filling stations in the area.  Trussville, Alabama is scheduled to make the same conversion next year.

The switch to natural gas will receive a big boost in 2014 when Cummins Westport, a Connecticut company, introduces a 12-liter NG engine that is designed to sell between the existing 9- and 15-liter products.  “This will is expected to provide robust growth for the day cab market in North America,” says Navigant.  Volvo Trucks will also be taking aim at that market niche with a 13-liter LNG dual fuel engine.

Hovering behind all this is the effort by T. Boone Pickens’ Clean Energy Fuels to build a “natural gas highway” across America.  CLNE, which trades on the NASDAQ, plans to sell natural gas at truck stops along the nation’s interstate highway system.  The company is even planning to build its own liquid natural gas terminal in Jacksonville, Florida.

“Natural gas is a better transportation fuel than gasoline,” says the indomitable Pickens, who is engaged to be married for the fifth time at age 85.  “It’s cheaper, it’s cleaner and it’s a domestic resource.”

In fact the market is now getting so crowded that providers are starting to bump up against each other.  In the Northwest, Clean Energy is objecting to plans by Puget Sound Electric, Portland-based NW Natural and Spokane-based Avista Utilities to build filling stations for natural gas vehicles.  “We feel that because of their monopoly status, regulated utilities will have an unfair advantage entering the natural gas refueling market,” said Warren Mitchell, chairman of Clean Energy.   “Choices in the marketplace are a good thing,” responded Ben Farrow, of Puget Sound.  “We don’t want to compete unfairly.”

Nevertheless, despite all this activity in the United States, Navigant actually sees Asia as natural gas’s prime growth market.  By 2020 the report anticipates annual sales of 400,000 medium and heavy-duty trucks and buses, but the Asian Pacific will account for an astounding 76.2 percent of these sales while North America will provide only 12.7 percent and Europe 8.6 percent.  With 1.2 million NGVs on the road by that time, China and the United States will represent a combined 96 percent of the world market.

Compressed natural gas still has its problems.  Even when stored at 3,600 pounds per square inch, compressed gas takes up five times the space of a gas tank holding the same amount of energy.  This means that on a Chrysler Ram 2500 pick-up the tank still occupies nearly half the truck’s rear cargo bay.  Obviously, the bigger the truck or bus, the better it will be at accommodating this bulk.  But when it comes to ordinary passenger cars, finding room for the gas tank will be much more difficult.  That is why there is still only one NG passenger vehicle – a Honda Civic – on the road today.

Converting passenger vehicles to natural gas will probably require a liquid fuel.  Methanol and butanol, both of which can be made from natural gas feedstock, are likely candidates. But that still lies ahead. For now, the progress of CNG among heavy duty trucks and buses is an encouraging sign that we may be able to reduce our dependence on foreign oil.

Arctic Leaf

Are Hydrogen Cars the Future – Again?

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The hydrogen car may be on the road to another comeback – again.  At the annual auto show in Los Angeles last week, both Honda and Hyundai unveiled “concept cars” of hydrogen models they expect to be available by 2015.  As a result, the automobile press has been filled with stories its revived prospects.

“For a long time, hydrogen fuel-cell vehicles were seen as a tantalizing technology to help reduce society’s reliance on oil,” Brad Plumer wrote in the Washington Post. “But the vehicles themselves were seen as forbiddingly expensive. Not the pendulum may be swinging back.”

“Toyota made a decagon – the fuel-cell car is going to be a big part of our future,” wrote Bradley Berman in The New York Times, quoting Toyota spokesman John Hanson.  “Today Toyota is not alone,” he continued. “Four other carmakers – General Motors, Hyundai, Honda and Mercedes-Benz – are also promising fuel-cell cars in the next few years.”

The prospect of an automobile running on hydrogen is indeed perpetually attractive.  Hydrogen is the most common element in the universe.  When combined with free oxygen in the atmosphere it “combusts” to produce H2O – water.  There are no other “exhausts”. Thus hydrogen promises transportation absolutely clean of any air pollution.  No global warming, either.

But it isn’t quite that simple.  The question that always presents itself is, “Where do you get the hydrogen?” Although hydrogen may be the most common element on earth, all of it is tied up in chemical compounds, mostly methane and water.  Accessing this hydrogen means freeing it up, which requires energy.

