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Outnumbered 100-to-1, Methanol Is Upbeat

“Why is it that we hear every day some new story about Elon Musk’s electric car, about Clean Energy Fuel’s efforts to build a CNG highway, or about some laboratory breakthrough that is at last going to bring us cellulosic ethanol, yet with methanol now cheaper than gasoline, you still never hear anything about it?”

That’s the question I posed to the three-member panel while serving as moderator for the wrap-up session at the 2014 Methanol Policy Forum in Washington last week.  The sponsors were the Methanol Institute, the Institute for the Analysis of Global Security (IAGS) and the Energy Security Council.

Anne Korin, co-director of IAGS, who earlier had moderated an even bigger panel that included former U.S. Senator J. Bennett Johnston, former National Security Advisor Robert McFarlane and former Ambassador to the European Union Boyden Gray, had a very unusual answer.  “If I may be permitted to be a bit cynical here,” she said, “I think the reason may be because methanol doesn’t require any subsidies.”  The implication, of course, is that those who come to Washington begging for money receive a lot more attention from Senators and Congressmen than those who don’t.

The question of politics versus economics had been raised at the outset of the daylong conference by Korin’s co-director at IAGS, Gal Luft, in his opening remarks.  “We’ve all heard this business about the circular firing squad and how the various alternatives to foreign oil shouldn’t be fighting each other,” he told the audience of about 400.  “But you have to acknowledge the importance of what goes on in Washington.  You can’t just talk about production you need money.  If you’re not at the table, that means you’re probably on the menu.

Luft showed a chart illustrating that while corn ethanol production exceeds methanol production by a factor of only 5-to-1 (14 billion gallons/year as compared with 2 bg/yr), the amount of money spent lobbying for ethanol is 50-to-1 (less than $100,000 vs. $5 million).  “When you add in the politics of the farm belt, it’s probably closer to 100-to-1,” he added.

So was anyone discouraged?  Not at all.  The news from industry executives is that methanol production is ramping up everywhere due to the bonanza of the fracking revolution.  It seems like only a matter of time before the idea of replacing large portions of our fuel imports with domestically produced methanol begins to command attention.

“In the past decade we closed down five methanol plants in the U.S. and moved them all to China,” John Floren, CEO of Methenex told the gathering of 400 at the Capital Hilton.  “The price of gas had become just too high.  Now we’ve moved two plants back from Chile and are looking at a third relocation.  We’ve got 1000 people working on our Louisiana site.  The chemical industry is starting to build as well.”

Tim Vail, the CEO of G2X, another methanol producer, had a similar take.  “The U.S. is a great place to invest right now,” he told the audience.  “The argument was always that you had to go to the ends of the earth to build methanol plants because that gas wasn’t available here.  Now all that has changed.  Our big worry is labor shortages but the construction industry is responding to our needs.  It takes away a lot of anxiety about having your assets appropriated by other countries.  China may seem like a good place to invest, but can you really trust the rule of law?”

Philip Lewis, chief technology officer of Zero Emission Energy Plants (ZEEP) was equally upbeat.  “I think the whole shale thing is being underestimated,” he said at the close of the morning session.  “It’s another industrial revolution.  And it won’t happen anywhere else because we have the thing that makes it work – private ownership of the resource.  In France, the government owns all the mineral rights and no one wants drilling on their land.”

But governments do have control over other things in this country and there was some questioning of whether federal agencies will be receptive to methanol as a fuel substitute or additive.  Matt Brusstar, deputy director of the EPA’s National Vehicle and Fuel Emissions Laboratory, claimed that his agency had been in the lead of methanol development for 30 years.  “Charlie Grady, who was in our department, was a big supporter of methanol,” said Brusstar.  “He even wrote a book about it.”  (Unfortunately, a Google search for Charlie Grady and methanol turns up no mention of Grady or his book.)  Patrick Davis, the director of the Fuel Cell Technologies Office in the Department of Energy, was even less encouraging.  “The Office of Science does not currently have any projects to create methanol as an end fuel,” he said.  “It could take a decade to sell enough methanol-compatible vehicles before a widespread distribution network would be feasible.”

When I queried Brusstar about Robert Zubrin’s documentation of the multi-thousand-dollar fines that the EPA is imposing for unauthorized conversions of engines to methanol, [See “Making the Case for Mars and Methanol,” Feb. 11] several government officials, plus Fuel Freedom Foundation director of research Mike Jackson, argued that faulty conversions can increase air pollution.

Despite the notable lack of enthusiasm from government agencies, however, there was a strong sense among the rank-and-file that methanol may be about to find a place in the sun.  “This is a much bigger crowd than we’ve ever had,” said one veteran of previous conferences.  “It’s a very exciting time for methanol.”

 

 

 

 

 

 

 

 

 

 

 

 

 

Can New Catalysts Turn the Corner for Methanol?

The concept of converting our abundant natural gas supplies into liquid methanol in order to replace oil in our gas tanks has had trouble gaining traction for several reasons, all of which are about to face change.

The first reason is that most of the attention towards additives has been focused on ethanol made from corn. Driven by highly specific government mandates, corn ethanol — which now consumes 45 percent of the country’s corn crop — has taken up whatever role industrial methanol might have been chosen to play as a gasoline additive.

Secondly, there’s the problem of the Environmental Protection Agency. Not only has the EPA not approved methanol for gas tanks, the organization actually imposes huge fines on anyone who converts a gasoline engine to methanol without its permission.

