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"Nanoscoop" Material Promises 40x Faster Charging of Batteries

Researchers at Rensselaer Polytechnic Institute (RPI) in Troy, NY have developed a new type of nanomaterial they have dubbed “nanoscoops” because of its resemblance to an ice cream cone. The novel material promises to enable li-ion batteries to charge 40 to 60 times faster than conventional batteries.

The research, which was led by Professor Nikhil Koratkar and initially published in the journal Nano Letters, demonstrated how a “nanoscoop” electrode was able to achieve its faster charge in 100 continuous charge/discharge cycles.

“Charging my laptop or cell phone in a few minutes, rather than an hour, sounds pretty good to me,” said Koratkar in a RPI press release. “By using our nanoscoops as the anode architecture for Li-ion rechargeable batteries, this is a very real prospect. Moreover, this technology could potentially be ramped up to suit the demanding needs of batteries for electric automobiles.”

While this technology could increase the charge/discharge rates of li-ion batteries, I didn’t see any discussion within the coverage of the research whether it will improve the watt-hours of energy per kilogram (Wh/kg), which I noted last month to much criticism Secretary Steven Chu had suggested should reach a level of 1000Wh/kg in electric vehicles to compete with fossil fuels.

At any rate, Koratkar also intriguingly suggests in the piece that the nanoscoop material could enable the bringing together of supercapacitors—used for power-intensive functions such as starting the car—and traditional batteries—that provide high energy density for normal driving—into one single battery unit.

The trick to the nanoscoops capabilities lies in its composition, structure and size. In composition and structure it sounds like a good ice cream cone. They are “made from a carbon (C) nanorod base topped with a thin layer of nanoscale aluminum (Al) and a “scoop” of nanoscale silicon (Si)”.

It is this structure that accounts for the material’s ability to accept and discharge Li ion batteries at extremely fast rates and without causing damage. The layered structure of the nanoscoop transfers strain from the carbon layer to the aluminum layer and then finally to the silicon.

The next steps for the researchers will be to overcome the lack of overall mass of the electrode. They are investigating growing longer scoops or perhaps stacking numerous scoops on top of each other.

Just Because It's Smaller Doesn't Make It Nanotechnology

Andrew Maynard is often the first stop for mainstream journalists when they need to cover the story of nanotech. This is no doubt due to Maynard’s unique blend of scientific knowledge and his ability to communicate the science effectively to both the layman and his fellow scientist.

So when PBS decided to launch a new program as part of the Nova series entitled Making Stuff, hosted by New York Times technology columnist David Pogue, they must have been a little concerned that Maynard was less than enthusiastic about a clip from the program’s coverage of bioengineered materials both in terms of its ethical and safety point of view, the latter of which is Maynard’s bailiwick.

So David Levin, Nova's resident podcaster, contacted Maynard and they produced a podcast entitled The Dangers of Nanotech. Well, if anyone thought the program was being too soft on the safety aspect of bioengineered materials, it appears they more than made up for it by creating an alarmist title for a podcast on nanotechnology.

But Maynard tries mightily to fight back the alarmism by stating out front, “At the moment, the health issues [around nanotech] are very speculative.” And he continues on this vein balancing concerns with what we really know, not an easy task to perform.

But there is a notable omission in the whole discussion. We get initially the typical scare screed: “Nanotechnology is in everything from our pants to sunscreen, but how safe is it really?” And then not once in this nine-minute podcast do we get a discussion on the safety of the products that contain nanotech. It is like deciding to do a safety segment on electronics and you decide to spend the entire presentation on the toxicity of mercury. That’s all fine and good but shouldn’t we talk about the lifecycle of the products, just for 30 seconds or so.

The actual of topic of "Making Stuff" with nanotechnology is scheduled to air initially on January 26th, and is ingeniously entitled Making Stuff: Smaller. It is a pity that the description of the episode feels it necessary to trot out “micro-robots that probe the human body” as what the future holds as technology continues to go smaller. But I suppose that’s what really grabs the audience’s attention when it comes to nanotech.

But just a tip to the program’s producers in case they’re interested, just because the robots are small doesn’t make them nanobots, or even nanotech-related. in fact, the practice of combining the concepts of nanotechnology and micro robots really just confuses the matter.

Graphene for Electrodes in Organic Solar Cells Could Reduce Costs

While organic solar cells have been promising an inexpensive way to exploit solar power in comparison to their silicon-based cousins, things have not panned out in the marketplace quite as expected with flexible solar cells being rolled out onto roofs like asphalt roofing material.

But researchers at MIT believe they have overcome at least one obstacle with organic solar cells by finding a material for the electrodes that will match organic cells’ flexibility and replace the expensive indium-tin-oxide (ITO).