Most of our commercial hydrogen is made by “reforming” natural gas, which splits the carbon and hydrogen in methane to produce carbon dioxide and free hydrogen. That doesn’t help much with global warming.  Another method is to split water through electrolysis. That is a much cleaner process but requires a considerable amount of electricity. Depending on what power source is used, this can produce zero or ample emissions. If it’s coal, the problem is made much worse. If it’s clean sources such as solar or nuclear, then there can be a strong advantage. In the 1930s, John Haldane proposed giant wind and solar farms that would generate hydrogen that could fuel all of society. Such facilities generating hydrogen for transportation would be a step toward such a utopia.

Even then, however, there are problems.  Hydrogen is the smallest molecule and leaks out of everything.  It is very difficult to transport.  Joseph Romm, a disciple of alternative energy guru Amory Lovins, was appointed head of hydrogen car development program under President Bill Clinton and worked for two years on its development.  In the end, he became very disillusioned and wrote a book entitled The Hype About Hydrogen, in which he argued that the idea really wasn’t practical. Romm is now one of the country’s premier global warming alarmists on ClimateProgress.org.

What has apparently brought hyfrohgen cars back to the forefront has been the substitution for platinum as the principal catalyst in the fuel cell process.

A fuel cell produces an electric current by stripping the electron off a hydrogen atom and running it around a barrier that is otherwise permeable to a naked proton.  The proton and electron are reunited on the other side of the barrier, where they combine with free oxygen to form water.  Until recently, platinum was the only substance that could fill this barrier function. This made fuel cells very expensive and raised the question of whether there was enough platinum in the world to manufacture fuel cells in mass production.  But several platinum substitutes have now been found, making fuel cells considerably cheaper and more accessible.

Estimates are now that next year’s Hyundai and Honda FCVs will sell for about $34,000, which puts them in the range of electric vehicles such as the Nissan Leaf and the Toyota Prius.  (The Tesla, a luxury car, is  priced in a much higher range,)  The problem then becomes fueling.  The FCV offers considerable advantages over the EV in that it has a range of 300 miles, comparing favorable to gasoline vehicles.  It can also be refilled in a matter of minutes, like gasoline cars, whereas recharging  an EVs can take anywhere from  20 minutes to three hours. But hydrogen refueling stations have not materialized, despite former governor Arnold Schwarzenegger’s promise of a “hydrogen highway.” At last count there were 1,350 EV recharging stations around the country but only ten hydrogen stations, eight of them In Southern California.

All this suggests that neither hydrogen cars or electric vehicles will be sweeping the country any time soon.  Neither the Chevy Volt nor the Nissan Leaf have sold well and are not expected to do much better next year.  If you read the press stories carefully, you soon realize that the reason the automakers are constantly cycling back and forth between electric and hydrogen cars is that they are trying to meet California’s requirements for low-emissions vehicles that will allow them to continue selling in the state. The problem, as always, is consumer resistance..  The automakers can manufacture all the hydrogen and electric cars they want but consumers are not always going to buy them, especially at their elevated price.  So the manufacturers will end up dumping them on car rental agencies where they will sit on the back lots, as did the first generation of EVs.

There is, however, one type of alternative that succeeded handsomely in California and had widespread consumer acceptance, although it is completely forgotten today.  That is methanol.  In 2003, California had 15,000 cars running on blends of up to 85 percent methanol.  Consumers were extremely happy and did not have to be dragooned into buying them.  Refueling was easy since liquid methanol slots right into our current gas stations. Cars that run on methanol can be manufactured for the same price as cars that run on gasoline.

The experiment only ended because natural gas, the main feedstock for methanol, had become too expensive.  In 2003, natural gas was selling as high as $11 per mBTU, making it more expensive than gasoline.  That was before the fracking revolution.  Today natural gas sells for less than $4 per mBTU and the industry is coping with a glut.  Methanol, which is already produced in industrial quantities, could sell for $1 less than motorists are now paying for energy equivalent in gasoline.  Moreover, methanol can be made from garbage and crop wastes and a variety of other sources that would reduce it’s carbon footprint.