The third, and less distinguishable explanation for methanol’s difficult implementation, is that the whole idea has never been very sexy. Methanol has little to do with the “Cutting Edge” or the “New Age Economy.” The manufacturing of methanol is a 60-year-old process practiced doggedly by dozens of industrial facilities around the world. They produce 33 billion gallons a year at the reasonable price of $1.50 per gallon; the energy equivalent of $2.35 gas. Meanwhile, Elon Musk seems to announce a new milestone for the Tesla, or some “breakthrough” in battery technology or cellulosic ethanol emerging from the university laboratories each week, making methanol appear rather plain-Jane and old fashioned. In effect, the solution to our gas tank woes has been hiding before us in plain sight.

Now an announcement from the Scripps Howard Research Institute and Brigham Young University may change everything. In a paper published last week in Science, a team led by Roy Periana of the Scripps Florida Center and Professor Daniel Ess of Brigham Young University say they have found catalysts made from the common elements of lead and thallium that facilitate the conversion of gaseous methane to liquid methanol, potentially making the process even cheaper and more accessible.

The hydrogen bonds in the alkanes (methane, ethane, propane, etc) are among the strongest in nature. To break them involves a heat-driven process invented in the 1940s that is conducted at 900 degrees Celsius. For more than two decades, the Scripps team has been looking for catalysts that would shorten this heat requirement. In the 1990s they came up with a series of catalysts employing platinum, palladium, rhodium and gold, but quickly realized that these elements were too rare and expensive for commercial application. So it was back to the drawing boards in search of something more useful.

Last week in Science they reported success:

The electrophilic main-group cations thallium and lead stoichiometrically oxidize methane, ethane, and propane, separately or as a one-pot mixture, to corresponding alcohol esters in trifluoroacetic acid solvent.
The process reduces the heat requirement to only 200 degrees Celsius, which introduces enormous potential for energy savings. That “one-pot” notation is also crucial. Methane, ethane and propane all come out of the Earth together in natural gas. Currently, they must be separated before the heat-driven process can begin, With the new catalysts, no separation will be necessary. This means that methanol could become significantly cheaper to harvest than it already is. More importantly, these findings signify that methanol conversion will be able to weather the inevitable price increases that will result as demand for natural gas supplies multiplies.

Periana says the process is three years from commercialization. Reports Chemical & Engineering News:
The team is in discussion with several companies and entrepreneurs and would ideally like to jointly develop the technology with a petrochemical company or spin off a startup.

Periana also claims that “Initial targets would be higher-value, lower-volume commodity chemicals such as propylene glycol or isopropyl alcohol directly from propane.” He told reporter Stephen Ritter:

The next target could be to develop lower-temperature processes for higher-volume chemicals, such as converting methane to methanol and ethane to ethanol or ethylene as inexpensive sources for fuels and plastics.

An enormous portion of the world’s energy consumption is still tethered to oil, particularly the transportation sector, where oil constitutes 80 percent of consumption. As oil becomes more and more difficult to find, natural gas use is escalating. In addition, 25 percent of the world’s gas is still flared off because it has been uneconomical to capture. All this could change rapidly if a low-cost conversion to methanol becomes a reality. Reuters grasped the implications of this development when it reported that the new catalytic processes “could lead to natural gas products displacing oil products in the future.”

Are We Entering the Age of Batteries?

Last week in Houston, Secretary of Energy Dr. Ernest Moniz told CERA Conference attendees that storage batteries may be the next big energy breakthrough.  “It’s pretty dramatic,” he said.  “The research is moving very, very fast.”

Indeed, if you’re looking for “energy breakthroughs” on the Internet these days, most of the hits are likely to turn up something new about “flow batteries,” “ten times the storage capacity,” or some new cathode material that dramatically improves the performance of lithium-ion batteries.

So where do we stand in this energy revolution now, and what are the possibilities that any of these breakthroughs are likely to lead to real improvements in our attempts to wean ourselves off traditional energy resources like fossil fuels?

A good place to start is “Next Generation Electrical Energy Storage: Beyond Lithium Ion Batteries,” a panel put together for last February’s meeting of the American Association for the Advancement of Science in Chicago.  Three experts – Haresh Kamath; of the Electric Power Research Institute, Mark Mathias; of General Motors, and Jeff Chamberlain; of Argonne National Laboratory – discussed the latest developments in the industry.

All three panelists agreed that battery research is progressing along two separate tracks:

1) lithium-ion batteries that power most consumer electronic devices are now being scaled up for electric vehicles; and

2) larger and more durable conventional batteries for the storage of grid-scale electricity.

Despite whatever hopes Elon Musk may have that his new “Gigafactory” will be able to address both of these markets at the same time, that does not seem likely.  “Lithium-ion just doesn’t have the durability that we’re looking for in the utility industry,” Kamath of EPRI told the audience.  He continued:

I was doing cable research one time and we had a model for a product that would last 40 years.  The utilities looked at it and said, `Could you try for 60 or 80?’  The utilities are looking for things that last a long, long time.’ said Kamath.

“There’s a lot of experimenting going on,” Kamath added, “but everything that is on the grid right now is a demonstration.  No one has yet come up with a sustainable business model.”

With electric cars, on the other hand, the challenge will be in equipping batteries with enough energy density so that their weight does not load down the vehicle to the point of being counterproductive.  “The standard measure is that you need 100 kilowatt-hours of power to drive a mid-sized vehicle 300 miles,” said Mathias, who works at GM’s electrical storage research and development project.  He explained.

If you get up in the density range of 350 Watt-hours per kilogram, you can make it.  But current batteries are operating at around 150 Wh/kg, which gives them a range of 125 miles.  The best we can project is that they can achieve 225 Watt-hours per liter, which still leaves them short. (Mathias).