The magic material is none other than graphene, the wonder material of the latter half of the first decade of the 21st century.

Of course, this is not the first time that graphene has been discussed in relation to organic solar cells, but actually getting the graphene to go where you want it to go remained an obstacle.

In a paper published in the Dec. 17 edition of the Institute of Physics journal Nanotechnology, MIT professors Jing Kong and Vladimir Bulovic demonstrated how they were able to overcome the material’s resistance to adhering to the panel. The solution turned out to be a doping process that introduced impurities into the graphene that made it bond with the panel.

After having overcome this manufacturing obstacle, the graphene performed much like ITO except that it was more flexible and also transparent to allow all available sunlight to pass through. But perhaps most importantly, carbon is far more abundant than the increasingly rare ITO, which would likely reduce the cost of the product.

Big Story in Nanotech for Last Decade: The Funding Gap

In a gesture to recognize its tenth anniversary, TNTLog asked its readers what has been the best and worst stories surrounding nanotechnology in the last 10 years.

In my estimation, the big story in nanotech would be the funding gap, or, as it might alternately be termed, the innovation gap.

It seems governments around the world are anxious to invest billions of dollars into nanotechnology and then leave the small start-ups that this investment germinates to die on the vine while they are left to search in vain for the funding that could bring their technologies to market.

While IBM and other large companies, especially in the electronics and chemical industries, have invested heavily in nanotech, and this likely accounts for a large portion of non-government investment in the field, funding for small to medium enterprises attempting to bring a product to market just has not been strong or effective enough.

I have argued that financial institutions that have typically funded start-ups like these, such as venture capitalists or other private capital institutions, just have not been effective at bridging the seven to ten year of funding that these start-ups need. 

I bring this all up because we have another cautionary tale of how a company with a promising technology and some initial funding, ends up in bankruptcy due to little more than under capitalization.

The story of Carbon Nanoprobes Inc.’s failure is presented to us in contrast to the success of Saladax Biomedical Inc. The story gives us no information on why Saladax was successful in raising more financing than Carbon Nanoprobes. It could be any number of reasons, but a very likely reason would be that the ROI horizon was so far off for Carbon Nanoprobes that it constituted a much riskier investment.

This has been the overarching issue for nanotechnology’s development in the last 10 years. A generation of investors has been so conditioned by the era and hedge funds fueled by derivatives and glorified Ponzi schemes that the prospect of having to wait 7 to 10 years for their investment to pay off is just beyond their attention span.

I suppose that some Darwinian-influenced economic theory would be plugged in right about now, i.e. these companies failed because they were not strong enough.

Fair enough. But we are facing challenges so grand now in terms of feeding our growing population, supplying energy and even having clean drinking water that maybe we should find some way of supporting innovation in areas where we desperately need it, instead of allowing those potential solutions to disappear because it presented too much risk for financiers’ portfolios.

Where are my solutions? I don’t have a solution of my own but I like the direction that both Andrew Maynard and Tim Harper are going with the innovation framework they are developing as part of their roles with the World Economic Forum. 

Perhaps there are better ways to separate the wheat from the chaff in emerging technologies than just letting the financiers decide.

Is Determining the Impact of Nanotechnology a Useful Exercise?

The latest organization to take a crack at sorting out how nanotechnology is going to make its impact is the Organization for Economic Cooperation and Development (OECD), which has just published a report entitled The Impacts of Nanotechnology on Companies.

Sorting out the impact of nanotechnology is a favorite pastime for governments and extra-governmental organizations , and this time the method involves performing 51 case studies of companies from all over the world and all different sizes. We already have a breakdown of the report from Nanowerk that gives us the main points. And as you might expect when distilling a 111-page report into a blog post, the main points seem pretty…well, predictable.

We get the none-too-illuminating insights that nanotechnology is an enabling technology, larger companies can excel at the early stages of assimilating nanotechnology into their products and that nanotechnology is a complex field due to its calling upon various disciplines.

It seems that many of the reports quasi determinations have been long understood by anyone in the business of bringing to market a nano-enabled product, such as VCs are absent from the funding mechanisms available for companies trying to commericalize a nano-eanbled product.

Sometimes I wonder who this kind of information is supposed to benefit. It seems to be researched and written by bureaucrats, who then are the people who read and base policy upon it and then it all gets ignored, or worse followed.

Silver Nanoparticles Enable Real-time, Hand-held Biomarker Measurement Device for Athletes

While emerging technologies have often found early adoption in military applications where spendthrift practices have resulted in $500 toilet seats, perhaps the new area for prodigious spending on emerging technologies is in recreational sports.

Weekend athletes can now use carbon nanotubes in their tennis racquets, golf clubs and bicycles. And they’re willing to spend big bucks for the privilege.