Hydrogen and electric cars each have a future and it is good to see the auto companies keep experimenting with them.  But each has impediments that are going to be difficult to overcome. Methanol, on the other hand, is a technology that could be implemented today at a price that not require subsidies.  Even if it is only perceived as a “bridge” to some more favorable, low-carbon future, it is worth pursuing now.

 

Arctic Leaf

The Principal Impediment to Alternative Fuels Is – Government Regulation?

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In their path-breaking study, “Fuel Choice for American Prosperity,” the Energy Security Council carefully outlines the dilemma that our complete dependence on oil for transportation has created.

“It’s not the oil we import, it’s the price,” was the way they summarized it. As I outlined in a previous post the authors show how OPEC still controls the bulk of the world’s oil reserves and has not increased its output since the 1970s. As a result, even though we have increased domestic production dramatically and cut down on consumption, we are actually paying more for our oil imports than we were ten years ago. Why?  Because, OPEC is still able to manipulate the price to keep it at $100 a barrel. It’s not the black stuff we import that crimps our economy, it’s the price of oil we must accept from a monopolistic cartel.

So what to do?  Do we set up protests outside OPEC’s corporate offices in Vienna?  Do we bring an anti-trust suit in some world forum? People have actually tried such things and gotten nowhere. No, the only way to extricate ourselves from this market is to break the monopoly that oil has on our transportation system. If oil had competitors, it will start acting like any other commodity and respond to supply and demand. The key to breaking the OPEC monopoly, says USESC, is to develop alternative fuels.

When it comes to asking why we have not made more progress in developing alternative fuels, however, USESC has a surprising answer: government regulation. Government regulation? How can that be? I thought the government was doing everything it could to foster alternatives and try to lower our oil imports. Well, as usually happens when the government gets involved in manipulating a market, things quickly get complicated and murky. Here’s what has happened:

CAFE standards. When Congress first started setting corporate fleet average standards, responsibility was given to the Environmental Protection Agency. In retrospect, this was an odd choice, since EPA is more concerned with air pollution than reducing oil consumption. The Department of Energy would have been a more logical choice. This didn’t become visible in the 1980s when pollution concerns centered on the combustion products of sulfur and nitrogen. But now that carbon dioxide and global warming have become the principal concerns, the EPA has subtly changed its emphasis. As USESC points out; “CAFE’s initial energy security centric vision has been blurred by the desire to use the law to promote greenhouse gas emission reduction goals.”

In its latest regulatory effort, for example, the EPA will reward auto companies for introducing alternative fuels by applying a “multiplier” to their corporate fleet average beginning in 2017. Every electric and hydrogen fuel cell vehicles will count as two vehicles in the denominator of the corporate average, phasing down to 1.5 by 2021. For plug-in hybrid electric vehicles (PHEVs) and compressed natural gas vehicles (CNG), the multiplier will be 1.6, phasing down to 1.3.

All this seems fair enough. EVs and FCVs use no gasoline and plug-in hybrids are only partially dependent on oil. The real problem, however, is that flexible-fuel vehicles – cars that are designed to burn ethanol, methanol or gasoline – have only been given credit based on how much E-85 they burn in real-world driving. The auto manufacturers have used this to avoid making improvements in car efficiency. This is regrettable because flexible fuel engines burning either ethanol from homegrown corn or methanol derived from natural gas would be the best say to cut down on imported oil. Both methanol and ethanol are liquids and fit right into our current gas station delivery system. Compressed natural gas and electricity, on the other hand, require a whole new replenishing system. Yet the EPA remains wary of both ethanol and methanol because they produce carbon exhausts. CNG also produces carbon exhausts, of course, and EVs drawing power from coal or natural gas will produce exhausts at the power plant. The EPA has tried to compensate for this by adding upstream carbon releases for EVs and other alternative fuels but it does not do the same for gasoline!  In short, the whole multiplier system is a mess. The EPA would do much better just trying to reduce oil dependence rather than bringing carbon emissions into the equation.

Costs of converting to alternative fuels: One of the most important steps in developing alternative fuels is converting existing gasoline vehicles to run on other fuels.

In general, there are three types of conversions – switching a gasoline or diesel car to run solely on another fuel (dedicated), changing a vehicles to run on higher alcohol blends (flex fuel), or installing an additional fuel tank so that the vehicles can burn the competing fuel as well (bi-fuel). In American, however, onerous regulations and staggering costs of conversion has deterred consumers.

