Tag Archives: Virginia

DARPA (US Defense Advanced Research Project Agency) ‘Atoms to Product’ program launched

It took over a year after announcing the ‘Atoms to Product’ program in 2014 for DARPA (US Defense Advanced Research Projects Agency) to select 10 proponents for three projects. Before moving onto the latest announcement, here’s a description of the ‘Atoms to Product’ program from its Aug. 27, 2014 announcement on Nanowerk,

Many common materials exhibit different and potentially useful characteristics when fabricated at extremely small scales—that is, at dimensions near the size of atoms, or a few ten-billionths of a meter. These “atomic scale” or “nanoscale” properties include quantized electrical characteristics, glueless adhesion, rapid temperature changes, and tunable light absorption and scattering that, if available in human-scale products and systems, could offer potentially revolutionary defense and commercial capabilities. Two as-yet insurmountable technical challenges, however, stand in the way: Lack of knowledge of how to retain nanoscale properties in materials at larger scales, and lack of assembly capabilities for items between nanoscale and 100 microns—slightly wider than a human hair.

DARPA has created the Atoms to Product (A2P) program to help overcome these challenges. The program seeks to develop enhanced technologies for assembling atomic-scale pieces. It also seeks to integrate these components into materials and systems from nanoscale up to product scale in ways that preserve and exploit distinctive nanoscale properties.

DARPA’s Atoms to Product (A2P) program seeks to develop enhanced technologies for assembling nanoscale items, and integrating these components into materials and systems from nanoscale up to product scale in ways that preserve and exploit distinctive nanoscale properties.

A Dec. 29, 2015 news item on Nanowerk features the latest about the project,

DARPA recently selected 10 performers to tackle this challenge: Zyvex Labs, Richardson, Texas; SRI, Menlo Park, California; Boston University, Boston, Massachusetts; University of Notre Dame, South Bend, Indiana; HRL Laboratories, Malibu, California; PARC, Palo Alto, California; Embody, Norfolk, Virginia; Voxtel, Beaverton, Oregon; Harvard University, Cambridge, Massachusetts; and Draper Laboratory, Cambridge, Massachusetts.

A Dec. 29, 2015 DARPA news release, which originated the news item, offers more information and an image illustrating the type of advances already made by one of the successful proponents,

DARPA recently launched its Atoms to Product (A2P) program, with the goal of developing technologies and processes to assemble nanometer-scale pieces—whose dimensions are near the size of atoms—into systems, components, or materials that are at least millimeter-scale in size. At the heart of that goal was a frustrating reality: Many common materials, when fabricated at nanometer-scale, exhibit unique and attractive “atomic-scale” behaviors including quantized current-voltage behavior, dramatically lower melting points and significantly higher specific heats—but they tend to lose these potentially beneficial traits when they are manufactured at larger “product-scale” dimensions, typically on the order of a few centimeters, for integration into devices and systems.

“The ability to assemble atomic-scale pieces into practical components and products is the key to unlocking the full potential of micromachines,” said John Main, DARPA program manager. “The DARPA Atoms to Product Program aims to bring the benefits of microelectronic-style miniaturization to systems and products that combine mechanical, electrical, and chemical processes.”

The program calls for closing the assembly gap in two steps: From atoms to microns and from microns to millimeters. Performers are tasked with addressing one or both of these steps and have been assigned to one of three working groups, each with a distinct focus area.

A2P

Image caption: Microscopic tools such as this nanoscale “atom writer” can be used to fabricate minuscule light-manipulating structures on surfaces. DARPA has selected 10 performers for its Atoms to Product (A2P) program whose goal is to develop technologies and processes to assemble nanometer-scale pieces—whose dimensions are near the size of atoms—into systems, components, or materials that are at least millimeter-scale in size. (Image credit: Boston University)

Here’s more about the projects and the performers (proponents) from the A2P performers page on the DARPA website,

Nanometer to Millimeter in a Single System – Embody, Draper and Voxtel

Current methods to treat ligament injuries in warfighters [also known as, soldiers]—which account for a significant portion of reported injuries—often fail to restore pre-injury performance, due to surgical complexities and an inadequate supply of donor tissue. Embody is developing reinforced collagen nanofibers that mimic natural ligaments and replicate the biological and biomechanical properties of native tissue. Embody aims to create a new standard of care and restore pre-injury performance for warfighters and sports injury patients at a 50% reduction compared to current costs.

