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<?xml version="1.0" encoding="UTF-8"?><rss version="2.0" xmlns:content="http://purl.org/rss/1.0/modules/content/" xmlns:dc="http://purl.org/dc/elements/1.1/" xmlns:sy="http://purl.org/rss/1.0/modules/syndication/" > <channel> <title>RSS Emerging technologies: nanocomposites, nanomaterials, nanostructures, nanoparticles</title> <link>http://jsswarriorsupport.com/</link> <description>Emerging technologies: nanocomposites, nanomaterials, nanostructures, nanoparticles</description> <lastBuildDate>Tue, 10 Sep 2019 04:37:47 -0400</lastBuildDate> <language>en</language> <sy:updatePeriod>daily</sy:updatePeriod> <sy:updateFrequency>1</sy:updateFrequency> <item> <title>Technology in Emergency Management</title> <description>1. Initial reports from the Federal Emergency Management Agency (FEMA) misunderstood the amount of damage the 47-floor WTC7 sustained from the debris of the falling North Towerbecause in early photographs, WTC7 was obscured by ...</description> <content:encoded><![CDATA[<img src="/img/answering_emergency_management_information_needs.jpg" alt="The Public Safety Common" align="left" /><p>ATLANTA, Ga., /PRNewswire-iReach/ -- Emergency Visions, Inc. (EVI), the leading provider of cloud and mobile enabled Disaster Resource Management (DRM) solutions, announces they will be co-hosting a webinar with Carahsoft on . The webinar, titled, will feature guest speaker, Brent Woodworth of the Los Angeles Emergency Preparedness Foundation and the Community Stakeholder Network of Los Angeles. Mr. Woodworth is a well-known leader in global risk, crisis management, community relations, and collaborative partnership development. He also has a distinguished history of working with governments, private sector corporations, and nonprofit organizations. With the recent seismic activity on the west coast and the current level of preparedness being questioned, any government agency or organization in the state of California can benefit from attending this webinar. Mr. Woodworth will lead a thought provoking webinar on earthquake preparedness for the Golden State and will discuss how technology solutions can play a strategic role in community resilience against the threat of a major earthquake. Mr. Woodworth will be followed by Shawn Smith, Chief Evangelist of EVI, who will discuss the role of technology in DRM and will demonstrate EVI's solution, ResponseVision® 4.0. This webinar will focus on: New approaches to community resilience utilizing technology for data sharing Best practices in mobile technology for managing disaster resources Major earthquake threats to the Golden State Q+A focused on California preparedness initiatives EVI's CEO and Chairman, Mark Morel said, "We are excited to partner with Carahsoft once again on an industry leading webinar to shed light on technology solutions that can benefit the citizens in the State of California." Mr. Morel went on to add, "Mr. Woodworth is a leader in developing community resilience and we look forward to hearing his thoughts on making California safer through the utilization of technology and Whole Community collaboration." to register for this free webinar.</p>]]></content:encoded> <category><![CDATA[Emerging Technologies]]></category> <link>http://jsswarriorsupport.com/EmergingTechnologies/technology-in-emergency-management</link> <guid isPermaLink="true">http://jsswarriorsupport.com/EmergingTechnologies/technology-in-emergency-management</guid> <pubDate>Tue, 10 Sep 2019 12:37:00 +0000</pubDate> </item> <item> <title>Printed Electronics: The Global Market</title> <description>By David Savastano Editor First Nanosolar utility panels shipped and deployed in Germany in a free-field plant installation. (Photo credit: Willi Breuer) As petroleum-based energy costs soar and concerns over the environment as ...</description> <content:encoded><![CDATA[<img src="/img/toppan_forms_to_test_markets_with.jpg" alt="Toppan Forms to test markets" align="left" /><p>By David Savastano Editor First Nanosolar utility panels shipped and deployed in Germany in a free-field plant installation. (Photo credit: Willi Breuer) As petroleum-based energy costs soar and concerns over the environment as well as sustainability grow, interest in new sources of natural energy is on a rapid ascent, whether it is wind or solar power. Solar technologies have generated tremendous interest among the public and investors alike, and the allure is understandable:the ability to harness the sun’s energy offers unlimited clean power. The goal, then, is to be able to gather this power efficiently at a reasonable cost. Typically, solar cells are costly, but if a way could be found to mass produce these cells, there could be fast growth in the market. This is where printing comes into play. It is becoming