The study points out that installing a CNG tank in an American car costs $10,000 while the same tank in Europe can be installed for $3,800. The difference is the strength of the tank as dictated by the EPA. Of course we don’t want to be in a situation such as Pakistan where CNG cars are exploding due to poor tank quality.  But even in comparison to other developed countries, U.S. regulatory requirements are excessive. 

Taxing by volume instead of by energy content: The federal and state governments places taxes on gasoline and any other product used to propel trucks and automobiles. The logic here is that the money goes into special highway trusts that maintain the roads. But the tax is imposed by the gallon rather than by energy content. USESC maintains that this is discriminatory because methanol, ethanol and other non-gasoline products have less energy density and therefore require more volume for the same amount of energy. This is a fine point and might be disputed by the oil industry, which would say if ethanol and methanol have less energy content, that is simply their tough luck. Ethanol, on the other hand, has been exempted from the federal highway tax and most state gas taxes, which is what makes it economical to add to gasoline.

The ban on methanol: Finally, although the USESC report does not even mention it, the biggest regulatory impediment to alternative fuels is the EPA’s failure to authorize the use of methanol in gas tanks. Putting anything in your gas tank requires permission from the EPA because of air pollution considerations. Although methanol actually produces less nitrous oxides and less particulate matter than gasoline, the EPA has never given it an OK. Although methanol made from natural gas might be the best alternative for replacing gasoline, it is does not yet have EPA approval.

Changing any and all of these regulations would require a huge concerted effort by some constituency that had a strong material interest in pushing it through Congress. Unfortunately, there is no such group. The natural gas industry is not yet organized around the issue and is more concerned about defending fracking and opening up natural gas exports. T. Boone Pickens is pushing CNG for trucks through his Clean Energy Fuels but there is no similar effort to promote the use of natural gas in cars. The entire farm bloc is behind corn ethanol, of course, which is why it has been so successful. But there is no similar interest promoting methanol, which may be just as good an alternative or better.

Under these circumstances, the best alternative is to persuade the auto manufacturers to produce flex-fuel vehicles that can run on any fuel – natural gas, hydrogen, biodiesel, E85 (85% ethanol) or M85 (85% methanol). The adjustment would not add significantly to the price of a new car and would open up the field to all the competitors attempting to replace gasoline.

Let the best fuel win.

Arctic Leaf

Building the Natural Gas Highway: The Journey of Thousands of Miles Begins in Newport Beach