Radio Frequency (RF) systems (e.g., cell phones, GPS) have performance limits due to alternating current loss. In lower frequency power systems this is addressed by braiding the wires, but this is not currently possibly in cell phones due to an inability to manufacture sufficiently small braided wires. Draper is developing submicron wires that can be braided using DNA self-assembly methods. If successful, portable RF systems will be more power efficient and able to send 10 times more information in a given channel.

For seamless control of structures, physics and surface chemistry—from the atomic-level to the meter-level—Voxtel Inc. and partner Oregon State University are developing an efficient, high-rate, fluid-based manufacturing process designed to imitate nature’s ability to manufacture complex multimaterial products across scales. Historically, challenges relating to the cost of atomic-level control, production speed, and printing capability have been effectively insurmountable. This team’s new process will combine synthesis and delivery of materials into a massively parallel inkjet operation that draws from nature to achieve a DNA-like mediated assembly. The goal is to assemble complex, 3-D multimaterial mixed organic and inorganic products quickly and cost-effectively—directly from atoms.

Optical Metamaterial Assembly – Boston University, University of Notre Dame, HRL and PARC.

Nanoscale devices have demonstrated nearly unlimited power and functionality, but there hasn’t been a general- purpose, high-volume, low-cost method for building them. Boston University is developing an atomic calligraphy technique that can spray paint atoms with nanometer precision to build tunable optical metamaterials for the photonic battlefield. If successful, this capability could enhance the survivability of a wide range of military platforms, providing advanced camouflage and other optical illusions in the visual range much as stealth technology has enabled in the radar range.

The University of Notre Dame is developing massively parallel nanomanufacturing strategies to overcome the requirement today that most optical metamaterials must be fabricated in “one-off” operations. The Notre Dame project aims to design and build optical metamaterials that can be reconfigured to rapidly provide on-demand, customized optical capabilities. The aim is to use holographic traps to produce optical “tiles” that can be assembled into a myriad of functional forms and further customized by single-atom electrochemistry. Integrating these materials on surfaces and within devices could provide both warfighters and platforms with transformational survivability.

HRL Laboratories is working on a fast, scalable and material-agnostic process for improving infrared (IR) reflectivity of materials. Current IR-reflective materials have limited use, because reflectivity is highly dependent on the specific angle at which light hits the material. HRL is developing a technique for allowing tailorable infrared reflectivity across a variety of materials. If successful, the process will enable manufacturable materials with up to 98% IR reflectivity at all incident angles.

PARC is working on building the first digital MicroAssembly Printer, where the “inks” are micrometer-size particles and the “image” outputs are centimeter-scale and larger assemblies. The goal is to print smart materials with the throughput and cost of laser printers, but with the precision and functionality of nanotechnology. If successful, the printer would enable the short-run production of large, engineered, customized microstructures, such as metamaterials with unique responses for secure communications, surveillance and electronic warfare.

Flexible, General Purpose Assembly – Zyvex, SRI, and Harvard.

Zyvex aims to create nano-functional micron-scale devices using customizable and scalable manufacturing that is top-down and atomically precise. These high-performance electronic, optical, and nano-mechanical components would be assembled by SRI micro-robots into fully-functional devices and sub-systems such as ultra-sensitive sensors for threat detection, quantum communication devices, and atomic clocks the size of a grain of sand.