“Fuel cells operating on hydrogen actually do a much better job at this point,” he added.  “They can now get us up in the 300-mile range.  We regard them as electric vehicles as well.  It’s just that you generate the electricity on board.”

Then there’s the matter of cost.  Capital costs for lithium-ion batteries quickly rise into the $20,000 range.  Fuel cells cost only $6,000 and gas-electric hybrids, $4,000.  “The good news for EVs is that fuel costs are only about one-third that of gasoline,” said Mathias. “Over a span of 100,000 miles, a gasoline engine will cost you $10,000 in fuel.  A hydrogen fuel cell vehicle will cost only $6,000 and a pure EV, $3,333.”  Still, that’s a long time to wait and a long way from complete cost recovery.

Refueling time is also a bit of a problem.  “When you pump gasoline into your car, you’re actually adding range at a rate of 150 miles per minute,” said Mathias.  He went on to say:

With hydrogen fuel, it’s 100 miles-per-minute, which is acceptable. But even with the new 120-kW superchargers, you can only add mileage to an EV at a rate of 6 miles per minute.  If you take a long- distance trip, you’re going to spend 20 percent of your time       recharging. (Mathias)

Overall, Mathias was not overly optimistic about further improvements.  “There’s not much on the horizon,” he concluded.  He was more optimistic about hydrogen cars.

Chamberlain, of Argonne National Laboratory, is part of a $120 million program funded by the Department of Energy that is aimed at developing batteries with five times the current energy density at 1/5th the cost within five years.  “That’s a very ambitious goal,” he told the audience, “but we feel that’s what’s needed to transform the transportation sector.”  A long chain of national and university laboratories are involved in the project.  Of course, government goals and mandates are just that – projections that may or may not come true.  Steve Jobs was good at inspiring his cast to pursue seemingly impossible goals but the federal government does not always have the same success.

So far, the research has involved searching the periodic table for more candidates.  “We’re not sure what we’re going to come up with,” said Chamberlain, elaborating:

We’ve decided that capacitors will never help us reach our goal.  The charge dissipates too quickly.  So we’re exploring other materials.  It may involve a metallic anode and a suspended-particle cathode.  If you move to magnesium or aluminum, you’re releasing two electrons  instead of one.  But zinc-air and lithium-air doesn’t get you there               because they simply don’t have the power.”  (Chamberlain)

Chamberlain said that a lot is already known about lithium-ion.  “We may be able to get two times what we have now.”  He had to agree with Mathias that no other significant developments are on the horizon right now.

Mathias warned against new reports that are constantly announcing progress at the material level.  “We often realize right away that they’re not going to work,” he said.  “It’s not worth the manufacturing dollars.

Overall, the takeaway from the panel was that Tesla has its work cut out for it.  Progress on electric vehicles will be tough.  The panelists agreed that natural gas vehicles make a lot of sense.  “The problem is you don’t really solve the CO2 problem,” said Mathias.  He did express confidence that battery research would eventually pay off in the end.  “All this progress will eventually be harvested at the hybrid level,” he said.  “It may not lead to pure electric level, but there is going to be a lot of improvement in hybrids.”

Khrushchev, Gorbachev, Putin , Ukraine and Oil

How many of you have ever been to Russia? It is a fascinating place filled with fascinating people. While in Russia facilitating an Aspen Global Forum of U.S. and Russian leaders,  I visited Nikita Khrushchev’s grave. He lies under six feet of earth — probably  banging his shoe and confessing that he still wishes he could have incrementally changed Russia.  He was not Gorbachev, but neither was he Rasputin.

On top of his grave was a very attractive gravestone. One half was white, the other half black. I asked the workmen what it meant.They explained the contrast by indicating that Khrushchev was part evil doer of black deeds, but also in part a good man who wanted to change Russia.

The gravestone seems to fit the current situation in Russia. It is a place of great thinkers, great writers, great dancers, great scientists and decent people, but it is also the land of Putin whose modus operandi is often dark and destructive. Putin is no Gorbachev!

In the present Ukrainian situation, the dark and dangerous side of Russian leadership is visible. Currently proposed Western sanctions are not persuasive. Paraphrasing, we won’t come to the G8 meeting in Sochi  and we won’t have any more relationships with your military are not earth shattering.Trade limits or sanctions, if announced, may hurt, but Russia’s ability to cut off natural gas to Europe and the Ukraine as a counter measure will marginalize any effort to develop meaningful  responses. Obama and his colleagues do not want to engage in military sanctions in order to counter Putin’s new version of our own Monroe Doctrine.

Speaking of energy, oil, and natural gas, most energy related U.S and Russian executives have not been told to slow down or avoid searching for new businesses in Russia. As a recent CNBC report indicated, “ the U.S. produces more natural gas than any other nation and Russia is now the biggest oil producer.” U.S. firms are seeking an increased stake in  Russian oil, which is light and good for gasoline.  U.S. companies are even building the rigs for Russian drillers. While the U.S. imports relatively little oil from Russia, this could change depending on price. Russia is still among the top five importers of oil to the U.S.  In light of the Russian actions in Crimea, the price of gas at the pump is expected to head up again. The stakes are high, and at the present time, no government leader in either nation has seriously suggested interfering with the export and import trade network between U.S. and Russia.

I suspect that the U.S. and Russia will eventually agree to a deal on some sort of a pullback in Crimea and the possibility of a monitored arrangement concerning Russians living in both Crimea and the eastern part of Ukraine. I could be wrong. Russia could insist on remaining in or even annexing the Crimea and it could invade part of Eastern Ukraine.  I pray neither happens!

