Monthly Archives: February 2015

Oilsands, pipelines, and coastlines at Vancouver’s (Canada) Café Scientifique on Feb. 24, 2015

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Vancouver’s next Café Scientifique is being held in the back room of the The Railway Club (2nd floor of 579 Dunsmuir St. [at Seymour St.], Vancouver, Canada), on Feb. 24,  2015. Here’s the meeting description (from the Feb. 9, 2015 announcement),

Our speaker for the evening will be Dr. Kyle Demes, a Hakai Postdoctoral Fellow in the Coastal Marine Ecology and Conservation lab at SFU.  The title of his talk is:

Inland Oil Sands and Coastal Ecology

Rising overseas oil demand has contributed to a series of proposed pipeline expansion and construction projects to move bitumen from areas of extraction in the interior of Canada to the coast, where it can be loaded onto tankers for shipment. These proposals represent a focal point of controversy in discussions around energy development, climate change and policy across North America and are one of the largest environmental concerns facing British Columbians. I will discuss the ways in which bitumen extraction, transport and shipment influence coastal marine ecosystems, identifying both potential and certain environmental impacts linked with the acceleration of oil sands operations to our coast. I will also review how well we understand each of these environmental impacts, emphasizing key uncertainties in our knowledge and how these gaps affect our ability to make informed decisions on these controversial proposals.

You can find out more about Kyle Demes here.

Nano-Clear® makes lifeboats glossy for Carnival Cruise Lines

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A Feb. 9, 2015 news item on Azonano profiles Carnival Cruise Lines and a deal the company has struck with Nanovere Technologies,

Carnival Cruise Lines implementing Nano-Clear® Coatings to restore their entire fleet of lifeboats.

Ship owners and operators spend a great deal of money and time maintaining their vessels and lifeboats to the highest quality standards, but are often let down by poor appearance. Conventional marine paints and gel coatings are highly susceptible to UV damage, causing the surface to oxidize and loose color over time. Lifeboats are designed to have a bright and glossy appearance for improved safety and visibility, but become dull and less visible over time due to UV damage.

 

A Feb. 7, 2015 Nanovere Technologies press release, which originated the news item, provides more details,

In late 2014, Nanotech Marine Services, based in the UK conducted a field application trial aboard the Queen Elizabeth Ship using Nano-Clear® Coatings manufactured by Nanovere Technologies in Brighton, MI USA. The purpose of the trial was to provide a long-term solution to the gel-coat oxidation issue on the ships lifeboats and tenders, as the orange gel-coat on these vessels are continually exposed to high levels of UV and fade rapidly. This paint oxidation issue has proven to be difficult to overcome including continuous polishing of the surface or a costly new paint job.

Nano-Clear® Coating was applied to the gel-coat surface and left to weather for several months aboard the Queen Elizabeth while operating in the Mediterranean. The field trial represented real world conditions and proved that a polished surface using the traditional cut-and-polish approach, fails surprisingly fast when exposed to harmful UV rays. The test patches coated with Nano-Clear® Coating showed “no” deterioration in gloss or color; as compared with the surrounding area showing a dull surface that will continue to oxidize over time.

Due to the outstanding success of the Nano-Clear® trials on the Queen Elizabeth, Nanotech Marine secured the restoration of 18 lifeboats aboard Queen Victoria. Carnival Cruise Lines is also implementing Nano-Clear® Coatings to restore their entire fleet of lifeboats starting with 26 aboard the Cruise Ship Azura in 2015. Nano-Clear® Coatings provide ship operators, maintenance yards and super yacht owners with a tested and practical solution to restore and maintain high value assets to the highest gloss level for many years.

Nano Clear is the only marine coating in the global market place to enhance, restore and extend the service life of newly painted or highly oxidized painted surfaces by 10 years. Nano-Clear® penetrates deep into the smallest pores of paint, enhancing the underlying color, dramatically improving gloss, scratch resistance, corrosion resistance and extending UV resistance, while reducing surface cleaning by 50%. Nano-Clear® eliminates the need to re-paint, color match or polish gel-coatings, thereby reducing material, labor and maintenance costs.

Nano-Clear® Coatings have been validated by leading global organizations including the US Army, Carnival Cruise Lines, Princimar Chemical Carriers, Toshiba Industrial Products and leading tank car manufactures. To learn more about Nano-Clear® Coatings, please email info@nanocoatings.com, visit www.nanocoatings.com or call (810) 227-0077.