SRI’s Levitated Microfactories will seek to combine the precision of MEMS [micro-electromechanical systems] flexures with the versatility and range of pick-and-place robots and the scalability of swarms [an idea Michael Crichton used in his 2002 novel Prey to induce horror] to assemble and electrically connect micron and millimeter components to build stronger materials, faster electronics, and better sensors.

Many high-impact, minimally invasive surgical techniques are currently performed only by elite surgeons due to the lack of tactile feedback at such small scales relative to what is experienced during conventional surgical procedures. Harvard is developing a new manufacturing paradigm for millimeter-scale surgical tools using low-cost 2D layer-by-layer processes and assembly by folding, resulting in arbitrarily complex meso-scale 3D devices. The goal is for these novel tools to restore the necessary tactile feedback and thereby nurture a new degree of dexterity to perform otherwise demanding micro- and minimally invasive surgeries, and thus expand the availability of life-saving procedures.

Sidebar

‘Sidebar’ is my way of indicating these comments have little to do with the matter at hand but could be interesting factoids for you.

First, Zyvex Labs was last mentioned here in a Sept. 10, 2014 posting titled: OCSiAL will not be acquiring Zyvex. Notice that this  announcement was made shortly after DARPA’s A2P program was announced and that OCSiAL is one of RUSNANO’s (a Russian funding agency focused on nanotechnology) portfolio companies (see my Oct. 23, 2015 posting for more).

HRL Laboratories, mentioned here in an April 19, 2012 posting mostly concerned with memristors (nanoscale devices that mimic neural or synaptic plasticity), has its roots in Howard Hughes’s research laboratories as noted in the posting. In 2012, HRL was involved in another DARPA project, SyNAPSE.

Finally and minimally, PARC also known as, Xerox PARC, was made famous by Steven Jobs and Steve Wozniak when they set up their own company (Apple) basing their products on innovations that PARC had rejected. There are other versions of the story and one by Malcolm Gladwell for the New Yorker May 16, 2011 issue which presents a more complicated and, at times, contradictory version of that particular ‘origins’ story.

Tobacco Indemnification and Community Revitalization Commission supports nanomaterial development with a $2M grant

Tobacco growing is not as lucrative as it once was. Worldwide anti-smoking legislation and health campaigns against smoking have had an effect on the industry and the farmers who grow tobacco. With that in mind, the June 10, 2015 news item on Azonano suggests that the industry and the farmers might be trying to find other uses for tobacco,

The Tobacco Commission [aka Tobacco Indemnification and Community Revitalization Commission] voted unanimously to award the Center for Advanced Engineering & Research a $2 million research and development grant, 100% of which will directly support NanoTouch Materials’ continued development of their NanoSeptic surfaces. This funding will be used to research new materials and advanced manufacturing processes, and build a dedicated fabrication facility in Bedford County [state of Virginia].

A June 9, 2015 NanoTouch news release on prnewswire.com, which originated the news item, describes the deal in more detail but offers no indication as to how tobacco might factor into the research (Note: A link has been removed),

“What makes research and development of NanoSeptic products complex and expensive is the multiple areas of scientific expertise required,” says NanoTouch co-founder Mark Sisson. “This funding will allow us to continue working with some of the best scientific minds in material science, nanotechnology, polymers and biotechnology.”

The research component of this grant will be focused on the development of the 5th generation of the NanoSeptic surface. Initial lab testing on early prototypes of the technology resulted in a surface that was 1,000 times more effective than the previous generation, achieving almost a six-log reduction.

Effectiveness of the current NanoSeptic surface has been extensively studied both by an independent FDA compliant lab and university research centers worldwide, including Saudi Arabia and South Korea. These studies utilize internationally recognized standard testing protocols against a variety of pathogens including E. coli, MRSA, Staph, Norovirus and the human Coronavirus, a strain of which is causing MERS outbreaks in the Middle East and Korea.