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California still is seen as the state that exports innovation, despite the fact that it has seen some tough economic times of late. In this context, I was pleased to see the recognition granted by the Orange County Register (Nov 6) to the Clean Energy Fuel Corporation, and its efforts to build the Natural Gas Highway. I was even more surprised to find out that the corporate offices were located near my own office. Clearly, the popularity of natural gas and its derivatives, ethanol and methanol, are on the uptake since the President’s State of the Union address indicating the nation’s economy and environment  would benefit if it weaned itself off oil and by implication gasoline. Even before Obama’s speech, there was a growing recognition among many Americans– including environmental and business leaders– that natural gas could become the core of a strategy aimed at reducing greenhouse gas (GHG) and other pollutants, lowering the costs of vehicular fuel, and reducing dependency on oil imports, thus providing funds for investment in the U.S. Clean Energy Fuels Corporation, located in Newport Beach, is making it easier for consumers to access natural gas for their vehicles. According to the story in the Register, it has invested more than $300 million in the last two years on natural gas fuel stations across the nation. Most of the more than 400 stations that they have developed and  offer only compressed natural gas (CNG), a fuel that works better for comparatively short trips ( e.g. buses, taxis, garbage trucks, short hall trucks, local consumers ). Current and future placement of stations will increasingly offer liquid natural gas (LNG). LNG works better than CNG for long distance trips. Are the leaders of the Clean Energy Fuel Corporation nuts?  Maybe they are…but I don’t believe so.  While, the Corporation has yet to turn a profit (apparently after 15 or 16 years), since going public in 2007, their market value is now more than 1 billion dollars. Their phones are ringing. Large retailing companies relying on trucks, long distance trucking companies, bus manufacturers, taxis and bus companies seem to be gravitating toward use of cheaper natural gas as a fuel. But these users and potential users need assurances that natural gas fuel stations will be reasonably accessible. Clean Energy Fuel aims to provide such assurances. Many respected financial analysts believe that the Clean Energy Fuel Corporation is on the cusp of and will benefit financially from the increased acceptance and growth of alternative transportation fuels, particularly natural gas. Assuming both the sizable price gap between oil and natural gas remains and the corresponding price gap between natural gas fuel and gasoline as well as between natural gas and diesel fuel stays relatively large; Clean Energy Fuel Corporation’s future looks bright. Yes, it will have rivals. Shell Oil, according to the Register article, apparently is going to start selling LNG at existing truck stops. Soundings that I have picked up from natural gas leaders, CEOS of businesses dependent on trucking and diverse investors suggest an evolving interest in developing both CNG and LNG fuel stations and the Natural Gas Highway. In this context, 22 states, under the bipartisan leadership of Governor John Hickenlooper (D) of Colorado and Governor Mary Fallin (R) of Oklahoma, have initiated a collaborative project to buy CNG outfitted cars from Detroit to replace old state vehicles, when their time passes. Detroit in turn has promised to develop a less expensive CNG vehicle for the participating states which could ultimately benefit consumers. Given recent projections of the market for natural gas fuel by government and reputable private and nonprofit groups and increased advocacy for alternative fuels by a coalition of environmental, nonprofit and business groups, I wouldn’t bet against Clean Energy Fuel’s future health. My hope, however, is that it and, indeed, its competitors add room for natural gas derivatives such as ethanol and methanol in their planned natural gas stations.  Apart from generating use by owners of flex fuel cars now in existence, their agreement to do so would encourage (the relatively inexpensive and easy) conversion of existing vehicles to flex fuel vehicles. Significantly, EPA has certified the use of E10 in all vehicles, E15 in vehicles after 2001 and E85 in approved flex fuel vehicles. Hopefully, EPA will soon certify methanol as well as approve an expanded list of conversion kits for existing older vehicles. These approvals are possible, if not probable, given the environmental, economic and consumer benefits of alternative fuels and the evolving politics of fuel. Allowing oil companies to sustain the very restrictive rules now governing the vehicular fuel market will continue to prop up America’s dependency on imported oil as well as support relatively high fuel costs and increased environmental degradation.   President and CEO Andrew Littlefair of Clean Energy Fuel indicated, “With cheaper, abundant fuel, a network of stations, [and] redesigned engines …the time for natural gas transportation has arrived.” I would add, the time for natural gas based ethanol and methanol has also arrived. I commend Clean Energy Fuel for its initiative in developing the Natural Gas Highway. The Company, borrowing from President John Kennedy, has begun an important journey of thousands of miles in Newport Beach. Contrary to (and paraphrasing) the poet Robert Frost, hopefully the road they are building will be very well travelled.  Maybe a couple of leisurely  lunches near the ocean in beautiful Newport Beach could convince my colleagues at Clean Energy Fuel  to consider working with producers of natural gas based ethanol and methanol as well as interested states and localities to  extend  the Natural Gas Highway to ethanol and methanol. It would be good for traffic and their bottom line, good for development of related commercial activities and, most important, good for America

Arctic Leaf

The U.S. and China on methanol: Two roads converge

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Nobel-Prize-winning chemist George Olah recently put methanol front and center again with a powerful Wall Street Journal editorial arguing for the conversion of carbon dioxide emissions from coal plants into methanol for use as a gasoline substitute in our car engines. Co-writing with University of Southern California trustee Chris Cox, Olah noted, “Thanks to recent developments in chemistry, a new way to convert carbon dioxide into methanol — a simple alcohol now used primarily by industry but increasingly attracting attention as transportation fuel — can now make it profitable for America and the world to reduce carbon-dioxide emissions.”

The authors argued that President Obama’s recently announced policy of mandating carbon sequestration for emissions from coal plants wastes a potentially valuable resource. “At laboratories such as the University of Southern California’s Loker Hydrocarbon Research Institute [founded by Olah], researchers have discovered how to produce methanol at significantly lower cost than gasoline directly from carbon dioxide. So instead of capturing and “sequestering” carbon dioxide — the Obama administration’s current plan is to bury it — this environmental pariah can be recycled into fuel for autos, trucks and ships.”

