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CNG & LPG Vehicle Market by Vehicle Type (Passenger Cars & Light Commercial Vehicles), Fuel Type (CNG & LPG), and Geography (Asia-Pacific, Europe, Americas & ROW) – Industry Trends & Forecasts to 2019

Report: The market for CNG & LPG vehicles is gaining traction in many countries due to the combined effects of low-cost CNG and LPG and sustained higher prices for gasoline and diesel. The dual fuel options available in these vehicles make them an attractive option in terms of reduction in running costs and removing range anxiety. The low cost of conversion and prospect of significant emission reduction will increase the penetration of alternate fuels, worldwide.

Jacksonville CNG station for entire public on its way, prompting forecasts for revolution in local truck fuel

The rush to make Jacksonville one of the leading players in the natural gas industry took another step Wednesday, when work began on a publicly accessible compressed-natural-gas station.

 

Garage filling stations — are we getting close?

One of the greatest appeals of switching to an alternative-fuel vehicle — electric, compressed natural gas or hydrogen — is saving money and freeing yourself from the clutches of foreign oil. But another is being able to supply your own fuel from a garage filling station where you may even be able to generate some of it yourself.

All this takes on a certain air of necessity when you realize that most of the infrastructure for recharging or refilling is not yet in place. In many cases, the garage may be the best option right now. So let’s run down some of the different options available and see how they stack up as being economical and practical.

Let’s start with the easiest one — electric cars. There are three types of chargers available to owners of a Prius, Leaf or Chevy Volt. The first is a Level 1 “trickle” charger, which is just a basic 120-volt line that plugs into any three-pronged outlet. This is the standard plug-in for all EVs. The problem is the amount of time it takes for a complete charge. For the Leaf, it takes close to 21 hours, which means that you can’t even do it overnight. For hybrids there’s some leeway since you can always revert to the gas motor and do some brake recharging as well. But if you’re planning to rely completely on a home outlet, you’d better have a second car.

More favorable is a Level 2 240-volt circuit. If you have an electric clothes dryer in your house, you’re already equipped. If you don’t have a 240-volt system at home, installation is easy enough. It will require a 40-amp circuit breaker, which may need a permit from the local building department, but the job is simple enough. Recharging time will be cut to less than eight hours, enough for an overnight. Plugincars.com puts the price at $600 -$700, although vendors such as ClipperCreek lists some for less.

If you really want to go really high-tech, you can move up to a Level 3 480-volt power supply that can give you an 80 percent charge in half an hour. The whole package costs $30,000, but with federal tax breaks and some help from the car companies, you can get it down to $10,000. Nissan offers a unit for $9,900. You could probably recoup some of the costs by recharging EVs for your neighbors, but you might need a zoning variance.

So how about compressed natural gas? What are the options there?

The Honda Civic is the only CNG passenger vehicle being sold in the United States. (Most of the progress has been with delivery trucks and long-haul trailers.) There are currently 1,000 CNG filling stations across the country, but half of them belong to companies that are using them for their fleets. Only about 500 are available to the public. So, unless you’re traveling along an Interstate and can make it to one of Clean Energy Fuels’ new truck stops, you’re going to have a hard time.

Refilling at home, however, isn’t all that impractical. More than half the residences in the country are equipped with natural gas for home heating, cooking or hot water. The trick is to get a device that can compress this household gas to be used in your car.

Honda originally offered a home refueling kit, the Phill, which costs $4,500 and could do a refill overnight. Honda stopped making the offer after 2012; however, due to concerns about the widely varying quality of non-commercial gas and the possibility of home devices allowing moisture to collect in the fuel system. For those willing to take the chance, the Phill is still available from its manufacturer, BRC FuelMaker. The question is, “Why is it so expensive when the same pump would cost 10% if it filled air bottles?” There is a regulatory review needed to reduce the cost.

Seeking to promote the technology, the Department of Energy (DoE) handed out grants a few years ago to encourage companies to develop affordable home systems. Now one of them may have come through. The Eaton Corporation of Cleveland, already prominent in the field of electrical charging stations, announced in 2012 that it plans to market a CNG home refueling device by 2015. “The system will use liquid to act as a piston in compressing the gas,” says Chris Roche, vice president at Eaton’s Innovation Center. “We have also developed an innovative heat exchange technology that will improve efficiency and cut costs dramatically.” Eaton is aiming at production costs of $500, which means the device could sell for less than $1,000. GoNatural, a Salt Lake City company, has also promised to have a product available by 2015. “It could be a game changer,” said New York Times reporter Paul Stenquist, in profiling CNG home compressors last October.

So, what about hydrogen? Is there anything available there? Hydrogen is very difficult to deal with. It is the smallest atom and will leak through just about anything. It’s hard to store and transport and must be kept under high pressure.

The upside, however, is the possibility of generating your own hydrogen, particularly from renewable resources. This can be done with simple electrolysis of water, which only requires an electric current. If you can generate that current with wind or solar energy, then you are essentially powering your car for free.