“NanoSeptic products present a great growth opportunity for this region,” says Bob Bailey, executive director of CAER. “The Center for Advanced Engineering and Research [this appears to be a wholly NanoTouch-owned research group] is excited to be part of this project and we believe that our strong research partnerships with multiple Virginia universities will prove to be a significant asset.”

As part of this three-year initiative, NanoTouch Materials is expected to grow their workforce in Bedford County, VA to a total of 14 employees, and an estimated 37 employees in five years. NanoTouch is also expected to invest $1 million in facilities and advanced manufacturing equipment.

“Virtually every firm or project with which the Tobacco Commission partners has a common characteristic: a tremendous potential to grow.  NanoSeptic is an ideal example of this.  It’s easy to see how big the potential is in healthcare, public and commercial transportation, and the hospitality industry,” says Delegate Kathy Byron, Chair of the Research & Development Committee. “That potential is emblematic of our entire region, and the reestablishment of our manufacturing community.  Once again, companies in Central and Southside Virginia are making products that are being used worldwide.”

While an entire line of NanoSeptic products have been developed and are being distributed to 29 countries, the company also plans to spend significant funding to conduct market research in the healthcare, education, facility management, commercial janitorial and food service industries. This market research will guide future product development and uncover specific ways that self-cleaning surfaces can be used to improve healthcare outcomes, reduce employee and student absenteeism, and broadly improve community health.

“While the vetting process for the grant was exhaustive, we’re grateful for the support of the Tobacco Commission and the Economic Development Authority of Bedford County in our mission of providing cleaner, healthier places in which to live, work and play,” says NanoTouch co-founder Dennis Hackemeyer. “And our investors couldn’t be happier with the company receiving funding that will accelerate growth without diluting their investment.”

The news release goes on to describe the funding agency,

The Tobacco Indemnification and Community Revitalization Commission is a 31-member body whose mission is to promote economic growth and development in tobacco-dependent communities using proceeds of the national tobacco settlement.  The Commission has awarded 1,831 grants totaling more than $1,072,922,288 across the tobacco region of the Commonwealth. http://www.tic.virginia.gov

I have mentioned NanoTouch before in an April 24, 2013 posting where I also expressed some interest in getting more technical information about the company’s products. In 2013, the company was introducing its product, NanoSeptic, into schools in the Bellmore-Merrick School District of New York.

NanoForArt in Mexico

Mexico recently hosted (Feb. 7 – 8, 2013) a pair of conferences focused on nanotechnology and art conservation. The country is part of an international consortium in the European Commision’s Seventh Framework Programme (FP7), NanoForArt project. Before mentioning the conference, here’s a little information about the NanoForArt project from its homepage,

The main objective of the NANOFORART proposal is the development and experimentation of new nano-materials and responsive systems for the conservation and preservation of movable and immovable artworks. [emphasis mine]

While the progress in material science has generated sophisticated nanostructured materials, conservation of cultural heritage is still mainly based on traditional methods and conventional materials that often lack the necessary  compatibility with the original artworks and a durable performance in responding to the changes of natural environment and man-made activities.

The main challenge of NANOFORART is the combination of sophisticated functional materials arising from the recent developments in nano-science/technology with innovative techniques in the restoration and preventive conservation of works of art, with unprecedented efficiency.

Immovable artworks tend to be things like cave art, frescoes, and other forms of wall and rock art. The Feb. 2013 conferences in Mexico as per a Feb. 27, 2013 Agencia EFE news item on the Global Post website featured (Note: Links have been removed),

Baglioni [Piero Baglioni, a researcher and professor at the University of Florence] and Dr. Rodorico Giorgi, also of the University of Florence, traveled to Mexico earlier this month to preside over a conference on Nanotechnology applied to cultural heritage: wall paintings/cellulose, INAH [Instituto Nacional de Antropología e Historia] said.

The project includes specialists from Italy, Spain, Britain, France, Denmark, the Czech Republic, Germany,  Slovenia and Mexico and is coordinated by the CSGI center [Center for Colloids and Surface Science] at the University of Florence.

