Tag Archives: Queensland University of Technology

The joys of an electronic ‘pill’: Could Canadian Olympic athletes’ training be hacked?

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Lori Ewing (Canadian Press) in an  August 3, 2018 article on the Canadian Broadcasting Corporation news website, heralds a new technology intended for the 2020 Olympics in Tokyo (Japan) but being tested now for the 2018 North American, Central American and Caribbean Athletics Association (NACAC) Track & Field Championships, known as Toronto 2018: Track & Field in the 6ix (Aug. 10-12, 2018) competition.

It’s described as a ‘computerized pill’ that will allow athletes to regulate their body temperature during competition or training workouts, from the August 3, 2018 article,

“We can take someone like Evan [Dunfee, a race walker], have him swallow the little pill, do a full four-hour workout, and then come back and download the whole thing, so we get from data core temperature every 30 seconds through that whole workout,” said Trent Stellingwerff, a sport scientist who works with Canada’s Olympic athletes.

“The two biggest factors of core temperature are obviously the outdoor humidex, heat and humidity, but also exercise intensity.”

Bluetooth technology allows Stellingwerff to gather immediate data with a handheld device — think a tricorder in “Star Trek.” The ingestible device also stores measurements for up to 16 hours when away from the monitor which can be wirelessly transmitted when back in range.

“That pill is going to change the way that we understand how the body responds to heat, because we just get so much information that wasn’t possible before,” Dunfee said. “Swallow a pill, after the race or after the training session, Trent will come up, and just hold the phone [emphasis mine] to your stomach and download all the information. It’s pretty crazy.”

First off, it’s probably not a pill or tablet but a gelcap and it sounds like the device is a wireless biosensor. As Ewing notes, the device collects data and transmits it.

Here’s how the French company, BodyCap, supplying the technology describes their product, from the company’s e-Celsius Performance webpage, (assuming this is the product being used),

Continuous core body temperature measurement

Main applications are:

Risk reduction for people in extreme situations, such as elite athletes. During exercise in a hot environment, thermal stress is amplified by the external temperature and the environment’s humidity. The saturation of the body’s thermoregulation mechanism can quickly cause hyperthermia to levels that may cause nausea, fainting or death.

Performance optimisation for elite athletes.This ingestible pill leaves the user fully mobile. The device keeps a continuous record of temperature during training session, competition and during the recovery phase. The data can then be used to correlate thermoregulation with performances. This enable the development of customised training protocols for each athlete.

e-Celsius Performance® can be used for all sports, including water sports. Its application is best suited to sports that are physically intensive like football, rugby, cycling, long distance running, tennis or those that take place in environments with extreme temperature conditions, like diving or skiing.

e-Celsius Performance®, is a miniaturised ingestible electronic pill that wirelessly transmits a continuous measurement of gastrointestinal temperature. [emphasis mine]

The data are stored on a monitor called e-Viewer Performance®. This device [emphases mine] shows alerts if the measurement is outside the desired range. The activation box is used to turn the pill on from standby mode and connect the e-Celsius Performance pill with the monitor for data collection in either real time or by recovery from the internal memory of e-Celsius Performance®. Each monitor can be used with up to three pills at once to enable extended use.

The monitor’s interface allows the user to download data to a PC/ Mac for storage. The pill is safe, non-invasive and easy to use, leaving the gastric system after one or two days, [emphasis mine] depending on individual transit time.

I found Dunfee’s description mildly confusing but that can be traced to his mention of wireless transmission to a phone. Ewing describes a handheld device which is consistent with the company’s product description. There is no mention of the potential for hacking but I would hope Athletics Canada and BodyCap are keeping up with current concerns over hacking and interference (e.g., Facebook/Cambridge Analytica, Russians and the 2016 US election, Roberto Rocha’s Aug. 3, 2018 article for CBC titled: Data sheds light on how Russian Twitter trolls targeted Canadians, etc.).

Moving on, this type of technology was first featured here in a February 11, 2014 posting (scroll down to the gif where an electronic circuit dissolves in water) and again in a November 23, 2015 posting about wearable and ingestible technologies but this is the first real life application I’ve seen for it.

Coincidentally, an August 2, 2018 Frontiers [Publishing] news release on EurekAlert announced this piece of research (published in June 2018) questioning whether we need this much data and whether these devices work as promoted,

Wearable [and, in the future, ingestible?] devices are increasingly bought to track and measure health and sports performance: [emphasis mine] from the number of steps walked each day to a person’s metabolic efficiency, from the quality of brain function to the quantity of oxygen inhaled while asleep. But the truth is we know very little about how well these sensors and machines work [emphasis mine]– let alone whether they deliver useful information, according to a new review published in Frontiers in Physiology.