Here’s an image illustrating the pre-NanoClear- and post-NanoClear-coated lifeboats,

Courtesy: Nanovere Technologies

Courtesy: Nanovere Technologies

I last wrote about Nanovere Technologies in a Jan. 2, 2013 post about automotive plastics.

A compendium of attosecond nanophysics papers

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A Feb.11, 2015 news item on Nanowerk features a new book on attosecond nanophysics,

A steadily growing treasure of knowledge has accumulated in the past years on attosecond nanophysics of nanostructured solids, which has, so far, not been sorted and structured.

This has now been rectified by two physics professors, Peter Hommelhoff and Matthias Kling. Together with numerous other authors, they have collected the studies conducted in this very young science field in their book Attosecond Nanophysics: From Basic Science to Applications.

The result is an overview for PhD students and interested students as well as other physicists, who like to gain an overview of ultrafast nanooptics and related fields.

A Feb. 9, 2015 Munich-Centre for Advanced Photonics Technische Universität München (TUM) press release by Thorsten Naeser, which originated the news item, describes the book further,

Elementary particles interacting with light move so fast, that they can only be observed with the help of sophisticated techniques. Typically, the motion of excited electrons in atoms or solids, for example, occurs on attosecond timescales. An attosecond is a billionth of a billionth of a second (10-18 s). Starting a few years ago, scientists around the world have been exploring how electrons in nanostructured solids behave when influenced by extremely short and intense light pulses. In order to observe such rapid electron motion, physicists used light pulses with durations of a few femtoseconds down to attoseconds (a femtosecond lasts 1000 attoseconds). These light flashes act, for example, as an ultrafast shutter, following the principles of conventional camera technology, to take pictures of the fast moving particles in the nanocosm.

The researchers’ new book is a collection of their accumulated knowledge in this new research area, a first publication of its kind. The main attention here is not drawn to single atoms or molecules but rather to nanostructured solids, which are typically comprised of many millions of atoms. The main question is: how do electrons behave under the influence of intense light? The answer to this question is of fundamental importance. This research could lead to new technologies, where the electromagnetic field of the light wave can be used to carefully control minute electronic building blocks. With such lightwave-controlled electronics, switching speeds in the petahertz domain (1015 Hz, one million times a billion operations per second) may be reached. “With this technology we could accelerate current electronics by up to a million times”, explains Matthias Kling, one of the editors of the book.

“Attosecond nanophysics” contains the descriptions of experiments which have been conducted in the last years and resulted in groundbreaking scientific publications. The book also contains their mathematical and physical foundations. “All authors are pioneers in this field”, describes the second editor, Peter Hommelhoff. “We have compiled – for the first time – a book, which conveys a current overview of our knowledge and activities on currently the fastest phenomena in the area of small solids”, elaborates Hommelhoff. With this the authors provide students of upper level physics and PhD students a handy overview of the topic. But also interested colleagues from other disciplines can use this book to gain a first, comprehensive insight into this young field of attosecond nanophysics.

Here’s a link to where you can purchase it.

Self-organizing nanotubes and nonequilibrium systems provide insights into evolution and artificial life

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If you’re interested in the second law of thermodynamics, this Feb. 10, 2015 news item on ScienceDaily provides some insight into the second law, self-organized systems, and evolution,

The second law of thermodynamics tells us that all systems evolve toward a state of maximum entropy, wherein all energy is dissipated as heat, and no available energy remains to do work. Since the mid-20th century, research has pointed to an extension of the second law for nonequilibrium systems: the Maximum Entropy Production Principle (MEPP) states that a system away from equilibrium evolves in such a way as to maximize entropy production, given present constraints.

Now, physicists Alexey Bezryadin, Alfred Hubler, and Andrey Belkin from the University of Illinois at Urbana-Champaign, have demonstrated the emergence of self-organized structures that drive the evolution of a non-equilibrium system to a state of maximum entropy production. The authors suggest MEPP underlies the evolution of the artificial system’s self-organization, in the same way that it underlies the evolution of ordered systems (biological life) on Earth. …

A Feb. 10, 2015 University of Illinois College of Engineering news release (also on EurekAlert), which originated the news item, provides more detail about the theory and the research,

MEPP may have profound implications for our understanding of the evolution of biological life on Earth and of the underlying rules that govern the behavior and evolution of all nonequilibrium systems. Life emerged on Earth from the strongly nonequilibrium energy distribution created by the Sun’s hot photons striking a cooler planet. Plants evolved to capture high energy photons and produce heat, generating entropy. Then animals evolved to eat plants increasing the dissipation of heat energy and maximizing entropy production.