NANONFORART is set to conclude in December 2014 with the “validation of the technology and the methods developed, as well as training activities,” INAH said.

Until now, preservation of cultural treasures has been carried out using conventional materials that are often incompatible with the works and can, over time, alter the appearance of the object.

Baglioni has worked with INAH personnel to clean and restore pre-Columbian murals at the Cacaxtla, Cholula, Tlatelolco, Mayapan, El Tajin, Monte Alban and Teotihuacan sites.

I have mentioned Baglioni’s work in Mexico previously in a Sept. 20, 2010 posting about  some work at La Antigua Ciudad Maya de Calakmul, an archaeological site which is located in the Campeche state.

Unfortunately, there aren’t too many details about the conferences, the Feb. 7, 2013 conference sported the previously noted title (in the Agencia EFE news item), Nanotechnology Applied to Cultural Heritage: Wall Paintings/Cellulose, and the Feb. 8, 2013 conference was titled, Nanotechnology for the Cleaning of Cultural Heritage.

There’s more information about nanotechnology aspects on the NanoForArt Overall page (Note: Links have been removed),

The work plan will start with design and formulation of nanostructured systems with special functionalities (WP1) such as deacidification of movable artworks (paper, parchment, canvas, leather), cleaning of movable artworks (paper, parchment, canvas paintings), protection of movable artworks (paper, canvas), consolidation of immovable artworks (wall-paintings, plaster and stones), and cleaning of immovable artworks (wallpaintings, plaster and stones). These systems, whose formulation will be optimized according to their functions, will include microemulsions, micellar solutions, gels and dispersions of different kinds of nanoparticles. A physico-chemical characterization of the developed materals (WP2) will constantly support the formulation activity. This will allow to understand and control the nature of interaction mechanisms between these nanostructures and the target substances/supports.

Assessment of the applicability of materials (WP3) will start in the second half of the first year. In this phase the up-scale of the technologies from the laboratory to the market level will be tackled. All the partners will interact in order to clarify and merge the priority from all the points of view. Evaluation of possible human health effects and environmental impacts of developed nanomaterials for restoration (WP7) will also start in the second half of the first year. Special emphasis will be given to potential hazardousness of nanoparticles used for design and formulation of nanostructured systems, as well as environmental impacts associated with the use of these nano-based products.

Nanotechnology developed by NANOFORART will aim also to significantly reduce the use of harmful solvents, as well as to introduce new environmentally friendly nanomaterials. Once the applicability and safety of the developed materials will be assessed, the development of industry process (WP4, WP5) will start in order to transfer technology on the market by the standardization of the applicative protocols and production of the nanomaterials on medium and large scale. Small and Medium Enterprise (SME) partners will have their main competence in this phase, that should start at the beginning of the second year. Safety and health risks of the industry processes will be also assessed. At the end of the first year, a study of the long-term behavior of the products and of the treated works of art (WP6) will be started by means of artificial ageing, in order to avoid damages due to unforeseen phenomena. The partners will have their main competence in ageing, monitoring of environmental pollution, and control of exhibitions and museums conditions.

The project is scheduled for completion in 2014.

The aspect I find most interesting is the ‘immovable art’. There was a controversy in Spain in 2011 over the prospect of opening some caves to tourists, from the Oct. 26, 2011 news item on ScienceDaily,

Plans to reopen Spain’s Altamira caves are stirring controversy over the possibility that tourists’ visits will further damage the 20,000-year old wall paintings that changed views about the intellectual ability of prehistoric people. That’s the topic of an article in the current edition of Chemical & Engineering News, ACS’ weekly newsmagazine. The caves are the site of Stone Age paintings so magnificent that experts have called them the “Sistine Chapel of Paleolithic Art.”