Would we react militarily in some form or manner, as we have at times in the Middle East in order to secure oil and gas supplies for the Ukraine and other needy western nations? I think not!  Such a provocation would lead to war and is  beyond the pale  for even ardent proponents of “getting tough” with Russia.  Indeed, because Russia’s military is strong, the U.S. and the West will most likely avoid any significant direct military response to possible Russian occupation/annexation of of the Crimea and even eastern Ukraine.

Possible high impact economic sanctions — different from the ‘I won’t come to your meetings and you cannot come to ours’ brand — would not be favored by most Western European countries or even the Ukraine, as they are dependent on Russia’s natural gas.  At the present time, the real options we have to counter Russia’s nefarious activities are not the best ones. While we could fulfill some of our allies’needs by exporting natural gas and oil, the decision to do so deserves (and I suspect is getting) hard analysis, especially in light of domestic U.S economic, political and security concerns about supply as well as demand and a fear of environmental problems, as well as increased consumer costs at the pump here at home. If shipping overseas passes muster, moving natural gas to our European allies and Ukraine could work both in providing needed gas and in possibly negatively affecting the price of Russian gas. Despite acknowledging the theoretical goal of oil independence, the world, including the U.S., is oil and gas dependent. We are lucky to have natural gas in ample supply, and if sane environmental regulations are applied, we can limit related methane and GHG emissions as well as other pollutants. Finally, we have an evolving and growing alternative fuel sector testing and developing renewable fuels.  Opening up U.S. fuel markets and fuel stations to increasingly available flex fuel vehicles and alternative fuels for consumers, including natural gas based ethanol and methanol, as well as electricity, can make us less dependent.

Progress on Fuel Efficiency: More is needed

Every now and then I will read a White House Blog.  They’re sort of a fun read when you’re depressed about the state of the world and the country.  The content always somehow reminds me of  Gene Kelly dancing in the street in the middle of the rain, or that old (possibly New Yorker) cartoon where the patient tells the psychiatrist that he is not doing well and the good doctor says ‘no you’re just fine, you’re happy and healthy.’  Probably neither is the proper analog to the politically necessary positive nature of the White House blurbs.  I marvel at times at the President’s ability to seek a better America, especially given the politics of the present.  While his optimism and tenacity don’t always come through as “Morning in America,” I believe that his attitude is based on a reasonable outlook about what the nation can do, if it can engage in an honest dialogue about key environmental and alternative fuel issues.

Last week’s blog focused on the White House’s effort to increase fuel efficiency standards.  It notes correctly that the President’s legislative approach to the environment has resulted in the toughest fuel economy standards in history:

“Under the first ever national program, average fuel efficiency for cars and trucks will nearly  double, reaching an average performance equivalent to about 54.5 miles per gallon by 2025….In 2011, the President also established the first-ever fuel efficiency and greenhouse gas standards for medium and heavy duty vehicles, covering model years 2014 through 2018.”

More is to come! Increased fuel efficiency standards are currently being addressed by the Administration, and the EPA is hard at work developing Tier 3 rules.

The Administration’s record is a decent one and has benefited the environment, lessened ghg emissions, and strengthened the economy. Regrettably though, fuel efficiency regulations primarily apply to new cars.  They should be matched by a cost efficient and comprehensive federal effort to encourage the conversion of older non flex fuel vehicles; they also should encourage Detroit to continue producing larger numbers of flex fuel cars.

In this context, EPA and Detroit automakers need to reach a consensus concerning effective engine recalibration alternatives, as well as an extension of consumer warranties and related financial coverage of recalibrated vehicles.  Without permitting older cars to achieve the fuel efficiency and environmental advantages of flex fuel vehicles, we will not be able to respond to Pogo’s admonition and Commodore Oliver Perry’s initial statement (paraphrased): that we, as a nation, have met the enemy, and he is us!

To grant primacy to new or relatively new flex fuel cars would increase the nation’s ability to reduce ghg emissions and other environmental pollutants (e.g. NOx and SOx). There are well over 200,000,000 non flex fuel cars in the U.S. that cannot readily use available fuel blends higher than E-15 and will not be able to use natural gas based ethanol that hopefully relatively soon will come on the market.

Lowering the certification costs of conversion kits by the EPA and increasing the number of manufacturers of those kits would bring down their price from around 1,000 dollars to the near 300 dollar level that is common in the “underground” market.  Simplifying legal conversion could  —and indeed would —-make an important environmental difference.  Such action would also open up the fuel market to competition, and likely lower the price of gas at the pump for consumers. Finally, such actions would also support the President’s objective to wean the nation off of oil and gasoline.  Oh Happy Day!  Go for it Gene Kelly and the American Association of Psychiatrists!  It might be time to show some real love for environmentally and efficiency neglected and needy older vehicles.

Tesla Takes It to the Next Level

This will be a week for watching Tesla, not only because the company’s stock had soared to new heights but because Elon Musk seems poised to take it to the next level – manufacturing batteries.

Musk has scheduled a conference call this week and gives every indication is he will be announcing plans for a new “Giga factory” where the Silicon Valley auto company will manufacture its own batteries. “Very shortly, we will be ready to share more information about the Tesla Giga-factory,” Musk told shareholders in his 4th quarter letter last week. This will allow us to achieve a major reduction in the cost of our battery packs and accelerate the pace of battery innovation.”

In a way the company has little choice. If Tesla is to move down-market from its current luxury niche – which has always been the plan – it is will need to buy the equivalent of the world’s entire current output of lithium-ion. The easiest thing to do is to go into manufacturing itself.

