Tag Archives: Army Research Laboratory

US soldiers get batteries woven into their clothes

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Last time I wrote about soldiers, equipment, and energy-efficiency (April 5, 2012 posting) the soldiers in question were British. Today’s posting focuses on US soldiers. From the May 7, 2012 news item on Nanowerk,

U.S. soldiers are increasingly weighed down by batteries to power weapons, detection devices and communications equipment. So the Army Research Laboratory has awarded a University of Utah-led consortium almost $15 million to use computer simulations to help design materials for lighter-weight, energy efficient devices and batteries.

“We want to help the Army make advances in fundamental research that will lead to better materials to help our soldiers in the field,” says computing Professor Martin Berzins, principal investigator among five University of Utah faculty members who will work on the project. “One of Utah’s main contributions will be the batteries.”

Of the five-year Army grant of $14,898,000, the University of Utah will retain $4.2 million for research plus additional administrative costs. The remainder will go to members of the consortium led by the University of Utah, including Boston University, Rensselaer Polytechnic Institute, Pennsylvania State University, Harvard University, Brown University, the University of California, Davis, and the Polytechnic University of Turin, Italy.

The new research effort is based on the idea that by using powerful computers to simulate the behavior of materials on multiple scales – from the atomic and molecular nanoscale to the large or “bulk” scale – new, lighter, more energy efficient power supplies and materials can be designed and developed. Improving existing materials also is a goal.

“We want to model everything from the nanoscale to the soldier scale,” Berzins says. “It’s virtual design, in some sense.”

“Today’s soldier enters the battle space with an amazing array of advanced electronic materials devices and systems,” the University of Utah said in its grant proposal. “The soldier of the future will rely even more heavily on electronic weaponry, detection devices, advanced communications systems and protection systems. Currently, a typical infantry soldier might carry up to 35 pounds of batteries in order to power these systems, and it is clear that the energy and power requirements for future soldiers will be much greater.” [emphasis mine]

“These requirements have a dramatic adverse effect on the survivability and lethality of the soldier by reducing mobility as well as the amount of weaponry, sensors, communication equipment and armor that the soldier can carry. Hence, the Army’s desire for greater lethality and survivability of its men and women in the field is fundamentally tied to the development of devices and systems with increased energy efficiency as well as dramatic improvement in the energy and power density of [battery] storage and delivery systems.”

Up to 35 lbs. of batteries? I’m trying to imagine what the rest of the equipment would weigh. In any event, they seem to be more interested in adding to the weaponry than reducing weight. At least, that’s how I understand “greater *lethality.” Nice of them to mention greater survivability too.

The British project is more modest, they are weaving e-textiles that harvest energy allowing British soldiers to carry fewer batteries. I believe field trials were scheduled for May 2012.

* Correction: leathility changed to lethality on July 31, 2013.

Art conservation and nanotechnology; the science of social networks; carbon nanotubes and possible mesothelioma; Eric Drexler has a few words

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It looks like nanotechnology innovations in the field of art conservation may help preserve priceless works for longer and with less damage. The problem as articulated in Michael Berger’s article on Nanowerk is,

“Nowadays, one of the most important problems faced during the cleaning of works of art is the removal of organic materials, mainly acrylic polymers, applied in the past as consolidants or protective coatings,” explains Piero Baglioni, a professor of Physical Chemistry at the University of Florence. “Unfortunately, their application induces a drastic alteration of the interfacial properties of the artwork and leads to increased degradation. These organic materials must therefore be removed.”

Baglioni and his colleagues at the University of Florence have developed “… a micro-emulsion cleaning agent that is designed to dissolve only the organic molecules on the surface of a painting …”

This is a little off Azonano’s usual beat (and mine too) but Rensselaer Polytechnic Institute’s Army Research Laboratory is launching an interdisciplinary research center for the study of social and cognitive networks.  From the news item,

“Rensselaer offers a unique research environment to lead this important new network science center,” said Rensselaer President Shirley Ann Jackson. “We have assembled an outstanding team of researchers, and built powerful new research platforms. The team will work with one of the largest academic supercomputing centers in the world – the Rensselaer Computational Center for Nanotechnology Innovations – and the leading visualization and simulation capabilities within our new Experimental Media and Performing Arts Center. The Center for Social and Cognitive Networks will bring together our world-class scientists in the areas of computer science, cognitive science, physics, Web science, and mathematics in an unprecedented collaboration to investigate all aspects of the ever-changing and global social climate of today.”