“Despite the fact that we live in an era of ‘big data,’ we know surprisingly little about the suitability or effectiveness of these devices,” says lead author Dr Jonathan Peake of the School of Biomedical Sciences and Institute of Health and Biomedical Innovation at the Queensland University of Technology in Australia. “Only five percent of these devices have been formally validated.”

The authors reviewed information on devices used both by everyday people desiring to keep track of their physical and psychological health and by athletes training to achieve certain performance levels. [emphases mine] The devices — ranging from so-called wrist trackers to smart garments and body sensors [emphasis mine] designed to track our body’s vital signs and responses to stress and environmental influences — fall into six categories:

  • devices for monitoring hydration status and metabolism
  • devices, garments and mobile applications for monitoring physical and psychological stress
  • wearable devices that provide physical biofeedback (e.g., muscle stimulation, haptic feedback)
  • devices that provide cognitive feedback and training
  • devices and applications for monitoring and promoting sleep
  • devices and applications for evaluating concussion

The authors investigated key issues, such as: what the technology claims to do; whether the technology has been independently validated against some recognized standards; whether the technology is reliable and what, if any, calibration is needed; and finally, whether the item is commercially available or still under development.

The authors say that technology developed for research purposes generally seems to be more credible than devices created purely for commercial reasons.

“What is critical to understand here is that while most of these technologies are not labeled as ‘medical devices’ per se, their very existence, let alone the accompanying marketing, conveys a sensibility that they can be used to measure a standard of health,” says Peake. “There are ethical issues with this assumption that need to be addressed.” [emphases mine]

For example, self-diagnosis based on self-gathered data could be inconsistent with clinical analysis based on a medical professional’s assessment. And just as body mass index charts of the past really only provided general guidelines and didn’t take into account a person’s genetic predisposition or athletic build, today’s technology is similarly limited.

The authors are particularly concerned about those technologies that seek to confirm or correlate whether someone has sustained or recovered from a concussion, whether from sports or military service.

“We have to be very careful here because there is so much variability,” says Peake. “The technology could be quite useful, but it can’t and should never replace assessment by a trained medical professional.”

Speaking generally again now, Peake says it is important to establish whether using wearable devices affects people’s knowledge and attitude about their own health and whether paying such close attention to our bodies could in fact create a harmful obsession with personal health, either for individuals using the devices, or for family members. Still, self-monitoring may reveal undiagnosed health problems, said Peake, although population data is more likely to point to false positives.

“What we do know is that we need to start studying these devices and the trends they are creating,” says Peake. “This is a booming industry.”

In fact, a March 2018 study by P&S Market Research indicates the wearable market is expected to generate $48.2 billion in revenue by 2023. That’s a mere five years into the future.”

The authors highlight a number of areas for investigation in order to develop reasonable consumer policies around this growing industry. These include how rigorously the device/technology has been evaluated and the strength of evidence that the device/technology actually produces the desired outcomes.

“And I’ll add a final question: Is wearing a device that continuously tracks your body’s actions, your brain activity, and your metabolic function — then wirelessly transmits that data to either a cloud-based databank or some other storage — safe, for users? Will it help us improve our health?” asked Peake. “We need to ask these questions and research the answers.”

The authors were not examining ingestible biosensors nor were they examining any issues related to data about core temperatures but it would seem that some of the same issues could apply especially if and when this technology is brought to the consumer market.

Here’s a link to the and a citation for the paper,

Critical Review of Consumer Wearables, Mobile Applications, and Equipment for Providing Biofeedback, Monitoring Stress, and Sleep in Physically Active Populations by Jonathan M. Peake, Graham Kerr, and John P. Sullivan. Front. Physiol., 28 June 2018 | https://doi.org/10.3389/fphys.2018.00743

This paper is open access.

Making graphene cheaply by using soybeans

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One of the issues with new materials is being able to produce them in a commercially viable fashion and it seems that researchers in Australia may have helped  to do that with graphene. From a Feb. 15, 2017 news item on phys.org,

A breakthrough by CSIRO-led [Australia’s Commonwealth Scientific and Industrial Research Organisation] scientists has made the world’s strongest material more commercially viable, thanks to the humble soybean.