As usual, Musk will be doing things with a flair. Rumor is that he will be combining with SolarCity, which is run by his cousin Lyndon Rive, to produce a facility running largely on solar power. This will take us way beyond fossil fuels into the kind of world environmentalists imagine, where intermittent solar and wind power are stored to provide the kind of “high-9’s” reliability required by an industrial, digital society. And the key to that will be the same thing that Musk is working on now – batteries.

This kind of convergence is the reason for the number-two rumor of the week – that Tesla and Apple have engaged for a possible collaboration, even a merger. Last week San Francisco Chronicle reporters Thomas Lee and David Baker revealed that Apple’s M&A specialist Adrian Perica met with Musk last spring. What did they talk about?  Obviously a joint venture is in the air. Remarkably, only last October German stock analyst Adnaan Ahmad wrote an open letter to Apple saying it should consider entering the auto business by buying Tesla. The reasoning is as follows:

  • Despite its reputation for cutting-edge products, Apple’s traditional market for personalized devices seems to be reaching its limits. Sales of smart phones and tablets are maturing. Apple’s Next Big Thing is supposed to be a smart watch. A watch?  Is that an appropriate ambition for the world’s most innovative company?  As Steve Jobs did so many times, Apple need to enter an entirely new business and turn it upside down.
  • Apple is sitting on $160 billion in cash. It could literally buy almost any company in the world. Even with a market capitalization that is inflated by high expectations, Tesla is only worth $24 billion. The whole thing is doable.
  • Tesla needs an infusion of cash if it is to break out of its luxury niche and provide a car for the masses. The company’s proposed Gen III would sell for $35,000 and compete with the Chevy Volt and the Ford Focus. But more than half of that cost is in the battery. If Tesla can achieve vertical integration and come up with some new innovations, it may be able to turn a profit. But Apple is in the battery business as well, since most of what’s under the hood in an iPad or iPhone is lithium-ion. There is a convergence taking shape.

Of course there are many things working against this vision. Both Tesla and Apple may deal in lithium-ion batteries but designs aren’t the same and the chemistry is different. Also, when it comes to storing huge amounts of electricity at the factory, lead-acid remains the preferred technology. It’s cheaper in a way that lithium-ion will find if very difficult to duplicate.

Still, there seem to be breakthroughs coming in battery research almost every week. Only two weeks ago, researchers at Harvard announced the invention of a “flow battery” that stores a charge in organic liquids rather than metals. At the University of Limerick, researchers announced the development of a new germanium nanowire-based anode that greatly expands the capacity and lifetime of lithium-ion batteries. And researchers at Stanford said they had developed a silicon anode based on the design of a pomegranate seed that improves lithium-ion storage capacity by a factor of 10. All this is within the space of the last two weeks.

Batteries are hot and Elon Musk will be walking right into the middle of it. He has proved Tesla’s charging system has legs. The first Model S just made the 3,464-mile journey from Los Angeles to New York in 76 hours using Tesla’s new network of supercharger stations. Recharging has been reduced to just over an hour. Model S sales hit 22,500 for 2013, exceeding expectations. With all this success under its belt, the company is preparing to move down-market, where it can really have an impact on our fossil fuel dependence.

Like many Silicon Valley entrepreneurs, Musk is obsessed with space travel. He says he wants to be buried on Mars – “and not on impact.” With Steve Jobs gone, Musk may be the man to take Silicon Valley’s venture into alternative automobile propulsion to the next level.

 

Bio-processing of Gas-to-Liquids: A Report Card

If finding microbes that can convert cellulose plant material into ethanol is of the holy grails of biofuels, an equally elusive goal is using microbes to make liquid fuels out of natural gas.

Almost everyone agrees that the best way to apply our now-abundant natural gas resources to transportation would be to convert it into a “drop-in” liquid fuel that would fit easily into our current gas-station infrastructure. T. Boone Pickens’ CleanFuels Corp. and others are trying to supply compressed natural gas to diesel trucks, but the effort has obvious impediments and will require a whole new infrastructure.

Much easier would be the direct conversion of natural gas to methanol, the simplest alcohol, which is now produced at a rate of 33 billion gallons per year for industrial purposes. But methanol still suffers from its Prohibition-Era reputation as poisonous “wood alcohol” (although gasoline is equally poisonous) and has run into stiff EPA regulations on converting contemporary engines to burn alternative fuels. (See “Making the Case for Mars and Methanol”) And so the vision has arisen that a golden gas-to-liquids pathway can be carved by the nation’s laboratories working with nature’s existing microbial stock.

A year ago, ARPA-E, the fast-track research funding agency modeled on the Defense Department’s Advanced Research Project Agency, announced a new initiative: REMOTE – the Reduced Emissions Using Methanotrophic Organisms for Transportation Energy.  Methanotrophic organisms are microbes that feast on methane, the simplest carbohydrate, and can convert it into more complex molecules such as butane or formaldehyde, which can in turn be synthesized by other microbes into butanol, methanol or other liquids that can be cleanly burned as fuels.  As the agency wrote in its Funding Opportunity Announcement (FOA):

The benefits of converting natural gas to liquid fuels for use in transportation have long been recognized. First, the existing transportation infrastructure is based on liquids, and such fuels can be conveniently “dropped in” without substantial changes in vehicles. Second, liquid fuels from methane have lower emissions than petroleum-based fuels. Liquid fuel produced from methane decreases emissions by up to 50%, compared to unconventional petroleum, and decreases particulate matter by up to 40%, compared to combustion of conventional diesel. Further, methane is responsible for 10% of the nation’s greenhouse gas emissions (on a CO2 equivalent basis), in part because its global-warming potential is 20 times greater than that of CO2 over a 100-year period. Technologies capable of capture and conversion of methane will help mitigate the global-warming potential of these emissions.