Carmen Drahl, C&EN associate editor, points out in the article that Spanish officials closed the tourist mecca to the public in 2002 after scientists realized that visitors were fostering growth of bacteria that damage the paintings. Now, however, they plan to reopen the caves. Declared a World Heritage Site by the United Nations’ Educational, Scientific and Cultural Organization (UNESCO), Altamira’s rock paintings of animals and human hands made scientists realize that Stone Age people had intellectual capabilities far greater than previously believed.

You can find an Oct. 6, 2011 piece about the Altamira rock paintings by Drahl titled, Keeping Visitors Out To Keep Cave Paintings Safe, on the Chemical and Engineering News (C&EN) blog. For anyone interested in more about rock art, there’s a UNESCO (United Nations Educational, Scientific, and Cultural Organization) World Rock Archives project or, as they call them, activity,

Due to their long sequence chronology, susceptibility to climate changes and vandalism, rock art sites are also among the most vulnerable on the World Heritage List.

Rock art, in the form of paintings and engravings, is a clear and lasting evidence of the transmission of human thoughts and beliefs through art and graphic representations. It functions as a repository of memory, enabling each culture to speak about themselves and their origins in all geographical settings.

I have two more items on cave art. The first is a piece I’ve been wanting to feature for almost two years. It’s an article on Slate by John Jeremiah Sullivan dated March 21, 2011 and titled, America’s Ancient Cave Art
Deep in the Cumberland Plateau, mysterious drawings, thousands of years old, offer a glimpse of lost Native American cultures and traditions. It’s an excerpt of an essay Sullivan wrote for the Paris Review. A fascinating exploration of a cave system that isn’t nearly as well known as France’s Lascaux Caves, here’s a snippet,

Over the past few decades, in Tennessee, archaeologists have unearthed an elaborate cave­-art tradition thousands of years old. The pictures are found in dark­ zone sites—places where the Native American people who made the artwork did so at personal risk, crawling meters or, in some cases, miles underground with cane torches—as opposed to sites in the “twilight zone,” speleologists’ jargon for the stretch, just beyond the entry chamber, which is exposed to diffuse sunlight. A pair of local hobby cavers, friends who worked for the U.S. Forest Service, found the first of these sites in 1979. They’d been exploring an old root cellar and wriggled up into a higher passage. The walls were covered in a thin layer of clay sediment left there during long­ ago floods and maintained by the cave’s unchanging temperature and humidity. The stuff was still soft. It looked at first as though someone had finger­-painted all over, maybe a child—the men debated even saying anything. But the older of them was a student of local history. He knew some of those images from looking at drawings of pots and shell ornaments that emerged from the fields around there: bird men, a dancing warrior figure, a snake with horns. Here were naturalistic animals, too: an owl and turtle. Some of the pictures seemed to have been first made and then ritually mutilated in some way, stabbed or beaten with a stick.

That was the discovery of Mud Glyph Cave, which was reported all over the world and spawned a book and a National Geographic article. No one knew quite what to make of it at the time. The cave’s “closest parallel,” reported the Christian Science Monitor, “may be caves in the south of France which contain Ice Age art.” A team of scholars converged on the site.

The sites range from Missouri to Virginia, and from Wisconsin to Florida, but the bulk lie in Middle Tennessee. Of those, the greater number are on the Cumberland Plateau, which runs at a southwest slant down the eastern part of the state, like a great wall dividing the Appalachians from the interior.

If you do decide to read the excerpt, you may want to reserve 30 to 45 minutes (at least).

For the last tidbit, here’s an introduction to TED (Technology, Entertainment and Design) Fellow, Genevieve von Petzinger’s work on cave art,

Genevieve von Petzinger’s [from the University of Victoria in British Columbia, Canada] database of prehistoric geometric shapes in cave art reveals some startling insights. More than mere doodles, the signs used across geological boundaries suggest there may have been a common iconography before people first moved out of Africa. When did people begin graphic communication, and what was its purpose? Genevieve studies these questions of our common heritage.

A very interesting interview follows that introduction.

As I more often cover movable art, I thought it was time to devote, again, at least part of a posting to immovable art.