In their experiment, the researchers suspended a large number of carbon nanotubes in a non-conducting non-polar fluid and drove the system out of equilibrium by applying a strong electric field. Once electrically charged, the system evolved toward maximum entropy through two distinct intermediate states, with the spontaneous emergence of self-assembled conducting nanotube chains.

In the first state, the “avalanche” regime, the conductive chains aligned themselves according to the polarity of the applied voltage, allowing the system to carry current and thus to dissipate heat and produce entropy. The chains appeared to sprout appendages as nanotubes aligned themselves so as to adjoin adjacent parallel chains, effectively increasing entropy production. But frequently, this self-organization was destroyed through avalanches triggered by the heating and charging that emanates from the emerging electric current streams. (…)

“The avalanches were apparent in the changes of the electric current over time,” said Bezryadin.

“Toward the final stages of this regime, the appendages were not destroyed during the avalanches, but rather retracted until the avalanche ended, then reformed their connection. So it was obvious that the avalanches correspond to the ‘feeding cycle’ of the ‘nanotube inset’,” comments Bezryadin.

In the second relatively stable stage of evolution, the entropy production rate reached maximum or near maximum. This state is quasi-stable in that there were no destructive avalanches.

The study points to a possible classification scheme for evolutionary stages and a criterium for the point at which evolution of the system is irreversible—wherein entropy production in the self-organizing subsystem reaches its maximum possible value. Further experimentation on a larger scale is necessary to affirm these underlying principals, but if they hold true, they will prove a great advantage in predicting behavioral and evolutionary trends in nonequilibrium systems.

The authors draw an analogy between the evolution of intelligent life forms on Earth and the emergence of the wiggling bugs in their experiment. The researchers note that further quantitative studies are needed to round out this comparison. In particular, they would need to demonstrate that their “wiggling bugs” can multiply, which would require the experiment be reproduced on a significantly larger scale.

Such a study, if successful, would have implications for the eventual development of technologies that feature self-organized artificial intelligence, an idea explored elsewhere by co-author Alfred Hubler, funded by the Defense Advanced Research Projects Agency [DARPA]. [emphasis mine]

“The general trend of the evolution of biological systems seems to be this: more advanced life forms tend to dissipate more energy by broadening their access to various forms of stored energy,” Bezryadin proposes. “Thus a common underlying principle can be suggested between our self-organized clouds of nanotubes, which generate more and more heat by reducing their electrical resistance and thus allow more current to flow, and the biological systems which look for new means to find food, either through biological adaptation or by inventing more technologies.

“Extended sources of food allow biological forms to further grow, multiply, consume more food and thus produce more heat and generate entropy. It seems reasonable to say that real life organisms are still far from the absolute maximum of the entropy production rate. In both cases, there are ‘avalanches’ or ‘extinction events’, which set back this evolution. Only if all free energy given by the Sun is consumed, by building a Dyson sphere for example, and converted into heat then a definitely stable phase of the evolution can be expected.”

“Intelligence, as far as we know, is inseparable from life,” he adds. “Thus, to achieve artificial life or artificial intelligence, our recommendation would be to study systems which are far from equilibrium, with many degrees of freedom—many building blocks—so that they can self-organize and participate in some evolution. The entropy production criterium appears to be the guiding principle of the evolution efficiency.”

I am fascinated

  • (a) because this piece took an unexpected turn onto the topic of artificial life/artificial intelligence,
  • (b) because of my longstanding interest in artificial life/artificial intelligence,
  • (c) because of the military connection, and
  • (d) because this is the first time I’ve come across something that provides a bridge from fundamental particles to nanoparticles.

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

Self-Assembled Wiggling Nano-Structures and the Principle of Maximum Entropy Production by A. Belkin, A. Hubler, & A. Bezryadin. Scientific Reports 5, Article number: 8323 doi:10.1038/srep08323 Published 09 February 2015

Adding to my delight, this paper is open access.