From a Feb. 15, (?) 2017 CSIRO press release (also on EurekAlert), which originated the news item, expands on the theme (Note: A link has been removed),

Graphene is a carbon material that is one atom thick.

Its thin composition and high conductivity means it is used in applications ranging from miniaturised electronics to biomedical devices.

These properties also enable thinner wire connections; providing extensive benefits for computers, solar panels, batteries, sensors and other devices.

Until now, the high cost of graphene production has been the major roadblock in its commercialisation.

Previously, graphene was grown in a highly-controlled environment with explosive compressed gases, requiring long hours of operation at high temperatures and extensive vacuum processing.

CSIRO scientists have developed a novel “GraphAir” technology which eliminates the need for such a highly-controlled environment.

The technology grows graphene film in ambient air with a natural precursor, making its production faster and simpler.

“This ambient-air process for graphene fabrication is fast, simple, safe, potentially scalable, and integration-friendly,” CSIRO scientist Dr Zhao Jun Han, co-author of the paper published today in Nature Communications said.

“Our unique technology is expected to reduce the cost of graphene production and improve the uptake in new applications.”

GraphAir transforms soybean oil – a renewable, natural material – into graphene films in a single step.

“Our GraphAir technology results in good and transformable graphene properties, comparable to graphene made by conventional methods,” CSIRO scientist and co-author of the study Dr Dong Han Seo said.

With heat, soybean oil breaks down into a range of carbon building units that are essential for the synthesis of graphene.

The team also transformed other types of renewable and even waste oil, such as those leftover from barbecues or cooking, into graphene films.

“We can now recycle waste oils that would have otherwise been discarded and transform them into something useful,” Dr Seo said.

The potential applications of graphene include water filtration and purification, renewable energy, sensors, personalised healthcare and medicine, to name a few.

Graphene has excellent electronic, mechanical, thermal and optical properties as well.

Its uses range from improving battery performance in energy devices, to cheaper solar panels.

CSIRO are looking to partner with industry to find new uses for graphene.

Researchers from The University of Sydney, University of Technology Sydney and The Queensland University of Technology also contributed to this work.

Here’s a link to and a citation for the paper,

Single-step ambient-air synthesis of graphene from renewable precursors as electrochemical genosensor by Dong Han Seo, Shafique Pineda, Jinghua Fang, Yesim Gozukara, Samuel Yick, Avi Bendavid, Simon Kwai Hung Lam, Adrian T. Murdock, Anthony B. Murphy, Zhao Jun Han, & Kostya (Ken) Ostrikov. Nature Communications 8, Article number: 14217 (2017) doi:10.1038/ncomms14217 Published online: 30 January 2017

This is an open access paper.

Supercapacitors* on automobiles

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Queensland University of Technology* (QUT; Australia) researchers are hopeful they can adapt supercapacitors in the form of a fine film tor use in electric vehicles making them more energy-efficient. From a Nov. 6, 2014 news item on ScienceDaily,

A car powered by its own body panels could soon be driving on our roads after a breakthrough in nanotechnology research by a QUT team.

Researchers have developed lightweight “supercapacitors” that can be combined with regular batteries to dramatically boost the power of an electric car.

The discovery was made by Postdoctoral Research Fellow Dr Jinzhang Liu, Professor Nunzio Motta and PhD researcher Marco Notarianni, from QUT’s Science and Engineering Faculty — Institute for Future Environments, and PhD researcher Francesca Mirri and Professor Matteo Pasquali, from Rice University in Houston, in the United States.

A Nov. 6, 2014 QUT news release, which originated the news item, describes supercapacitors, the research, and the need for this research in more detail,

The supercapacitors – a “sandwich” of electrolyte between two all-carbon electrodes – were made into a thin and extremely strong film with a high power density.

The film could be embedded in a car’s body panels, roof, doors, bonnet and floor – storing enough energy to turbocharge an electric car’s battery in just a few minutes.

“Vehicles need an extra energy spurt for acceleration, and this is where supercapacitors come in. They hold a limited amount of charge, but they are able to deliver it very quickly, making them the perfect complement to mass-storage batteries,” he said.

“Supercapacitors offer a high power output in a short time, meaning a faster acceleration rate of the car and a charging time of just a few minutes, compared to several hours for a standard electric car battery.”

Dr Liu said currently the “energy density” of a supercapacitor is lower than a standard lithium ion (Li-Ion) battery, but its “high power density”, or ability to release power in a short time, is “far beyond” a conventional battery.

“Supercapacitors are presently combined with standard Li-Ion batteries to power electric cars, with a substantial weight reduction and increase in performance,” he said.