So, it’s little surprise that a hand-held, self-diagnostic device is being touted as a tool for British athletes training for 2012 London Olympics rather than for application in the multiple-billon-dollar, point-of-care (PoC) market.

Argento Diagnostics, of course, is not ignoring the vast PoC market, but just like about every other company either making nanomaterials or developing a finished product enabled by nanomaterials, they are initially pursing sports applications for a very attractive introduction to the commercial marketplace.

On the one hand, you have a market that will provide all sorts of publicity for your technology (you can imagine that UK-based Argento after the London Olympics will be getting David Beckham to spit into their device) and then you have middle-aged, weekend athletes willing to spend any amount of money to ensure that they can improve their record-best time in their next triathlon.

However, what might make sense for an athlete training for an Olympic event, may not necessarily translate into use by a regular Joe. Either way, this application angle has won the technology a fair bit more media pixels than if they just been plodding through doctor’s offices trying to get them to use the device.

Artificial Palladium Is a Big Story in the Midst of Japan's Rare Earth Squeeze

The story of Japanese researchers who were able to combine rhodium and silver in a way to make an artificial palladium alloy “with nanotechnology” has been making the rounds this week as a new wrinkle in the medieval practice of alchemy.

However, I see it a bit differently. It seems to me more like a brilliant stroke of geo-economic politics.

This past Summer there was a rather significant imbroglio between China and Japan in which it was reported that China was suspending delivery of rare earth minerals to Japan over a fishing boat incident. (The issue of China’s current stranglehold on rare earths I covered myself here last Spring.)

Whatever the true story is on this Japan/China incident, ever since Japan has been looking into finding new sources of rare earths. It’s not like these rare earth minerals don’t exist anywhere else, it’s just that the rest of the world has stopped mining for them. In fact, as recently as the 1980s, the US dominated production.

While palladium is not strictly speaking a rare earth mineral, but rather a chemical element and belongs to the platinum group of metals, it is quite rare and in high demand from the electronics industry. So being able to synthesize palladium from the elements of rhodium and silver could conceivably make Japan less dependent on its sources for this element.

Geo-economic politics aside, the claims of this research are quite impressive, although some circles are already expressing skepticism over the results.

While one of the charges is that Japanese academics are typically quick to patent anything, even if it has questionable commercial applications, I imagine the context of the rare earth squeeze made the sound of trumpeting a new way to make palladium too attractive to pass up.

Building 3D Batteries from the Bottom Up with Coated Nanowires

To continue on with the string of nanotechnology developments at the end of last year (here and here) that were aimed at improving the battery, I start this New Year with another such story this time coming from researchers at Rice University.

This news actually broke in December when it was originally published in the December 6th online edition of Nanoletters.

The research, which was led by Pulickel Ajayan, managed to find a way to coat nanowires with PMMA coating that provides good insulation from the counter electrode while still allowing ions to pass easily through.

This minimized separation between two electrodes manages to make the battery much more efficient.

"In a battery, you have two electrodes separated by a thick barrier," said Ajayan, professor in mechanical engineering and materials science and of chemistry. "The challenge is to bring everything into close proximity so this electrochemistry becomes much more efficient."

To achieve this, the Ajayan and his lead researchers Sanketh Gowda and Arava Leela Mohana Reddy took the concept of 3D batteries and coated millions of nanowires to create the 3D structure from the bottom up.

“We wanted to figure out how the proposed 3-D designs of batteries can be built from the nanoscale up," said Gowda, a graduate student in Ajayan's lab. "By increasing the height of the nanowires, we can increase the amount of energy stored while keeping the lithium ion diffusion distance constant."

As Gowda readily admits in the news release, 3D designs are nothing new. However, the achievement here was the process they developed for coating the nanowires in the PMMA without any break in the coating.

The process involves the growing of 10-micron-long nanowires through electrodisposition in the pores of an anoidized alumina template. They then drop-coated PMMA onto the nanowire array resulting in an even casing from top to bottom. 

The result of this work is ultimately expected to be batteries for scalable microdevices that possess a greater surface area than thin-film batteries.


The Premiere of the Nanoclast Awards

While I have been contributing to IEEE Spectrum Online’s blogosphere since June 2007, 2010 marks the first full year of writing a stand-alone blog.

To mark this occasion I am going to offer up for the first time the Nanoclast Awards that may, or may not, become an annual event.

With little deliberation on the matter, the awards will be broken into three categories. They are: Best Advancement in Microscopy, Best Advancement in Nanomaterials, and finally no Nanoclast award ceremony would be complete without the Most Annoying Nano-related Story of the Year.

Let’s proceed to the nominees.

