Posted on 02/11/2015 5:10:39 AM PST by thackney
Ectric cars are quick and quiet, with a range more than long enough for most commutes. If you want a car with extremely fast acceleration, the Tesla Model S is hard to beat. And, of course, electric vehicles avoid the pollution associated with conventional cars, including emissions of carbon dioxide from burning gasoline. Yet they account for a tiny fraction of automotive sales, mainly because the batteries that propel them are expensive and need to be recharged frequently.
A better battery could change everything. But while countless breakthroughs have been announced over the last decade, time and again these advances have failed to translate into commercial batteries with anything like the promised improvements in cost and energy storage. Some well-funded startups, most notably A123 Systems, began with bold claims but failed to deliver (see “What Happened to A123?”).
The Powerhouse, a new book by journalist Steve LeVine, chronicles the story behind one of the most dramatic battery announcements of recent years and explains how it came to nothing (see “The Sad Story of the Battery Breakthrough that Proved Too Good to Be True”). The announcement was made in February 2012, at a conference in Washington, D.C., where a crowd of researchers, entrepreneurs, and investors had come to hear the likes of Bill Gates and Bill Clinton expound on the importance of new energy technology—and also to tap into one of the newest funding sources in Washington, the Advanced Research Projects Agency for Energy, or ARPA-E. Founded in 2009, ARPA-E had been tasked with identifying potentially transformational research. The head of that agency, Arun Majumdar, was ready to unveil one of its first major successes: a battery cell, developed by the startup Envia, that could store twice as much energy as a conventional one. The cost of a battery that could take a car from Washington to New York without recharging, Majumdar said, would fall from $30,000 to $15,000. Electric cars would become far more affordable and practical (see “A Big Jump in Battery Capacity”).
Within months, GM licensed the technology and signed an agreement to support its development, gaining the right to use any resulting batteries. The deal was potentially worth hundreds of millions of dollars to Envia, LeVine writes. But soon Envia was getting frustrated messages from GM engineers who couldn’t reproduce the startup’s results. The year after the announcement, the deal was scuttled. Envia’s impressive battery had been a fluke.
LeVine’s account of Envia’s work shows why major progress in batteries is so hard to achieve and why startups that promise world-changing breakthroughs have struggled. Over the last decade we’ve seen remarkable improvements in this industry, but they’ve come largely from established companies steadily making small advances.
Envia’s cell was a new type of lithium-ion battery. Invented in the late 1970s and early 1980s and commercialized in the 1990s, these batteries generate electrical current when lithium ions shuttle between two electrodes. Light but powerful, they have transformed portable electronics. Their use in electric cars, however, is recent. In the 1990s, GM used cheaper lead-acid batteries for its electric EV-1; each battery weighed a bulky 600 kilograms and delivered only 55 to 95 miles before it needed to be recharged. When Tesla Motors introduced one of the first lithium-ion-powered electric cars in 2008, it could go 250 miles on a charge, roughly three times farther than the EV-1. But the vehicle cost over $100,000, in large part because the batteries were so expensive. To cut costs, the lithium-ion-powered electric cars made today by companies such as Nissan and GM use small battery packs with a range of less than 100 miles.LeVine’s account of Envia’s work shows why major progress in batteries is so hard to achieve and why startups that promise world-changing breakthroughs have struggled. Over the last decade we’ve seen remarkable improvements in this industry, but they’ve come largely from established companies steadily making small advances.
Envia’s cell was a new type of lithium-ion battery. Invented in the late 1970s and early 1980s and commercialized in the 1990s, these batteries generate electrical current when lithium ions shuttle between two electrodes. Light but powerful, they have transformed portable electronics. Their use in electric cars, however, is recent. In the 1990s, GM used cheaper lead-acid batteries for its electric EV-1; each battery weighed a bulky 600 kilograms and delivered only 55 to 95 miles before it needed to be recharged. When Tesla Motors introduced one of the first lithium-ion-powered electric cars in 2008, it could go 250 miles on a charge, roughly three times farther than the EV-1. But the vehicle cost over $100,000, in large part because the batteries were so expensive. To cut costs, the lithium-ion-powered electric cars made today by companies such as Nissan and GM use small battery packs with a range of less than 100 miles.
One difficult thing about developing better batteries is that the technology is still poorly understood. Changing one part of a battery—say, by introducing a new electrode—can produce unforeseen problems, some of which can’t be detected without years of testing. To achieve the kinds of advances venture capitalists and ARPA-E look for, Envia incorporated not just one but two experimental electrode materials.
LeVine describes what went wrong. In 2006 Envia had licensed a promising material developed by researchers at Argonne National Laboratory. Subsequently, a major problem was discovered. The problem—which one battery company executive called a “doom factor”—was that over time, the voltage at which the battery operated changed in ways that made it unusable. Argonne researchers investigated the problem and found no ready answer. They didn’t understand the basic chemistry and physics of the material well enough to grasp precisely what was going wrong, let alone fix it, LeVine writes.
With its experimental material for the opposite electrode, this one based on silicon, Envia faced another challenge. Researchers had seemingly solved the major problem with silicon electrodes—their tendency to fall apart. But the solution required impractical manufacturing techniques.
When Envia made its announcement in 2012, it seemed to have figured out how to make both these experimental materials work. It developed a version of the silicon electrode that could be manufactured more cheaply. And through trial and error it had stumbled upon a combination of coatings that stabilized the voltage of the Argonne material. Envia cofounder Sujeet Kumar “understood that the answer was a composite of coatings,” LeVine writes. “But he still didn’t know what the composite was arresting or why it succeeded in doing so.” Since Envia was a startup with limited funds, he “didn’t have the instruments that could figure it out.” But once it became obvious that the results Envia had reported for its battery couldn’t be reproduced, understanding the problem became crucial. Even tiny changes to the composition of a material can have a significant impact on performance, so for all Envia knew, its record-setting battery worked because of a contaminant in a batch of material from one of its suppliers.