Fish skin for wound healing

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A Feb. 11, 2015 news item on Nanowerk features Chinese research on tilapia fish skin and possible applications for wound healing (Note: A link has been removed),

With a low price tag and mild flavor, tilapia has become a staple dinnertime fish for many Americans. Now it could have another use: helping to heal our wounds. In the journal ACS Applied Materials & Interfaces (“Development of Biomimetic Tilapia Collagen Nanofibers for Skin Regeneration through Inducing Keratinocytes Differentiation and Collagen Synthesis of Dermal Fibroblasts”), scientists have shown that a protein found in this fish can promote skin repair in rats without an immune reaction, suggesting possible future use for human patients.

A Feb. 11, 2015 American Chemical Society (ACS) news release, which originated the news item, provides a few more details about the work,

Jiao Sun, Xiumei Mo and colleagues explain that applying collagen — a major structural protein in animals — to wounds can help encourage skin to heal faster.  But when the protein dressing comes from mammals such as cows and pigs, it has the potential to transmit conditions such as foot-and-mouth disease. Searching for an alternative source of collagen, scientists recently turned to the ocean. Sun’s team wanted to test fish collagen’s potential as a more benign wound treatment.

The researchers developed nanofibers from tilapia collagen and used them to cover skin wounds on rats. The rats with the nanofiber dressing healed faster than those without it. In addition, lab tests on cells suggested that the fish collagen was not likely to cause an immune reaction. The researchers conclude that it could be a good candidate to develop for clinical use.

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

Development of Biomimetic Tilapia Collagen Nanofibers for Skin Regeneration through Inducing Keratinocytes Differentiation and Collagen Synthesis of Dermal Fibroblasts by Tian Zhou, Nanping Wang, Yang Xue, Tingting Ding, Xin Liu, Xiumei Mo, and Jiao Sun. ACS Appl. Mater. Interfaces, 2015, 7 (5), pp 3253–3262 DOI: 10.1021/am507990m Publication Date (Web): January 19, 2015

Copyright © 2015 American Chemical Society

This article is behind a paywall.

Nanoscale antioxidants

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A Feb. 10, 2015 news item on Azonano features injectable nanoparticles that act as antioxidants useful in case of injury, in particular, brain injury,

Injectable nanoparticles that could protect an injured person from further damage due to oxidative stress have proven to be astoundingly effective in tests to study their mechanism.

Scientists at Rice University, Baylor College of Medicine and the University of Texas Health Science Center at Houston (UTHealth) Medical School designed methods to validate their 2012 discovery that combined polyethylene glycol-hydrophilic carbon clusters — known as PEG-HCCs — could quickly stem the process of overoxidation that can cause damage in the minutes and hours after an injury.

A Feb. 9, 2015 Rice University news release (also on EurekAlert), which originated the news item, describe the benefits in more detail,

The tests revealed a single nanoparticle can quickly catalyze the neutralization of thousands of damaging reactive oxygen species molecules that are overexpressed by the body’s cells in response to an injury and turn the molecules into oxygen. These reactive species can damage cells and cause mutations, but PEG-HCCs appear to have an enormous capacity to turn them into less-reactive substances.

The researchers hope an injection of PEG-HCCs as soon as possible after an injury, such as traumatic brain injury or stroke, can mitigate further brain damage by restoring normal oxygen levels to the brain’s sensitive circulatory system.

“Effectively, they bring the level of reactive oxygen species back to normal almost instantly,” said Rice chemist James Tour. “This could be a useful tool for emergency responders who need to quickly stabilize an accident or heart attack victim or to treat soldiers in the field of battle.” Tour led the new study with neurologist Thomas Kent of Baylor College of Medicine and biochemist Ah-Lim Tsai of UTHealth.

The news release goes on to describe the antioxidant particles and previous research,

PEG-HCCs are about 3 nanometers wide and 30 to 40 nanometers long and contain from 2,000 to 5,000 carbon atoms. In tests, an individual PEG-HCC nanoparticle can catalyze the conversion of 20,000 to a million reactive oxygen species molecules per second into molecular oxygen, which damaged tissues need, and hydrogen peroxide while quenching reactive intermediates.

Tour and Kent led the earlier research that determined an infusion of nontoxic PEG-HCCs may quickly stabilize blood flow in the brain and protect against reactive oxygen species molecules overexpressed by cells during a medical trauma, especially when accompanied by massive blood loss.

Their research targeted traumatic brain injuries, after which cells release an excessive amount of the reactive oxygen species known as a superoxide into the blood. These toxic free radicals are molecules with one unpaired electron that the immune system uses to kill invading microorganisms. In small concentrations, they contribute to a cell’s normal energy regulation. Generally, they are kept in check by superoxide dismutase, an enzyme that neutralizes superoxides.