“In the future, it is hoped the supercapacitor will be developed to store more energy than a Li-Ion battery while retaining the ability to release its energy up to 10 times faster – meaning the car could be entirely powered by the supercapacitors in its body panels.

“After one full charge this car should be able to run up to 500km – similar to a petrol-powered car and more than double the current limit of an electric car.”

Dr Liu said the technology would also potentially be used for rapid charges of other battery-powered devices.

“For example, by putting the film on the back of a smart phone to charge it extremely quickly,” he said.

The discovery may be a game-changer for the automotive industry, with significant impacts on financial, as well as environmental, factors.

“We are using cheap carbon materials to make supercapacitors and the price of industry scale production will be low,” Professor Motta said.

“The price of Li-Ion batteries cannot decrease a lot because the price of Lithium remains high. This technique does not rely on metals and other toxic materials either, so it is environmentally friendly if it needs to be disposed of.”

A Nov. 10, 2014 news item on Azonano describes the Rice University (Texas, US) contribution to this work,

Rice University scientist Matteo Pasquali and his team contributed to two new papers that suggest the nano-infused body of a car may someday power the car itself.

Rice supplied high-performance carbon nanotube films and input on the device design to scientists at the Queensland University of Technology in Australia for the creation of lightweight films containing supercapacitors that charge quickly and store energy. The inventors hope to use the films as part of composite car doors, fenders, roofs and other body panels to significantly boost the power of electric vehicles.

A Nov. 7, 2014 Rice University news release, which originated the news item, offers a few technical details about the film being proposed for use as a supercapacitor on car panels,

Researchers in the Queensland lab of scientist Nunzio Motta combined exfoliated graphene and entangled multiwalled carbon nanotubes combined with plastic, paper and a gelled electrolyte to produce the flexible, solid-state supercapacitors.

“Nunzio’s team is making important advances in the energy-storage area, and we were glad to see that our carbon nanotube film technology was able to provide breakthrough current collection capability to further improve their devices,” said Pasquali, a Rice professor of chemical and biomolecular engineering and chemistry. “This nice collaboration is definitely bottom-up, as one of Nunzio’s Ph.D. students, Marco Notarianni, spent a year in our lab during his Master of Science research period a few years ago.”

“We built on our earlier work on CNT films published in ACS Nano, where we developed a solution-based technique to produce carbon nanotube films for transparent electrodes in displays,” said Francesca Mirri, a graduate student in Pasquali’s research group and co-author of the papers. “Now we see that carbon nanotube films produced by the solution-processing method can be applied in several areas.”

As currently designed, the supercapacitors can be charged through regenerative braking and are intended to work alongside the lithium-ion batteries in electric vehicles, said co-author Notarianni, a Queensland graduate student.

“Vehicles need an extra energy spurt for acceleration, and this is where supercapacitors come in. They hold a limited amount of charge, but with their high power density, deliver it very quickly, making them the perfect complement to mass-storage batteries,” he said.

Because hundreds of film supercapacitors are used in the panel, the electric energy required to power the car’s battery can be stored in the car body. “Supercapacitors offer a high power output in a short time, meaning a faster acceleration rate of the car and a charging time of just a few minutes, compared with several hours for a standard electric car battery,” Notarianni said.

The researchers foresee such panels will eventually replace standard lithium-ion batteries. “In the future, it is hoped the supercapacitor will be developed to store more energy than an ionic battery while retaining the ability to release its energy up to 10 times faster – meaning the car would be powered by the supercapacitors in its body panels,” said Queensland postdoctoral researcher Jinzhang Liu.

Here’s an image of graphene infused with carbon nantoubes used in the supercapacitor film,

A scanning electron microscope image shows freestanding graphene film with carbon nanotubes attached. The material is part of a project to create lightweight films containing super capacitors that charge quickly and store energy. Courtesy of Nunzio Motta/Queensland University of Technology - See more at: http://news.rice.edu/2014/11/07/supercharged-panels-may-power-cars/#sthash.0RPsIbMY.dpuf

A scanning electron microscope image shows freestanding graphene film with carbon nanotubes attached. The material is part of a project to create lightweight films containing super capacitors that charge quickly and store energy. Courtesy of Nunzio Motta/Queensland University of Technology

Here are links to and citations for the two papers published by the researchers,

Graphene-based supercapacitor with carbon nanotube film as highly efficient current collector by Marco Notarianni, Jinzhang Liu, Francesca Mirri, Matteo Pasquali, and Nunzio Motta. Nanotechnology Volume 25 Number 43 doi:10.1088/0957-4484/25/43/435405

High performance all-carbon thin film supercapacitors by Jinzhang Liu, Francesca Mirri, Marco Notarianni, Matteo Pasquali, and Nunzio Motta. Journal of Power Sources Volume 274, 15 January 2015, Pages 823–830 DOI: 10.1016/j.jpowsour.2014.10.104

Both articles are behind paywalls.