Olah, of course, has been the principal advocates of methanol since his publication of “Beyond Oil and Gas: The Methanol Economy,” in 2006.

To date, he has been recommending our growing natural gas supplies as the principal feedstock for a methanol economy. But the emissions from the nation’s coal plants offer another possibility.

This is particularly important since indications are that the Environmental Protection’s Agency’s assumption that a regulatory initiative will “force” the development of carbon-sequestering technology may be mistaken. A recent report from Australia’s Global CCS Institute said that, despite widespread anticipation that carbon capture will play a leading role in reducing carbon emission, experimental efforts have actually been declining.

The problem is the laborious task of storing endless amounts of carbon dioxide in huge underground repositories plus the potential dangers of accidental releases, which have aroused public opposition. Olah and Cox write, “By placing the burden of expensive new carbon capture and sequestration technology on the U.S. alone, and potentially requiring steep cuts in domestic energy to conform to carbon caps, the proposal could send the U.S. economy into shock without making a significant dent in global emissions… In place of expensive mandates and wasteful subsidies, what is needed are powerful economic incentives. These incentives should operate not just in the U.S., but in other countries as well.”

All this brings into stark relief the diverging paths that China and the United States have taken in trying to find some alcohol-based fuels to substitute in gas tanks. While Olah has been advocating a transformation to a methanol economy in this country, China is actually much further down the road to developing its own methanol economy. There are now more than a million methanol cars on the road in China and estimates show the fuel substitutes for 5-8% of gasoline consumption — about the same proportion that corn ethanol provides in this country.

In this country, the proposal has been that we derive methanol from our now-abundant supplies of natural gas. California had 15,000 methanol cars on the road in 2003 but curtailed its experiment because gas supplies appeared to be too scarce and expensive! Instead, the main emphasis has been on tax incentives and mandates to promote corn ethanol.

China has vast shale gas supplies and could benefit from America’s fracking technology. We could benefit strongly from China’s greater experience in developing methanol cars. The pieces of the puzzle are all there. Perhaps Olah’s proposal may be the catalyst that puts them all together.

Ironically, all this began with a Chinese-American collaboration in 1996. At the time, China had little knowledge or interest in methanol but was persuaded by American scientists to give it a try. Ford provided a methanol engine and China began ramping up its methanol industry and substituting it for gasoline. As a result, China is now the world’s largest producer of methanol, with about one-quarter of the market.

A year ago the Chinese national government was about to mandate a 15% percent methanol standard for gasoline when it ran into opposition from executives in its oil industry. Those leaders have since been deposed, however, and the 15% mandate may go ahead this year. In the meantime, provincial governments  have developed their own standards, with the Shanxi province west of Beijing in the lead.

Ironically, because methanol is only half the price of gasoline, many local gas stations are diluting their gasoline with methanol anyway in order to shave their costs. As a 2011 Energy Policy article by Chi-jen Yang and Robert B. Jackson of Duke University’s Nicholas School of the Environment reported, Private gasoline stations often blend methanol in gasoline without consumers’ knowledge… In fact, its illegal status makes methanol blending more profitable than it would be with legal standards. Illegally blended methanol content is sold at the same price as gasoline. If legalized, standard methanol gasoline would be required to be properly labeled and sold at a lower price than regular gasoline because of its reduced energy content. Such unannounced blending is now common in China.”

So both countries are feeling their way toward a methanol economy. As Olah points out, the problem in the U.S. is that the various advantages given to ethanol have not been extended to methanol.One means of addressing this inequity would be for Congress to pass the bipartisan Open Fuel Standard Act of 2013, which would put methanol, natural gas, and biodiesel on the same footing as ethanol (but without subsidies and without telling consumers which one to choose) for use in flex-fuel cars.

In China, the concern is about coal supplies but this could be alleviated with help from America’s fracking industry or by implementing Olah’s new technology for tapping coal exhausts.

Either way, the pieces are all there. It may be time to start putting them together.

Arctic Leaf

Robert Rapier loves methanol

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Robert Rapier – “R2” as he calls himself in good scientific notation – is one of the smartest people out there when it comes to energy. A master’s graduate in chemical engineering from Texas A&M University, Rapier is chief technology officer and executive vice president for Merica International, a renewable energy company. He also writes a regular column at EnergyTrendsInsider.com.