There are several interesting things going on here. First, ARPA-E has chosen the goal of reducing emissions rather than reducing dependence on foreign oil as the motivating force of the project. Alcohols do burn cleaner than gasoline. In fact, the whole California effort that put 15,000 methanol cars on the road in the 1990s was aimed at reducing air pollution, not replacing oil imports. This may satisfy environmentalists, who tend to see natural gas as just another fossil fuel and would prefer to pursue cellulosic ethanol in order to remain “carbon neutral.”

Second, although the chemical synthesis of methanol, butanol and other potential fuels is already economical, employing biotechnology gives the whole plan a “green” tinge. Chemical processes are regarded as “old economy” and unlikely to attract investment from Silicon Valley and other centers of venture capital, whereas biotechnology has a New Age sheen to it. Already ARPA-E has handed out $20 million to small startups and others have been forthcoming.

Finally, by latching onto natural gas flaring, ARPA-E is addressing a problem that is gaining more and more attention, particularly the publication of a paper in Science last week claiming that will be no climate benefits in switching from diesel and other crude-oil-based fuels to natural gas derivatives. Indeed, flaring is now said to consume the equivalent of one-third of America’s consumption of crude oil. Obviously, anything that addresses this will get attention.

So how are thing going?  Last week Robert J. Conrado and Ramon Gonzalez, two researchers in the Department of Energy, issued a progress report in Science. Basically, the news is that while there’s still lots of optimism about the idea, nothing much has been accomplished yet.

Conrado and Gonzalez note that the process of biological conversion involves three steps:   1) the “activation” of the stable methane molecule so it becomes chemically receptive; 2) the conversion of methane to formaldehyde and other intermediates; and 3) the synthesis of these intermediates into alcohols and other fuels through bioreactors. All three steps need improvement. “To access small-scale and time-varying resources [i.e., flared gas at remote wells], process intensification leading to an order-of-magnitude increase in volumetric productivities is needed and will require technological breakthroughs in [all] three areas.”

One institution that is working on the problem is the Sandia National Laboratory in New Mexico. Blake Simmons, manager of the lab’s biofuels and biomaterial science group, says the challenges are daunting but he remains optimistic. “There have been plenty of investigations into this in the past since there are plenty of organisms in nature that thrive and multiply off natural gas,” he said in an interview with Phys.org. “The problem, though, is that they exist in unique, tailored environments and are typically very slow at what they do. People have been trying to express this class of enzymes for a couple of decades, so this won’t be a slam dunk. But we have the collective experience and capabilities at Sandia to figure it out.”

And so the search for a clean, green conversion of methane to a liquid fuel goes on. In the meantime, however, it might be worth opening the door to methanol and other chemically synthesized products just as a placeholder.

Making the Case for Mars and Methanol

Robert Zubrin is one of those oddball geniuses who prowl around the peripheries of important national issues making suggestions that may seem completely off the wall but on closer inspection are revealed to have penetrating insight.

I first came across him a couple of years ago while writing about space exploration. Zubrin is perhaps the world’s leading advocate of manned trips to Mars. He’s written five books about making the trip to Mars, including How to Live on Mars (2008), which detailed how to establish a permanent colony on the red plant. None of this is going to happen soon, of course, and even though Zubrin is a highly trained aerospace engineer, it’s easy enough to dismiss him as a fatuous dreamer.

Except for one thing: he has also become the most knowledgeable and well versed advocate of substituting methanol from natural gas for imported oil as a way of breaking the back of OPEC.

Zubrin actually wrote his first highly informed book on the subject – Energy Victory – in 2008, before the fracking revolution began producing prodigious amounts of natural gas. At the time he was suggesting we use our abundant coal resources as the feedstock. Now that George Mitchell’s revolution has pumped up gas production to 24 times the level of 2007, the case is even stronger.

Zubrin has just published a 5,700-word article in the current issue of New Atlantis. I won’t do more than summarize it here, but I would recommend tying it up in a bow and giving it to everyone you know as a Valentine’s Day present. Zubrin wraps up all the major arguments for methanol and even manages to illuminate some obscure details about the Environmental Protection Agency’s policy toward methanol that eluded some of us for some time. Here are his major talking points:

  • OPEC still essentially controls the world price of oil. Even though non-OPEC production has increased 60 percent since 1973, 60 percent of the oil traded around the world is exported from OPEC countries and 80 percent commercially viable reserves are still owned by OPEC members. The price of oil is still set in the Persian Gulf.
  • This oligopolistic control has a huge impact on the American economy. Ten of the last 11 postwar recessions were preceded by sharp increases in oil prices. The recent upsurge in shale oil production won’t help much. The Energy Information Administration expects it to level off after 2016. By 2040 we will still be importing 32 percent of our oil.
  • Methanol made from natural gas is the only commodity that can realistically replace oil. “Methanol is not some futuristic dream touted by researchers seeking funding,” writes Zubrin. “Rather, it is an established chemical commodity, with a global annual production capacity of almost 33 billion gallons. It has recently been selling for around $1.50 a gallon.” Methanol’s energy content is only about 60 percent of gasoline, but the bottom line is that “pure methanol can get a car 30 percent farther down the road than a dollar of gasoline.”
  • Methanol has numerous environmental advantages. In fact, when California put 15,000 methanol cars on the road in the 1990s, it was for air pollution purposes, rather than cutting imports or reducing prices to motorists. Methanol burns cleaner, produces virtually no particulate matter or smog components, has none of gasoline’s carcinogenic aromatic compounds and reduces carbon emissions.  On pollution grounds alone, it would be worth making the transformation.