For our first category, “Best Advancement in Microscopy” it has been a banner year with some groundbreaking research. Here are the nominees:

First, IBM's Breakthrough in STM Imaging that now makes it possible to take images of an atom at nanosecond speeds as opposed to mere millisecond speeds.

The second nominee are the researchers at Ohio State University and the University of Hamburg in Germany who developed a custom-made scanning tunneling microscopy (STM) that reportedly took the very first images of the spin of an electron.

Our third and final nominee in this category is again Ohio State University this time in cooperation with Oak Ridge National Laboratory in using every conceivable microscopy tool in their arsenal to determine the causes for the demise of rechargeable batteries.

And the winner is…IBM’s breakthrough in STM imaging. I have made this selection from such a strong group of nominees based on the researchers' willingness to put their work into some perspective. While the press were mentioning “molecular electronics” and “Moore’s Law” they were saying, “Wait a minute.”

Our second category, “Best Advancement in Nanomaterials” not only had strong candidates but a lot of them.

With little surprise, our first nominee is research into graphene. After being the new darling of the advanced material community for the past 6 years, this year its discovery got the Nobel Prize in Physics for Andre Geim and Konstantin Novoselov.

So, our first nominee goes to IBM again for developing a simpler approach for creating a band gap in graphene.

Our second nominee are the researchers at Oregon State University who developed a method for creating a metal-insulator-metal (MIM) diode architecture that in the past had proven difficult to produce with high yield and top-level performance.

And our third and final nominee for this truncated list of nominees is a bit of a change from the previous two and a bit more humble in its aims but still managed to generate a fair amount of interest here on this blog. That is the coating that could make an average (not stealth) plane invisible to radar.

And our winner is…IBM’s ability to create a band gap in graphene. Graphene may be a wonder material but its electronic applications are going to be severely limited if they can’t find a way of creating a band gap for it. IBM’s research here may be just the ticket.

Our third and final category, “Most Annoying Nano-related Story of the Year” will come from three areas. They are hype: exaggerating the potential of nanotechnology; fear mongering: turning nanotechnology into all the wicked things that have resulted from man’s history of industrialization; and finally just plain wrong headedness: just examples of such sloppy thinking you lose all patience.

In the area of hype, we have our first nominee, which represents the story template that starts off telling us that nanotechnology is nothing but hype and then sets about trying to hype up its potential applications. Really annoying.

Our second nominee is an example of fear mongering that has become quite popular and that is confusing economic systems like capitalism and political systems like totalitarianism with nanotechnology. Either sadly misguided or deliberately misguiding others.

Our third and final nominee is for an example of an over taxed journalist who just begins to lose their way in a story and loses you in the process. Just a sad display. 

And our winner is…none of the above but instead the story that managed to combine elements of all three. What happens when a Pulitzer Prize winning journalist decides he’s going to blow the lid off of nanotechnology? You get this annoying bit of slapstick.

I hope you enjoyed our premier of the Nanoclast Awards, and I am looking forward to see what 2011 will have to offer.

Nanostructured Paper Leads to Printable Ultracapacitors

Breakthroughs in creating printable ultracapacitors and batteries have been coming fast and furious in the last 18 months.

Perhaps the latest news on the pages of IEEE Spectrum that details how two companies are printing batteries and ultracapacitors is the most promising to date.

The spectrum article reports on a printed solid-state lithium battery developed by Planar Energy Devices that manages to replace the liquid electrolyte typically found in lithium-ion batteries with a ceramic electrolyte. The results are that it performs much better than traditional li-ion batteries, achieving 400 watt-hours of energy per kilogram and can last for tens of thousands recharge cycles.

While this is at least a factor of two better than traditional batteries, for electrical vehicles it still falls short of the 1000Wh/kg target that was suggested by Energy Secretary Steven Chu to be what is needed for a power source to replace fossil fuels in automobiles.

But if Tesla can make a buck selling sports cars with 6,831 lithium-ion batteries that weigh all together about 1500 lbs, surely a car company could do better with the lighter, cheaper to produce, greater energy density and longer life cycle of the batteries being offered by Planar.

The other company highlighted in the article is Paper Battery, which produces an ultracapacitor that uses a nanostructured paper as the separator between the electrodes in the ultraccapcitor. It looks as though initial applications will be in the areas of a medical diagnostic devices and thin film solar panels

If these two companies are any indication, we should expect things to start heating up in the printed battery and ultracapacitor space fairly soon.



IEEE Spectrum’s nanotechnology blog, featuring news and analysis about the development, applications, and future of science and technology at the nanoscale.

Dexter Johnson
Madrid, Spain
Rachel Courtland
Associate Editor, IEEE Spectrum
New York, NY
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