Making it happen is probably a long way off, although people are working on it. HyperSolar, Inc., a Santa Barbara company, has announced “proof of concept” of a method for generating solar hydrogen. “Using our self-contained particle in a low cost plastic bag, we have successfully demonstrated our ability to mimic photosynthesis to produce renewable hydrogen from virtually any source of water using the power of the Sun,” said CEO Tim Young while making the announcement. Horizon Fuel Cells, a Singapore company, released a “desktop” hydrogen generator in 2010 that generates hydrogen through electrolysis from any power source. It sells for $250 on Amazon. Although the company is targeting much smaller fuel-cell devices, it could eventually scale up to handle quantities needed to run a hydrogen fuel cell car

Altogether for cutting loose from the local gas station, electric vehicles are the best bet for now. But natural gas in its many forms — including methanol — are moving up and renewable hydrogen may be on the horizon. With home-generating devices proliferating, it is not hard to see all this eventually making a dent in our consumption of fossil fuels.

DME poses a challenge to CNG

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

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

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

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

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

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

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

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

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

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

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

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

Clean Energy Fuels sees daylight ahead

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

CNG moves ahead on all fronts

The effort to substitute compressed natural gas for foreign oil in our gas tanks is moving ahead on all fronts across the country, in scores of municipal departments that are converting their fleets, in new gas stations that are opening and with entrepreneurs who are looking for ways to speed up the conversion.

Leading the pack is Clean Energy Fuels, T. Boone Pickens’ effort to put the nation’s natural gas resources to work in the transport sector. Clean Energy Fuels has targeted long-distance, heavy-duty trucks, which tend to stay on the Interstate Highway System and can be services at massive truck stops. In Pennsylvania, for instance, Clean Energy Fuels is building stations in Pittston and Pottsville that will serve trucks on heavily the traveled I-81 and I-476. They are scheduled to open later this year.

But much of Clean Energy Fuels’ real success is coming from the fleet conversion for major shipping firms that rely heavily on truck transportation. The company has had particular success with UPS. Fueling depots were recently opened in Oklahoma City and Amarillo, Texas. The carrier E.J. Madison, LLC has deployed a fleet of 20 long-haul LNG trucks that will utilize a CEF network of stations that stretches from Los Angeles to Jacksonville, Florida. Jacksonville is emerging as a hub of CEF activity as the company has opened a liquid natural gas (LNG) terminal there as well. LNG is more difficult to handle than compressed natural gas but has much greater energy density.

Rapidly expanding in Florida, CEF has just announced a grand opening of a CNG filling station that will service the Hillsborough Area Regional Transit Authority (HART), which provides public transportation throughout the Tampa metropolitan area. The opening kicks off a plan to convert HART’s entire fleet of public services buses and vans to compressed gas.

Just last week Clean Energy Fuels CEO Andrew Littlefair was in the news telling The Motley Fool that Tesla’s electric cars will not be in competition with CEF’s efforts. “Tesla and electric vehicles are really great for certain applications,” he told interviewer Josh Hall. “But hauling 80,000 pounds of cargo, natural gas is really well suited for that.”

However, even if Clean Energy Fuels doesn’t think CNG can compete with electric at the passenger-car level, others do. Last week the Wawa convenience store chain announced it will partner with South Jersey Gas to open CNG fueling stations in southern New Jersey. “Compressed natural gas gives us an opportunity to increase the convenience we offer our customers and positions us for the future as well,” Brian Schaller, vice president of fuel for Wawa told the press. “We’re excited about the growth potential.” With 600 stores on the East Coast from New Jersey to Florida, Wawa has plenty of room to grow.

Pennsylvania is becoming a hotbed of compressed gas progress as the state seeks to take advantage of the Marcellus Shale. The state has adopted a funding program to help businesses convert. One of the first to take advantage is Houston-based Waste Management, which received an $806,000 grant from the State Department of Community & Economic Development to switch 25 of its waste and recycling collection vehicles to CNG. Pennsylvania-American Water Company has also announced plans to convert its fleet with a $315,000 state grant. American Water, the largest water utility in the state, operates out of Scranton.

Nebraska is a long way from any natural gas drilling but the Uribe Refuse Services company of Lincoln has announced it will convert its entire fleet of 17 trucks to natural gas over the next few years. The first trucks were displayed in the city last week on Earth Day.

Oklahoma is a big oil-and-gas producing state and is making a major effort to convert state vehicles to natural gas. In 2011 Gov. Mary Fallin joined 15 other states in a multi-state memorandum of understanding committing them to purchase NGVs for the state fleet. The state now has 400 CNG vehicles and is pushing the federal government to convert its fleet in the state as well. Oklahoma is building CNG gas stations to match and now stands third in the nation behind California and New York.

The natural gas industry is putting its shoulder to the wheel on this effort. The American Gas Association and America’s Natural Gas Alliance (ANGA) have teamed up to sponsor “Add Natural Gas (+NG),” an effort that is encouraging entrepreneurs and mechanics to convert ordinary passenger cars already on the road to CNG. “Fleets across the country are already using natural gas vehicles to save money and reduce emissions,” says the group’s website. “However, natural gas can be used to fuel any vehicle. To demonstrate this, we worked with automotive engineers to add natural gas as a fueling option for some of the most popular vehicles on the market today.”

Performance CNG LLC is a Michigan startup that has been inspired to take up the initiative. The company recently had a hybridized 2012 Ford Mustang GT demonstrated as part of +NG’s campaign and is currently trying to raise $55,000 in capital on Indiegogo, an international crowd funding site. More than half the money would go to EPA emissions testing.

Not everyone is convinced that CNG is the way to go. Clean Energy Fuel’s stock has done poorly since January, based on investor skepticism that its market is not that big and that some liquid natural-gas based fuel – methanol of butanol – will prove easier to handl

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.”

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.