One final note, Dexter Johnson provides some insight into issues with graphene-based supercapacitors and what makes this proposed application attractive in his Nov. 7, 2014 post on the Nanoclast blog (on the IEEE [Institute of Electrical and Electronics Engineers] website; Note: Links have been removed),

The hope has been that someone could make graphene electrodes for supercapacitors that would boost their energy density into the range of chemical-based batteries. The supercapacitors currently on the market have on average an energy density around 28 Wh/kg, whereas a Li-ion battery holds about 200Wh/kg. That’s a big gap to fill.

The research in the field thus far has indicated that graphene’s achievable surface area in real devices—the factor that determines how many ions a supercapacitor electrode can store, and therefore its energy density—is not any better than traditional activated carbon. In fact, it may not be much better than a used cigarette butt.

Though graphene may not help increase supercapacitors’ energy density, its usefulness in this application may lie in the fact that its natural high conductivity will allow superconductors to operate at higher frequencies than those that are currently on the market. Another likely benefit that graphene will yield comes from the fact that it can be structured and scaled down, unlike other supercapacitor materials.

I recommend reading Dexter’s commentary in its entirety.

*’University of Queensland’ corrected to “Queensland University of Technology’ on Nov. 10, 2014 at 1335 PST.

* ‘super-capacitor’ changed to ‘supercapacitor’ on April 29, 2015.

Glass bubbles on the moon contain nanoparticles

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There’s something quite charming about this June 12, 2012 news item on Nanowerk,

A stunning discovery by Queensland University of Technology (QUT) soil scientist Marek Zbik of nano particles inside bubbles of glass in lunar soil could solve the mystery of why the moon’s surface topsoil has many unusual properties.

Dr Zbik, from Queensland University of Technology’s Science and Engineering Faculty, said scientists had long observed the strange behaviour of lunar soil but had not taken much notice of the nano and submicron particles found in the soil and their source was unknown.

Dr Zbik took the lunar soil samples to Taiwan where he could study the glass bubbles without breaking them using a new technique for studying nano materials call synchrotron-based nano tomography to look at the particles. Nano tomography is a transmission X-ray microscope which enables 3D images of nano particles to be made.

“We were really surprised at what we found,” Dr Zbik said.

“Instead of gas or vapour inside the bubbles, which we would expect to find in such bubbles on Earth, the lunar glass bubbles were filled with a highly porous network of alien-looking glassy particles that span the bubbles’ interior.

“It appears that the nano particles are formed inside bubbles of molten rocks when meteorites hit the lunar surface. Then they are released when the glass bubbles are pulverised by the consequent bombardment of meteorites on the moon’s surface.

“This continuous pulverising of rocks on the lunar surface and constant mixing develop a type of soil which is unknown on Earth.”

This video from the Queensland University of Technology is in 3-D (I believe this is the first I’ve hosted a 3-D video here),

Here’s more about this video and Zbik’s work from the YouTube page,

Discovery of possible source of the lunar regolith fine fraction from liberation of particles born within impact generated vesicles in the lunar impact glass. 3D image obtained using Transmission X-Ray Microscope (TXM), shown here as the anaglyph, reveals fine structure within vesicle in the lunar impact glass.
Marek S. Żbik, Yen-Fang Song, Chun-Chieh Wang, and Ray L. Frost, “Discovery of Discrete Structured Bubbles within Lunar Regolith Impact Glasses,” ISRN Astronomy and Astrophysics, (2012), Article ID 506187, 3 pages.

More details about the discovery can be found in the June 12, 2012 news item on Nanowerk or in the Queensland University of Technology June 12, 2012 news release,

“Lunar soil is electro-statically charged so it hovers above the surface; it is extremely chemically active; and it has low thermal conductivity eg it can be 160 degrees above the surface but -40 degrees two metres below the surface.

“It is also very sticky and brittle such that its particles wear the surface off metal and glass.”

I loved the video and watched it twice, all 17 secs. of it.