apparent that flexible thin-film photovoltaic (PV)cells can be used to collect solar energy at a fraction of the cost of present technologies. A wide variety of companies are in the market:United Solar Ovonic (a wholly-owned subsidiary of Energy Conversion Devices Inc.), Global Solar, First Solar, Nanosolar, Konarka, Solopower, HelioVolt, Miasole, Daystar and Evergreen Solar are just a few of the companies in this growing field. A look at the investments into these companies shows the potential for the field. Nanosolar has received $500 million in funding to date, including investments from leading power companies such as AESCorporation, EDF and the Carlyle Group. Meanwhile, Dow Chemical is partnering with Global Solar. There is plenty of expansion as well. First Solar announced plans in August to add 500, 000 square feet to its manufacturing and R&Dfacility in Perrysburg, OH. Global Solar just moved into its new 100, 000 square foot factory in Tucson, AZ.</p>]]></content:encoded> <category><![CDATA[Printed Electronics]]></category> <link>http://jsswarriorsupport.com/PrintedElectronics/printed-electronics-the-global-market</link> <guid isPermaLink="true">http://jsswarriorsupport.com/PrintedElectronics/printed-electronics-the-global-market</guid> <pubDate>Sun, 11 Aug 2019 12:37:00 +0000</pubDate> </item> <item> <title>What are the new Emerging Technologies?</title> <description>Oligopoly, Inc. 2005' serves as a reminder that what looks like buying and selling between countries is most often the redistribution of capital among subsidiaries of the same parent multinational corporation. In a very real ...</description> <content:encoded><![CDATA[<img src="/img/img_0115.jpg" alt="IMG_0115.jpg" align="left" /><p>The Nanotube Sponge Developed last year, the carbon nanotube sponge has some very interesting properties, and huge potential for limiting environmental disasters such as oils spills and providing access to clean drinking water. The sponge itself is made of carbon nanotubes which are essentially sheets of carbon rolled into cylinders. The sheets themselves are only an atom thick. Being made of almost pure carbon, the sponge naturally repels water, but attracts oil. As a result, this material could prove invaluable when it comes to cleaning up oil spills, and elegantly simple approach. Furthermore, the sponge itself is magnetic, which offers some options as to how these might be deployed in a large scale, and recovered. Additionally, the sponges are extremely durable and resistant to burning, which makes them have a long life span. It is also being explored as to how this technology might be further developed to allow the filtration of microbes and harmful bacteria from unsafe drinking water. Currently, this is being explored by coating more traditional polyurethane with carbon nanotubes , and additionally with silver nanowires. The sponges then form a very good conductor, and can cleanse contaminated drinking water with a very low voltage input.</p>]]></content:encoded> <category><![CDATA[Emerging Technologies]]></category> <link>http://jsswarriorsupport.com/EmergingTechnologies/what-are-the-new-emerging-technologies</link> <guid isPermaLink="true">http://jsswarriorsupport.com/EmergingTechnologies/what-are-the-new-emerging-technologies</guid> <pubDate>Fri, 12 Jul 2019 12:35:00 +0000</pubDate> </item> <item> <title>Nanotechnology phone waterproof</title> <description>Share this article This is the future, but it's here now The mobile phone has gone from a novelty device to untether us from the wall to the one thing we take everywhere and expect to keep up with the demands of our unpredictable ...</description> <content:encoded><![CDATA[<img src="/img/for_the_love_or_fear_of.jpg" alt="After NeverWet" align="left" /><p>Share this article This is the future, but it's here now The mobile phone has gone from a novelty device to untether us from the wall to the one thing we take everywhere and expect to keep up with the demands of our unpredictable lives. As the cost has escalated, so has our desire to keep them safe, leading to reams of cases and hundreds of thousands of pounds spent on insuring our treasured possessions. In recent years manufacturers have made progress in making these phones more "life proof" by using tougher materials, stronger glass, and some manufacturers - such as Sony - have even made some of their newer smartphones fully waterproof. There's a new round of companies too, aiming to make almost every device waterproof without having suffer any compromises in design or weight to achieve it. What does this all mean? We'll we've dived into the deep end to find. Best waterproof smartphones Whether you've been unfortunate to drop your phone in the bath, drink or even down the toilet (we kid you not), you'll have felt the pain of attempting