The story of Envia stands in sharp contrast to what’s turned out to be the most successful recent effort to cut the price of batteries and improve their performance. This success hasn’t come from a breakthrough but from the close partnership between Tesla Motors and the major battery cell supplier Panasonic. Since 2008, the cost of Tesla’s battery packs has been cut approximately in half, while the storage capacity has increased by about 60 percent. Tesla didn’t attempt to radically change the chemistry or materials in lithium-ion batteries; rather, it made incremental engineering and manufacturing improvements. It also worked closely with Panasonic to tweak the chemistry of existing battery materials according to the precise needs of its cars.
Tesla claims that it is on track to produce a $35,000 electric car with a roughly 200-mile range by 2017—a feat that’s equivalent to what GM hoped to achieve with Envia’s new battery. The company anticipates selling hundreds of thousands of these electric cars a year, which would be a big leap from the tens of thousands it sells now. Yet for electric cars to account for a significant portion of the roughly 60 million cars sold each year around the world, batteries will probably need to get considerably better. After all, 200 miles is far short of the 350-plus miles people are used to driving on a tank of gasoline, and $35,000 is still quite a bit more than the $15,000 price of many small gas-powered cars.
How will we close the gap? There is probably still plenty of room to improve lithium-ion batteries, though it’s hard to imagine that Tesla’s success with minor changes to battery chemistry will continue indefinitely. At some point, radical changes such as the ones Envia envisioned may be needed. But the lesson from the Envia fiasco is that such changes must be closely integrated with manufacturing and engineering expertise.
That approach is already yielding promising results with the Argonne material that Envia licensed. Envia’s battery operated at high voltages to achieve high levels of energy storage. Now battery manufacturers are finding that using more modest voltage levels can significantly increase energy storage without the problems that troubled Envia. Meanwhile, battery researchers are publishing papers that show how trace amounts of additives change the behavior of the materials, making it possible to edge up the voltage and energy storage. The key is to combine research that illuminates details about the chemistry and physics of batteries with the expertise that battery manufacturers have gained in making practical products.
It’s an industry in which it’s very difficult for a startup, however enticing its technology, to go it alone. Andy Chu, a former executive at A123 Systems, which went bankrupt in 2012, recently told me why large companies dominate the battery industry. “Energy storage is a game played by big players because there are so many things that can go wrong in a battery,” he said. “I hope startups are successful. But you can look at the history over the past few years, and it’s not been good.”
And, of course, any pollution from the source of electricity necessary to recharge the thing is discounted.
Technology Review, eh?
The key problem is Lithium is a fairly rare element. Recycling will help but demand will in 50 years way outstrip supply.
Battery technology is a good example of “All the easy things have already been done”
Several well-funded Chinese companies are trying to achieve this breakthrough, too. And don’t dismiss them—most as attached to major universities in the Beijing and Shanghai metro areas, places with a lot of very smart people that know things like graphene sheets could become vital in dramatically increasing the storage density of lithium-ion batteries.
Wanting a battery to be capable of storing huge amounts of energy and sustaining multiple charges and discharges doesn’t make it true.
For every chemical process (reaction), there is a specific maximum amount of energy that can be stored and released. To increase the amount, you have to find a new chemical process.
Not unlike the transistor. Silicon is an insulator, but add just a tiny bit of arsenic, and you have a semiconductor.
The laws of physics trump political correctness.
The laws of physics trump political correctness.
I think that technology has asymptotic limits... during the period of growth when it seems exponential, people start to think there is no limit to what technology can produce.
Thus you get stuff like Star Trek, transporters, warp drive, etc. The truth is that EVERYTHING has limits. The only thing that seems to have no limit is human arrogance and stupidity, which is yet another limiting factor on technology.
Another fluke job.
“Why We Don’t Have Battery Breakthroughs?”
See: ‘Law of Thermodynamics”.
Given our set conditions on earth ... I.E the basics like gravity, earth rotations and what have you, It takes the same amount of energy to move a given mass no matter what form of energy you use.
So if you’re using electricity generated by fossil fuels then an electric car saves you nothing.
“And, of course, electric vehicles avoid the pollution associated with conventional cars, including emissions of carbon dioxide from burning gasoline.”
Electricity is like government money to leftists. They think both appear out of nowhere.
Ha...
I did not know that.
Guess I fluked up on that one.
And, of course, any pollution from the source of electricity necessary to recharge the thing is discounted.And, of course, electric vehicles avoid the pollution associated with conventional cars, including emissions of carbon dioxide from burning gasoline.
And (of course, as the writer of the article would say) CO2 emissions are headed straight North whether you magically eliminate emissions by your car (even if you used nuclear or water power to generate the electricity) or not. Because China and India are stamping out coal-fired electric power plants like cookies and - whatever propaganda China may put out about reducing China’s CO2 emissions REAL SOON NOW, that is about like Congress promising to balance the budget ten years hence.AND, of course, the actual effect, if any, of such emissions on geological-scale weather/climate are speculative since scientists don’t know why the temperature is doing what it is doing right now, let alone what it will do in the future.
I would love to see an EV that would tow a camper or a 23’ foot boat that will carry a family of 6. When Ford do that, I’ll buy it. :-)
I would love to see an EV that would tow a camper or a 23’ foot boat that will carry a family of 6. When Ford do that, I’ll buy it. :-)
What brand of mayonnaise do you think Sandra Fluke uses on her hair?
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