Mathematical healing of skin and bone

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Mathematics professor at Australia’s Queensland University of Technology (QUT), Graeme Pettet provides a fascinating perspective on skin and bone, from the April 23, 2012 news item by Alita Pashley on physorg.com,

Professor Graeme Pettet, a mathematician from QUT’s Institute of Health Biomedical Innovation (IHBI), said maths could be used to better understand the structure of skin and bones and their response to healing techniques, which will eventually lead to better therapeutic innovations.

“Mathematics is the language of any science so if there are spatial or temporal variations of any kind then you can describe it mathematically,” he said.

“Skin is very difficult to describe. It’s very messy and very complicated. In fact most of the descriptions that engineers and biologists use are schematic stories (diagrams),” he said.

“Once we understand the structure (of the skin) and how it develops we can begin to analyze how that development impacts upon healing in the skin and maybe also diseases of the skin.”

Professor Pettet said his research would, for the first time, formalise the theories about the way cells interact when healing.

Professor Pettet is also working on applying similar techniques to figure out how to show how small, localised damage at the site of bone fractures can impact on healing.

Unfortunately, there isn’t much more in the way of detail either in the news item or on the Tissue Repair and Regeneration Research Program webpage.

A brief reference to the Fukushima nuclear accident then, nanotechnology and cleaning up radioactive waste

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I came across an excellent article about the Fukushima nuclear accident (courtesy @edyong209) that recounts the first 24 hours of  the emergency. It’s fascinating to find out what they did right and why it all went so wrong in 24 Hours at Fukushima by Eliza Strickland for the November 2011 issue of IEEE Spectrum (published by the Institute of Electrical and Electronics Engineers [IEEE]). Excerpted from the article,

True, the antinuclear forces will find plenty in the Fukushima saga to bolster their arguments. The interlocked and cascading chain of mishaps seems to be a textbook validation of the “normal accidents” hypothesis developed by Charles Perrow after Three Mile Island. Perrow, a Yale University sociologist, identified the nuclear power plant as the canonical tightly coupled system, in which the occasional catastrophic failure is inevitable.

On the other hand, close study of the disaster’s first 24 hours, before the cascade of failures carried reactor 1 beyond any hope of salvation, reveals clear inflection points where minor differences would have prevented events from spiraling out of control. Some of these are astonishingly simple: If the emergency generators had been installed on upper floors rather than in basements, for example, the disaster would have stopped before it began. And if workers had been able to vent gases in reactor 1 sooner, the rest of the plant’s destruction might well have been averted.

Strickland provides some historical context (Three Mile Island and Chernobyl nuclear accidents) in the addition to the 24 hour overview which provides details such as the fact that workers at the plant pulled the batteries out of their cars to generate some form of power after the plant generators failed.

Whether or not you believe we should be using nuclear, there can’t be any question that we have to deal with radioactive waste. From the Strickland article,

… So far, the cost of Fukushima is a dozen dead towns ringing the broken power station, more than 80 000 refugees, and a traumatized Japan.

On that note, the Nov. 2, 2011 news item (Nanotechnology makes storing radioactive waste safer) takes on some urgency. From the news item on Nanowerk,

Queensland University of Technology (QUT) researchers have developed new technology capable of removing radioactive material from contaminated water and aiding clean-up efforts following nuclear disasters.

The technology, which was developed in collaboration with the Australian Nuclear Science and Technology Organisation (ANSTO) and Pennsylvania State University in America, works by running the contaminated water through the fine nanotubes and fibres, which trap the radioactive Cesium (Cs+) ions through a structural change.

By adding silver oxide nanocrystals to the outer surface, the nanostructures are able to capture and immobilise radioactive iodine (I-) ions used in treatments for thyroid cancer, in probes and markers for medical diagnosis, as well as found in leaks of nuclear accidents.

“It is our view that just taking the radioactive material in the adsorbents isn’t good enough. We should make it safe before disposing it,” he [Professor Huai-Yong Zhu] said.

“The same goes for Australian sites where we mine nuclear products. We need a solution before we have a problem, rather than looking for fixes when it could be too late.”

“In France, 75 per cent of electricity is produced by nuclear power and in Belgium, which has a population of 10 million people there are six nuclear power stations,” he said.

“Even if we decide that nuclear energy is not the way we want to go, we will still need to clean-up what’s been produced so far and store it safely,” he said.

There’s no mention of commercializing this means of dealing with radioactive waste but I hope they manage it, or something better,  soon (from the news item),

“One gram of the nanofibres can effectively purify at least one tonne of polluted water,” Professor Zhu said.