But even mild traumas can release enough superoxides to overwhelm the brain’s natural defenses. In turn, superoxides can form such other reactive oxygen species as peroxynitrite that cause further damage.

“The current research shows PEG-HCCs work catalytically, extremely rapidly and with an enormous capacity to neutralize thousands upon thousands of the deleterious molecules, particularly superoxide and hydroxyl radicals that destroy normal tissue when left unregulated,” Tour said.

“This will be important not only in traumatic brain injury and stroke treatment, but for many acute injuries of any organ or tissue and in medical procedures such as organ transplantation,” he said. “Anytime tissue is stressed and thereby oxygen-starved, superoxide can form to further attack the surrounding good tissue.”

These details about the research are also noted in the news release,

The researchers used an electron paramagnetic resonance spectroscopy technique that gets direct structure and rate information for superoxide radicals by counting unpaired electrons in the presence or absence of PEG-HCC antioxidants. Another test with an oxygen-sensing electrode, peroxidase and a red dye confirmed the particles’ ability to catalyze superoxide conversion.

“In sharp contrast to the well-known superoxide dismutase, PEG-HCC is not a protein and does not have metal to serve the catalytic role,” Tsai said. “The efficient catalytic turnover could be due to its more ‘planar,’ highly conjugated carbon core.”

The tests showed the number of superoxides consumed far surpassed the number of possible PEG-HCC bonding sites. The researchers found the particles have no effect on important nitric oxides that keep blood vessels dilated and aid neurotransmission and cell protection, nor was the efficiency sensitive to pH changes.

“PEG-HCCs have enormous capacity to convert superoxide to oxygen and the ability to quench reactive intermediates while not affecting nitric oxide molecules that are beneficial in normal amounts,” Kent said. “So they hold a unique place in our potential armamentarium against a range of diseases that involve loss of oxygen and damaging levels of free radicals.”

The study also determined PEG-HCCs remain stable, as batches up to 3 months old performed as good as new.

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

Highly efficient conversion of superoxide to oxygen using hydrophilic carbon clusters by Errol L. G. Samuel, Daniela C. Marcano, Vladimir Berka, Brittany R. Bitner, Gang Wu, Austin Potter, Roderic H. Fabian, Robia G. Pautler, Thomas A. Kent, Ah-Lim Tsai, and James M. Tour. Published online before print February 9, 2015, doi: 10.1073/pnas.1417047112 PNAS February 9, 2015

This paper is behind a paywall.

Can the future influence the past? The answer is: mostly yes

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The principles of quantum mechanics mystify me which, as it turns out, is the perfect place to start with the work featured in a Feb. 9, 2015 news item on ScienceDaily,

We’re so used to murder mysteries that we don’t even notice how mystery authors play with time. Typically the murder occurs well before the midpoint of the book, but there is an information blackout at that point and the reader learns what happened then only on the last page.

If the last page were ripped out of the book, physicist Kater Murch, PhD, said, would the reader be better off guessing what happened by reading only up to the fatal incident or by reading the entire book?

The answer, so obvious in the case of the murder mystery, is less so in world of quantum mechanics, where indeterminacy is fundamental rather than contrived for our reading pleasure.

A Feb. 13, 2015 Washington University at St. Louis (WUSTL) news release by Diana Lutz, which originated the news item, describes the research,

Even if you know everything quantum mechanics can tell you about a quantum particle, said Murch, an assistant professor of physics in Arts & Sciences at Washington University in St. Louis, you cannot predict with certainty the outcome of a simple experiment to measure its state. All quantum mechanics can offer are statistical probabilities for the possible results.

The orthodox view is that this indeterminacy is not a defect of the theory, but rather a fact of nature. The particle’s state is not merely unknown, but truly undefined before it is measured. The act of measurement itself that forces the particle to collapse to a definite state.

It’s as if what we did today, changed what we did yesterday. And as this analogy suggests, the experimental results have spooky implications for  time and causality—at least in microscopic world to which quantum mechanics applies.

Until recently physicists could explore the quantum mechanical properties of single particles only through thought experiments, because any attempt to observe them directly caused them to shed their mysterious quantum properties.

But in the 1980s and 1990s physicists invented devices that allowed them to measure these fragile quantum systems so gently that they don’t immediately collapse to a definite state.