So why don’t we do it?  As Peter Drucker always said, in order to replace a well established technology, an upstart replacement must be 10 times as efficient to clear the institutional barriers. That’s a tall order. But as Zubrin details, there are some specifics that stand out:

  • In terms of sheer market capitalization, the oil industry far surpasses the auto industry. Thus, even though the auto industry might benefit from opening up to new fuels, the oil companies’ interest in maintaining the status quo overwhelms them. Zubrin documents how institutional investors that own large shares of the auto companies are even more heavily invested in oil. Several OPEC sovereign wealth funds also own huge slices of the auto companies. The Qatar Investment Authority owns 17 percent of Volkswagen, which has the highest auto company revenues in the world.  Its vice chairman sits on Volkswagen’s board.
  • The Environmental Protection Agency, through overregulatory zeal, has somehow ended up as one of the major impediments to methanol conversion, even though there would be vast environmental benefits. Although older cars can easily be converted to run on methanol at a cost of less than $200, the EPA no longer permits it. “Since 2002, the only way for a vehicle modification to be deemed lawful is if it receives certification ahead of time from the EPA or the California air-quality board. . . In 2009, the EPA specified massive fines that it may level against any individual or business that modifies a vehicles without advance certification, even if there is clear and compelling proof that no emissions increase had resulted, or even been risked, by such changes. In fact, even the use of unapproved engine parts identical to the certified brands would be considered an emissions violation . . . These fines are set at thousands of dollars for individuals and hundreds of thousands, or even millions, for manufacturers. For example, if a mechanic running his own small business converting cars to flex-fuel in his garage modified just a dozen cars, he would face a crippling fine of more than $105,000.”

In 2011 on National Review Online, Zubrin offered to bet anyone $10,000 he could modify his 2007 Chevy Cobalt (apparently in violation of EPA regulations) to run on 100 percent methanol and get 24 miles per gallon. He did it by replacing the fuel pump seal with a 41-cents replacement made from a synthetic rubber that resists methanol erosion. He also had to adjust the ignition timing for methanol’s higher octane. He would have won the bet but no one took him up.

As a way of moving the ball forward, Zubrin advocates the Open Fuel Standard Act, which has been sitting around in Congress since 2008. The present version would clear up some of the EPA’s restrictions and require at least 30 percent of each carmaker’s new vehicles be flex-fuel by 2016, moving up to 50 percent by 2107. The modification would only add about $200 to the price of the car.

Zubrin is one of those American treasures, an independent thinker operating outside the world of “policymaking” who dares think differently and big. His ideas for colonizing Mars may never get off the drawing boards.  But his proposal for substituting methanol as a domestic alternative to imported oil certainly deserves the greatest attention.

No Sex-Just Smirking; No Lies-Just No Strategic Thinking; No Videotapes- Just Lots Of words And Ideology

According to several well-known writers of blogs and columns, based on a recent study by North Carolina State University, EDV’s (electric cars, hybrids and plug ins) are not all they are cracked up to be. Because they may be powered by a coal or natural gas utilities, they spew pollutants, because hybrids may use gasoline, they emit ghg and other pollutants, because their production processes are “dirty,” they generate more pollutants than gasoline.

Electric cars in China have an overall impact on pollution that could be more harmful to health than gasoline vehicles…  EDVs ghg reduction will not make a big difference because the total number of vehicles in the U.S. only produces about 20 percent of all carbon emissions.”

I have seen higher numbers than stated by the writers concerning carbon emissions by cars and trucks fueled by gasoline. It is not clear whether the North Carolina study compared general supply chains to supply chain specifics. For example, EV engines use a proportionately large share of aluminum. Its mining probably emits more ghg than materials used in non evs. Yet, its use in cars, given its lighter weight, produces less emissions.

More relevant, perhaps, while recently there has been some retreat because of rising natural gas costs compared to coal costs, in the long term future, (perhaps aided by government regulations of carbon emissions,) conversion of coal based power generation to natural gas will  again trend upward and lower the total ghg allocated to EDVs.

The bloggers and columnists as well as the North Carolina scholars seem to believe in the theory that if you build it they will come.  Indeed, the most frequent comments on the models used in the study relate to one model, that is, a 42 percent EDV market share by 2050. It presumes a government cap on emissions.   Apparently, according to this model, any ghg reductions caused by EDVs will soon be filled up by other emitters. According to the study’s author, Joseph DeCarolis, ( interviewed by Will Oremus, a critic of the paper in his article in Future Tense, Jan. 27),   “It’s that there all this other stuff going on in this larger energy system that effects overall emissions.” I would add based on the study, DeCarolis presumes ghg emissions are fungible and equilibrium will result in 2050.

Diminishing the ghg importance of  EDVs ,  more than three decades out,  shifts  issues and initiates arguments over whether or not government should have a tougher cap; whether or not other sectors of the economy will illustrate more or less ghg emissions; whether or not technological advancements focused on ghg reduction across the economy will remain almost static; whether or not businesses will accept ghg reduction as a must or as part of  “conscientious capitalism” both to sustain profits and quality of life.

The continued development and increased sales of edvs are important to the nation’s long term effort to reduce ghg and other pollutants. But, until evs among edvs increase mileage per charge to remove owner fear of stalling out in either remote or congested places like freeways and until the price comes down and size increases for families with children, they will at best constitute a relatively small share of the new market for cars in the  near future. Even if the total numbers of edvs significantly increase their proportion of new car sales, many years will pass before they, will collectively, play a major role in lessening the nation’s carbon footprint.