And he is a big enthusiast of methanol.

In a series of recent columns, Rapier has made a strong case that methanol is our best option for replacing foreign oil. He believes it can be done cleanly and in a way that also reduces carbon emissions. Unfortunately, one of the biggest impediments, according to Rapier, is the huge political momentum behind corn ethanol, which he regards as an inferior fuel. He is also highly critical of the biofuels effort, which has attracted so much attention in the form of venture capital from Silicon Valley.

“You can buy methanol today for around $1 per gallon,” he said. “This is a big, well-established business that does not receive heavy subsidies and government support as ethanol does. On a per BTU basis, unsubsidized methanol costs $17.61 per million BTUs. You can buy ethanol today – ethanol that has received billions in taxpayer subsidies – for $1.60 per gallon. On a per BTU basis, heavily subsidized and mandated ethanol sells for $21.03 per million BTUs.”

Yes, you read that correctly. We are paying 20% more for ethanol, enabled via highly paid lobbyists, heavy government intervention, taxpayer funds and protectionist tariffs than we are for methanol that has long been produced subsidy-free.

Unfortunately, the decision to mandate ethanol consumption while ignoring methanol has been based much more on politics than on the two fuels comparative advantages. “The fact is, methanol simply has not had the same sort of political favoritism, but is in [Rapier’s] opinion a far superior option to ethanol as a viable, long-term energy option for the world.”

Where biofuels are concerned, Rapier states that the effort has always been predicated on the assumption that we will eventually switch from corn ethanol to much more abundant, non-food cellulosic feedstocks such as switch grass. We just have to wait until somebody comes up with a way to break down cellulose. What investors do not seem to realize is that techniques for breaking down cellulose have been around since the 19th century. They just have proved to be too expensive.

But “high costs have never been a deterrent for Silicon Valley entrepreneurs who wielded Moore’s Law as the solution to every problem. In their minds, the advanced biofuel industry would mimic the process by which computer chips continually became faster and cheaper over time. But advanced biofuels amounted to a fundamentally different industrial process that was already over 100 years old. A decade into this experiment it is clear that Moore’s Law isn’t solving the cost problem.”

(Actually, if you read George Gilder’s latest book, “Knowledge and Power,” you would realize that mathematicians such as Claude Elwood Shannon and John von Neumann have determined that information as an entirely separate entity from energy and matter. Moore’s Law applies only to information, not matter and energy.)

Rapier says biofuels will never succeed until the effort at developing them is redirected into producing methanol rather than ethanol once again:

For methanol, we can produce it from biomass via a similar process to how it is produced for $1 per gallon today. There are numerous biomass gasifiers out there. Some are even portable. They do not require high fossil fuel inputs and they utilize a much larger fraction of the biomass. They aren’t limited to cellulose. They gasify everything – cellulose, hemicellulose, lignin, sugars and proteins – all organic components. And if there is also a heating application, the combined heat and fuel or power efficiency of a biomass to methanol via gasification route is going to put cellulosic ethanol to shame. In any case, the efficiency of biomass gasification to methanol is going to put cellulosic ethanol to shame, because it doesn’t have to deal with all of that water present in the ethanol process.

Altogether, Rapier argues that methanol has a much broader potential feedstock, is easier and cheaper to produce and could be manufactured in much larger quantities than corn ethanol. And this doesn’t even consider the possibility of synthesizing it from our superabundant supplies of natural gas. The problem is that “methanol doesn’t have a big lobby and 42 senators from farm states it can count on for perpetual support.”

At Fuel Freedom Foundation, we believe we should pursue all these options – ethanol, biofuels, compressed natural gas (CNG), liquefied natural gas (LNG) and electric cars. They all offer the possibility of reducing the $350 billion we shell out each year for imported oil. But we can’t help but admire Rapier’s observation that the methanol option is greatly underappreciated. The reasons are: 1) the EPA restrictions that make it illegal to use in car engines and 2) the lack of any large constituency such as the farm lobby that stands to gain from it. For that reason alone we’re very encouraged by Rapier’s writings and look forward to more in the future.