to resurrect your phone from a potential watery grave. If you haven't, then it's probably only a matter of time before you do according to the statistics, so here's our picks from the current crop of smartphones on the market to help you guard your device from the dangers of liquid. Sony Xperia Z1 & Xperia Z The waterproof Sony Xperia Z1 This article couldn't pass by without a nod to the Sony Xperia Z1, a smartphone built with the clumsy, or perhaps adventurous, types in mind. Unlike many other waterpoof phones it has all the features of a flagship Android handset, but with the addition of IP 58 rating. This rating represents the Z1's abilities to withstand dust and water, allowing submersion in up to one and a half metres of fresh water for up to 30 minutes. The Z1 superseded the Xperia Z, which was not as refined in the design department, with a covered headphone slot and only packing an IP rating of 57, meaning it's less water resistant than the Xperia Z1 (but also cheaper).</p>]]></content:encoded> <category><![CDATA[Nanotechnology]]></category> <link>http://jsswarriorsupport.com/Nanotechnology/nanotechnology-phone-waterproof</link> <guid isPermaLink="true">http://jsswarriorsupport.com/Nanotechnology/nanotechnology-phone-waterproof</guid> <pubDate>Wed, 12 Jun 2019 12:33:00 +0000</pubDate> </item> <item> <title>Emerging Health Information Technology</title> <description>For the first time ever, global spending on prescription drugs has topped $600 billion, even as growth slowed in Europe and North America.Sales of prescription medicines worldwide rose 7 percent to $602 billion, according to IMS ...</description> <content:encoded><![CDATA[<img src="/img/build_the_health_data_infrastructure_in.png" alt="Examples From Summit on" align="left" /><p>This report highlights states' innovative use of health information technology in their Medicaid and SCHIP programs to improve their ability to reach and enroll eligible children, improve the quality of care for children, increase communications with families, and continue to modernize their programs. Although many of these efforts are still in their early stages, findings to date indicate improvements in access to care, care coordination, case management, and administrative efficiency. States are pursuing ways to overcome financing and other challenges to getting new health information technology efforts off the ground, but federal leadership and funding is key for continuing to support and advance state Medicaid and SCHIP health information technology efforts.</p>]]></content:encoded> <category><![CDATA[Emerging Technologies]]></category> <link>http://jsswarriorsupport.com/EmergingTechnologies/emerging-health-information-technology</link> <guid isPermaLink="true">http://jsswarriorsupport.com/EmergingTechnologies/emerging-health-information-technology</guid> <pubDate>Mon, 13 May 2019 12:32:00 +0000</pubDate> </item> <item> <title>Nanostructures use</title> <description>Boston, MA -- Researchers at the Wyss Institute for Biologically Inspired Engineering at Harvard University have created more than 100 three-dimensional (3D) nanostructures using DNA building blocks that function like Lego® ...</description> <content:encoded><![CDATA[<img src="/img/researchers_help_assess_economic_impact_of.jpg" alt="Enlarge" align="left" /><p>Boston, MA -- Researchers at the Wyss Institute for Biologically Inspired Engineering at Harvard University have created more than 100 three-dimensional (3D) nanostructures using DNA building blocks that function like Lego® bricks -- a major advance from the two-dimensional (2D) structures the same team built a few months ago. In effect, the advance means researchers just went from being able to build a flat wall of Legos®, to building a house. The new method, featured as a cover research article in the 30 November issue of Science , is the next step toward using DNA nanotechnologies for more sophisticated applications than ever possible before, such as "smart" medical devices that target drugs selectively to disease sites, programmable imaging probes, templates for precisely arranging inorganic materials in the manufacturing of next generation computer circuits, and more. Computer-generated 3D models (left) and corresponding 2D projection microscopy images (right) of nanostructures self-assembled from synthetic DNA strands called DNA bricks. A master DNA brick collection defines a 25-nanometer cubic "molecular canvas" with 1000 voxels. By selecting subsets of bricks from this canvas, Ke et al. constructed a panel of 102 distinct shapes exhibiting sophisticated surface features as well as intricate interior cavities and tunnels. These nanostructures may enable diverse applications ranging from medicine to nanobiotechnology and electronics. [Image Credit: Yonggang Ke, Wyss Institute, Harvard