Perfectibility not perfection should be a legitimate goal for all of us concerned with the environment. Individuals and groups concerned with the economic and social health of the nation should drop their ideological bundling boards. (Some of us are old enough to remember the real origins of the bundling board. Because of a shortage of space in many homes, it was used to separate males and females who often slept together before they were married in revolutionary days. I am not sure it was abandoned because mores changed, houses got bigger or people got splinters. I have no videotapes!)

2014 should witness the development of a non-partisan,non- ideological coalition of environmental, business, non-profit, academic  and government leaders to embrace  the need for an effective transitional alternative fuel strategy for new and existing cars and EDVs.  The embrace should respond to national and local objectives concerning the environment, the economy, and security and consumer well-being.   A good place to start would be to extend the use of natural gas based fuels, including ethanol and methanol.

Simultaneously, the coalition should encourage Detroit to expand production of flex fuel cars and the nation to implement a large scale flex fuel conversion program for existing cars.  Added to the coalition’s agenda should be development of a more open fuels market and support for intense research and development of EDV’s, particularly EVs.  Hopefully, evs will soon be   ready for prime time in the marketplace. Succinctly, we need both alternative fuels and evs.

Can Butanol Be the New Ethanol?

Even as the ethanol industry is wobbling over the Environmental Protection Agency’s decision to cut back on the ethanol mandate in 2014, a new candidate has emerged as an additive to gasoline – butanol.

Virgin Airways founder and CEO Richard Branson has announced that his Virgin Green Fund will be cosponsoring a groundbreaking butanol manufacturing plant in Luverne, Minnesota.  “Butanol is the future of renewable fuel,” said Branson, who is already using renewable jet fuel for his airline.  “It’s hugely versatile and can be used to produce gasoline fuel blends, rubbers, solvents, and plastics, which gives us scope to enter a range of markets,” he said in an interview with Bloomberg.

Corn ethanol now dominates the $26 billion gasoline additive market, drawing the glucose content out of 45 percent of the nation’s corn crop (the protein is fed to animals).  Branson’s butanol would use a similar feedstock – corn, sugar cane or cellulosic biomass – but would produce a fuel that has 84 percent of gasoline’s fuel density compared to ethanol’s 66 percent, although ethanol has a higher octane rating.  The implication is that butanol could be mixed at higher blends, giving it almost the same range as gasoline.

Both butanol and ethanol are made through a process that employs yeasts to ferments the glucose from organic material into alcohols.  Methanol, the simplest alcohol, has one carbon joined to a hydroxyl ion while ethanol has two carbons and butanol has four.  Octane, the principal ingredient in gasoline, has eight carbons without the hydroxyl ion.

As far a butanol is concerned, it’s not as if people haven’t tried this before.  Both BP and Royals Dutch Shell have experimented with producing butanol from organic material but have found the process harder than they anticipated.  “There is certainly a potential, but there have been quite considerable problems with the technology,” Clare Wenner, of the London-based Renewable Energy Association, told Bloomberg.  “It’s taking a lot longer than anybody thought years ago.”

Gevo’s plant in Minnesota, for instance, has been running at only two-thirds of its 18 million gallon-a-year capacity because of a contamination in its yeast fermenting facility in September 2012.  Similar instabilities in the microbial-based process have dogged the efforts to break down cellulose into simple molecules.  There operations can often be performed in the laboratory but become much more difficult when moved up to a commercial scale.

Branson is confident these obstacles can be overcome.  He’s already got Silicon Valley investor Vinod Khosla on board in Gevo and Total, the French oil company, has also taken a stake.  Together they have enlisted big ethanol producers such as Big River Resources and Siouxland Ethanol to commit to switching their manufacturing process to butanol.  Butamax Advanced Biofuel, another Minnesota refiner funded by Dupont and BP, is also in the process of retrofitting its ethanol plant to butanol.  Taken together, these facilities would be able replace 1 billion of the 14 billion gallons of ethanol now being produced every year.

Whether this would be enough to make a bigger dent in America’s oil import budget remains to be seen.  The 14 billion gallons of ethanol currently substitutes for 10 percent of our gasoline and about 6 percent of our total oil consumption.  The Environmental Protection Agency has limited ethanol additives to 15 percent of the blend, mainly to protect older cars.  (In Iowa, newer cars are running on an 85 percent blend.)  Now the reduction in the 2014 mandate is making the ethanol industry nervous about overcapacity.  Butanol is less corrosive of engines and the 16 percent blend could give it an edge.

On another front, T. Boone Pickens’ Clean Energy Fuels announced this week that it may turn a profit for the first time since its founding in 1997.  Clean Fuels is concentrating on supplying compressed natural gas for trucks, signing major contracts with Frito-Lay, Proctor & Gamble, United Parcel Service and Ryder.  It is also attempting to set up a series of filling stations on the Interstate Highway System.  The use of CNG requires an entirely new infrastructure, however, rather than the easy substitution of liquid and butanol.

The dark horse here is methanol, which is liquid and fits easily into our present infrastructure but would be synthesized from natural gas.  Somehow, methanol has not attracted the attention of Branson’s biofuels and Pickens’ CNG.     All of these efforts hold promise, however, and would make a huge dent in our annual $350 billion bill for oil imports, which constitutes the bulk of our $450 billion trade deficit.  So good luck to all and may the best fuel win – or all of them, for that matter.