The center will study the fundamentals of social and cognitive networks and their roles in today’s society and organizations, including the U.S. Army. The goal will be to gain a deeper understanding of these networks and build a firm scientific basis in the field of network science. The work will include research on large social networks, with a focus on networks with mobile agents. An example of a mobile agent is someone who is interacting (e.g., communicating, observing, helping, distracting, interrupting, etc.) with others while moving around the environment.

My suspicion is that the real goal for the work is to exploit the data for military advantage, if possible. Any other benefits would be incidental. Of course, a fair chunk of the technology we enjoy today (for example, tv and the internet) was investigated by the military first.

I’ve mentioned carbon nanotubes and possible toxicology before. Specifically, some carbon nanotubes resemble asbestos fibers and pilot studies have suggested they may behave the same way when ingested by one means or another  into the body. There is a new confirmation of this hypothesis with a study where mice inhaled carbon nanotubes. From the news item on Nanowerk,

Using mice in an animal model study, the researchers set out to determine what happens when multi-walled carbon nanotubes are inhaled. Specifically, researchers wanted to determine whether the nanotubes would be able to reach the pleura, which is the tissue that lines the outside of the lungs and is affected by exposure to certain types of asbestos fibers which cause the cancer mesothelioma. The researchers used inhalation exposure and found that inhaled nanotubes do reach the pleura and cause health effects.

This was one exposure and the mice recovered after three months. More studies will be needed to determine the effects of repeated exposure. This study (Inhaled Carbon Nanotubes Reach the Sub-Pleural Tissue in Mice by Dr. James Bonner, Dr. Jessica Ryman-Rasmussen, Dr. Arnold Brody, et. al.) can be found in the Oct. 25, 2009 issue of Nature Nanotechnology.

On Friday (Oct. 23, 2009) I mentioned an essay by Chris Toumey on the forthcoming 50th anniversary of Richard Feynman’s seminal talk, There’s plenty of room at the bottom. Today I found a response to the essay by Eric Drexler.  From Drexler’s essay on Nanowerk,

Unfortunately, yesterday’s backward-looking guest article in Nanowerk reinforces the widespread but quite mistaken idea that my views are essentially the opposite of what I’ve stated above, and that those perverse ideas are also those of the Foresight Institute. I cannot speak for that organization, or vice versa, because I left it years ago. Contrary to what the article may suggest, I have no affiliation with the organization whatsoever. Regarding terminology, it is of course entirely appropriate to use the term “nanotechnology” to describe nanoscale technologies. The idea that there is a conflict between progress in the field and future applications of that progress is puzzling. This idea appears to stem from a strange episode that came to a head during the political push for the bill that established and funded the U.S. National Nanotechnology Initiative, an episode in which some leading science spokesmen quite properly rejected a collection of popular fantasies, but quite improperly attributed those fantasies to me. Reading claims by confused enthusiasts and the press that “Drexler says this” or “Drexler says that” is no substitute for reading my journal articles, or the technical analysis in my book, Nanosystems, and in my MIT dissertation). The failure of these leaders to do their homework has had substantial and lingering toxic effects.

(My own focus was on the ‘origin’ story for nanotechnology and not on Drexler’s theories.) If I understand the situation rightly, much of the controversy has its roots in Drexler’s popular book, Engines of Creation. It was written over 20 years ago and struck a note which reverberates to this day. The irony is that there are writers who’d trade places with Drexler in a nano second. Imagine having that kind of impact on society and culture (in the US primarily). The downside as Drexler has discovered is that the idea or story has taken on its own life. For a similar example, take Mary Shelley’s book where Frankenstein is not the monster’s name, it’s the scientist’s name. However, the character took its own life and name.