University.] The nanofabrication technique, called "DNA-brick self-assembly, " uses short, synthetic strands of DNA that work like interlocking Lego® bricks. It capitalizes on the ability to program DNA to form into predesigned shapes thanks to the underlying "recipe" of DNA base pairs: A (adenosine) only binds to T (thymine) and C (cytosine) only binds to G (guanine). But there's a "twist" in the new method required to build in 3D. The trick is to start with an even smaller DNA brick (32 bases in length), which changes the orientation of every matched-up pair of bricks to a 90 degree angle -- giving every two Legos® a 3D shape. In this way, the team can use these bricks to build "out" in addition to "up, " and eventually form 3D structures, such as a 25-nanometer solid cube containing hundreds of bricks. The cube becomes a "master" DNA "molecular canvas"; in this case, the canvas was comprised of 1000 so-called "voxels, " which correspond to eight base-pairs and measure about 2.5 nanometers in size - meaning this is architecture at its tiniest. The master canvas is where the modularity comes in: by simply selecting subsets of specific DNA bricks from the large cubic structure, the team built 102 3D structures with sophisticated surface features, as well as intricate interior cavities and tunnels. "This is a simple, versatile and robust method, " says Peng Yin, Ph.D., Wyss core faculty member and senior author on the study. The DNA-brick technique capitalizes on the ability of DNA strands to selectively attach to other strands, thanks to the underlying "recipe" of DNA base pairs. This animation shows how the DNA strands self-assemble to build a structure. Another method used to build 3D structures, called DNA origami, is tougher to use to build complex shapes, Yin said, because it relies on a long "scaffold" strand of DNA that folds to interact with hundreds of shorter "staple" strands - and each new shape requires a new scaffold routing strategy and hence new staples. In contrast, the DNA brick method does not use any scaffold strand and therefore has a modular architecture; each brick can be added or removed independently.</p>]]></content:encoded> <category><![CDATA[Nanostructures]]></category> <link>http://jsswarriorsupport.com/Nanostructures/nanostructures-use</link> <guid isPermaLink="true">http://jsswarriorsupport.com/Nanostructures/nanostructures-use</guid> <pubDate>Sat, 13 Apr 2019 12:27:00 +0000</pubDate> </item> <item> <title>Biomimetics photonic nanostructures</title> <description>Overview This one-day course is part of the Nanotechnology Summer School 2014 on nanotechnologies in biology. It can be taken individually or as part of the one-week Summer School. The programme for the Nanoparticles ...</description> <content:encoded><![CDATA[<img src="/img/challenges_and_opportunities_for_structural_dna.jpg" alt="DNA nanostructures as" align="left" /><p>Overview This one-day course is part of the Nanotechnology Summer School 2014 on nanotechnologies in biology. It can be taken individually or as part of the one-week Summer School. The programme for the Nanoparticles, Nanostructures and Biomimetics course provides an introduction to nanoparticles and their applications, as well as biomimetics. It includes the following topics: Natural and incidental nanoparticles Engineered nanoparticles and their syntheses Applications of nanoparticles Biologically inspired nanostructures - introduction to biomimetics Biomimetics of photonic nanostructures Hydrophobic coatings and their applications Spider silk and novel bio-inspired synthetic polymers. Dr Christiane Norenberg Role: Director Christiane is the Nanotechnology HEIF Manager at the University of Oxford's Begbroke Science Park. She received her DPhil in Materials Science from the University of Oxford in 1998 and continued with postdoctoral research. In 2001, Christiane was awarded the Royal Society Dorothy Hodgkin Fellowship for her work on the growth and characterisation of nanostructures on semiconductor surfaces. After a period as a lecturer at the Multidisciplinary Nanotechnology Centre at Swansea University, Christiane returned to Oxford in 2007 to take up her present post. Her interests and expertise are in the areas of surface science, growth and characterisation of nanostructures on surfaces, and nanotechnology in general. Christiane also teaches nanoscience and materials science at undergraduate and postgraduate level. Professor Peter J Dobson OBE Role: Presenter Professor Dobson was the Academic Director at Begbroke Science Park. After a career as a lecturer in Physics at Imperial College and Senior</p>]]></content:encoded> <category><![CDATA[Nanostructures]]></category> <link>http://jsswarriorsupport.com/Nanostructures/biomimetics-photonic-nanostructures</link> <guid isPermaLink="true">http://jsswarriorsupport.com/Nanostructures/biomimetics-photonic-nanostructures</guid> <pubDate>Thu, 14 Mar 2019 12:27:00 +0000</pubDate> </item> <item> <title>Printed Electronics Harmonized</title> <description>Dispensing involves printing organic and inorganic components on various substrates including paper, plastics and textiles. Dispensing encompasses applications including printed electronics, 3D printing and conformal coatings ...</description> <content:encoded><![CDATA[<img src="/img/drivecontrol_drivecontrol_printing_smart_objects.jpg" alt="On the printing press" align="left" /><p>Dispensing involves printing organic and inorganic components on various substrates including paper, plastics and textiles. Dispensing encompasses applications including printed electronics, 3D printing and conformal coatings. Overall system accuracy and throughput are important requirements in these applications to dispense along complex contours. Aerotech's product line is specifically designed with these requirements in mind. Common configurations include gantries, split bridge assemblies and 5 - 6 axis degree of freedom (DOF) systems. Printed electronics involves printing functional electronic circuits, such as OLED displays, electroluminescent lighting, stretchable electronics, wearable sensors, RFID tags and photovoltaic panels on a variety of media. Aerotech motion systems are built for reliability and flexibility, allowing you to bring printed electronics concepts to reality. 6-Axis DOF Dispensing System Split axis, 6 degrees of freedom assembly allows dispensing on complex contours Precision rotational axis of intersection alignments minimize three dimensional stack-up errors at the workpoint. Multi-axis position synchronized output (PSO) couples your dispensing head directly to the encoder feedback for consistent deposition, regardless of the contour complexity or velocity variability, which allows for the highest possible throughput. Direct-drive rotary axes exhibit high acceleration and zero backlash for ultra-smooth velocity regulation. Dual-head configuration allows for two tool points which in turn doubles the process capabilities over the same work area. Aerotech controllers provide coordinated motion between work-points, creating harmonized motion. Systems offered in both “T” style and “H” style gantries (“T” style shown below). Biological Dispensing Printing organic structures has opened up new frontiers in medical research. Printing 3D cell structures provides a better model for studying interactions between cells and growth factors or chemical agents as opposed to traditional 2D cell cultures grown in a dish. Additionally, printing bone scaffolds helps cells heal in severe fractures. Here, pore size of the scaffold is critical to allow cells the ideal environment to grow. Typical pore sizes are hundreds of microns in diameter and require micron-level precision to construct, a core competency of Aerotech systems. Compact 3-Axis Assemblies Ultra-compact, modular direct-drive axes exhibit excellent in-position stability with no hysteresis or backlash, enabling submicron accuracy and repeatability for precise deposition. Nanometer performance (1 nm step size) in a large-travel footprint. Compact design, pneumatic Z. Anti-creep crossed-roller bearings allow for smooth velocity regulation.</p>]]></content:encoded> <category><![CDATA[Printed Electronics]]></category> <link>http://jsswarriorsupport.com/PrintedElectronics/printed-electronics-harmonized</link> <guid isPermaLink="true">http://jsswarriorsupport.com/PrintedElectronics/printed-electronics-harmonized</guid> <pubDate>Tue, 12 Feb 2019 13:23:00 +0000</pubDate> </item> <item> <title>3D printing plastic Electronics</title> <description>The history of printing spans centuries and it’s one that is rich in breakthrough innovations and societal impact – from block printing to movable type to xerography to PARC’s own invention of the laser printer. What is not ...</description> <content:encoded><![CDATA[<img src="/img/3d_printing_electronic_sensors_with_extruded.png" alt="3D printed electronics has" align="left" /><p>The history of printing spans centuries and it’s one that is rich in breakthrough innovations and societal impact – from block printing to movable type to xerography to PARC’s own invention of the laser printer. What is not widely known is that all of these new printing innovations take advantage of the same technologies used in actual printers, such as the printheads; ink, particle, and materials management capabilities; and printhead control. Instead of the familiar ink on paper, it’s an all new “ink” printed on plastic, or glass, or really almost anything. Using semiconducting and conductive inks and materials, we can now print transistors, sensors, circuits, batteries, and displays. Advanced materials can be engineered to behave as a semiconductor, emit light, or sense analytes. In other words, we can now print electronic functionalities and PARC has been exploring a variety of printed components and circuits that are now finding themselves in applications from smart labels to flexible devices to wearable sensors. We are even working on making tiny silicon chiplets into inks, each containing entire circuits. And, of course, we’ve all heard of a little advancement called 3D printing. With the emergence of 3D printing suddenly it becomes accessible to design and build both objects and (for now, fairly simple) devices. It’s the same type of process as we use to edit and print a document, and it’s all happening now. lectronics has the potential to expand additive manufacturing to make things that contain intelligence. Ultimately the transition is more of an evolution – from editing and printing a document (traditional printing) to designing and printing a plastic part (3D) to designing and printing devices that include intelligence (printing electronics or integrated objects). These new advancements hold incredible innovation and business-changing opportunities for many sectors, including printing companies and presses. With business diminishing due to digital distribution and e-books, there are new value chains and models for organizing manufacturing and distribution. The printing industry has the potential to re-tool their own existing set-ups and replace books with electronics. The idea of printing electronics can extend to both a large press or even the personal desktop – much like the equivalent of commercial printers and home desktop printers available today.</p>]]></content:encoded> <category><![CDATA[Printed Electronics]]></category> <link>http://jsswarriorsupport.com/PrintedElectronics/3d-printing-plastic-electronics</link> <guid isPermaLink="true">http://jsswarriorsupport.com/PrintedElectronics/3d-printing-plastic-electronics</guid> <pubDate>Sun, 13 Jan 2019 13:21:00 +0000</pubDate> </item> <item> <title>Cumberland Emerging Technologies</title> <description>Cumberland Emerging Technologies (CET) provides access to a long term pipeline of innovative, biopharmaceutical product candidates. CET was established as a joint initiative between Cumberland Pharmaceuticals Inc., Vanderbilt ...</description> <content:encoded><![CDATA[<img src="/img/performa_free_to_transfer_beale_street.jpg" alt="And Performa were in" align="left" /><p>Cumberland Emerging Technologies (CET) provides access to a long term pipeline of innovative, biopharmaceutical product candidates. CET was established as a joint initiative between Cumberland Pharmaceuticals Inc., Vanderbilt University and the state of Tennessee to identify innovative product candidates and advance them from the laboratory to the marketplace. CET has formal collaboration agreements with leading academic research centers located in the mid-south region of the United States. Through these research centers CET evaluates a range of new emerging technologies and then teams with scientist to develop promising candidates. In addition to these development partnerships, CET manages a Life Sciences Center to support its activities and to help support the growth of the biomedical industry within Tennessee and the region. Dual Focus Development Partnerships – CET works with researchers at universities and other organizations who seek a corporate partner to develop innovative research projects. CET identifies promising therapeutics, diagnostics and other technologies with high commercial potential and provides support to expedite development and improve the probability of success. CET’s role includes technology evaluation, product development, grant program management and commercialization support. CET Life Sciences Center – CET has also formed the CET Life Sciences Center, a business incubator facility that provides laboratory and office space, equipment, and infrastructure to early-stage biomedical companies. Located in the heart of downtown Nashville and just minutes away from renowned research centers including Vanderbilt University, this vibrant Life Sciences Center houses CET’s activities and also creates a collaborative setting to support other life science initiatives.</p>]]></content:encoded> <category><![CDATA[Emerging Technologies]]></category> <link>http://jsswarriorsupport.com/EmergingTechnologies/cumberland-emerging-technologies</link> <guid isPermaLink="true">http://jsswarriorsupport.com/EmergingTechnologies/cumberland-emerging-technologies</guid> <pubDate>Fri, 14 Dec 2018 13:02:00 +0000</pubDate> </item> </channel></rss>If you would like to create a banner that links to this page (i.e. this validation result), do the following:
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