The device Murch uses to explore quantum space is a simple superconducting circuit that enters quantum space when it is cooled to near absolute zero. Murch’s team uses the bottom two energy levels of this qubit, the ground state and an excited state, as their model quantum system. Between these two states, there are an infinite number of quantum states that are superpositions, or combinations, of the ground and excited states.

The quantum state of the circuit is detected by putting it inside a microwave box. A few microwave photons are sent into the box, where their quantum fields interact with the superconducting circuit. So when the photons exit the box they bear information about the quantum system.

Crucially, these “weak,” off-resonance measurements do not disturb the qubit, unlike “strong” measurements with photons that are resonant with the energy difference between the two states, which knock the circuit into one or the other state.

In Physical Review Letters, Murch describes a quantum guessing game played with the qubit.

“We start each run by putting the qubit in a superposition of the two states,” he said. “Then we do a strong measurement but hide the result, continuing to follow the system with weak measurements.”

They then try to guess the hidden result, which is their version of the missing page of the murder mystery.

“Calculating forward, using the Born equation that expresses the probability of finding the system in a particular state, your odds of guessing right are only 50-50,” Murch said. “But you can also calculate backward using something called an effect matrix. Just take all the equations and flip them around. They still work and you can just run the trajectory backward.

“So there’s a backward-going trajectory and a forward-going trajectory and if we look at them both together and weight the information in both equally, we get something we call a hindsight prediction, or “retrodiction.”

The shattering thing about the retrodiction is that it is 90 percent accurate. When the physicists check it against the stored measurement of the system’s earlier state it is right nine times out of 10.

Going from a 50% accuracy rate to 90% is quite amazing and according to the news release, this has many implications,

The quantum guessing game suggests ways to make both quantum computing and the quantum control of open systems, such as chemical reactions, more robust. But it also has implications for much deeper problems in physics.

For one thing, it suggests that in the quantum world time runs both backward and forward whereas in the classical world it only runs forward.

“I always thought the measurement would resolve the time symmetry in quantum mechanics,” Murch said. “If we measure a particle in a superposition of states and it collapses into one of two states, well, that sounds like a process that goes forward in time.”

But in the quantum guessing experiment, time symmetry has returned. The improved odds imply the measured quantum state somehow incorporates information from the future as well as the past. And that implies that time, notoriously an arrow in the classical world, is a double-headed arrow in the quantum world.

“It’s not clear why in the real world, the world made up of many particles, time only goes forward and entropy always increases,” Murch said. “But many people are working on that problem and I expect it will be solved in a few years,” he said.

In a world where time is symmetric, however, is there such a thing as cause and effect? To find out, Murch proposes to run a qubit experiment that would set up feedback loops (which are chains of cause and effect) and try to run them both forward and backward.

“It takes 20 or 30 minutes to run one of these experiments,” Murch said, “several weeks to process it, and a year to scratch our heads to see if we’re crazy or not.”

“At the end of the day,” he said, “I take solace in the fact that we have a real experiment and real data that we plot on real curves.”

Here are links to and citations for the Physical Review paper and an earlier version of the paper,

 Prediction and retrodiction for a continuously monitored superconducting qubit by D. Tan, S. Weber, I. Siddiqi, K. Mølmer, K. W. Murch. arXiv.org > quant-ph > arXiv:1409.0510 (Submitted on 1 Sep 2014 (v1), last revised 10 Nov 2014 (this version, v2))

I last mentioned Kater Murch and his work in a July 31, 2014 post titled: Paths of desire: quantum style.

Swedish nano plans in Lund

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It was a bit a surprise to learn a few years ago that Chalmers University of Technology (Sweden) was the lead in the European Union’s Graphene Flagship project. I was expecting the lead to be one of the British universities, specifically, the University of Manchester seeing that graphene was first isolated there by Nobel Laureates Andre Geim and Konstantan (Kostya) Novoselov, Since then, I’ve kept an eye on the Swedish nanotechnology enterprise and am pleased to have received a Feb. 13, 2014 announcement about hopes for establishing a new nano centre in Lund, Sweden,

A production facility for start-ups in the field of nanotechnology may be built in the Science Village in Lund, a world-class research and innovation village that is also home to ESS, the European Spallation Source.

“With this new facility, we want to create the conditions to enable new companies to develop from the R&D phase to full production, without needing to leave Sweden,” says Lars Samuelson, Professor of Nanophysics at Lund University.

The project originates from the successful research into nanowires at Lund University, which has resulted in nanotechnology companies like Glo AB and Sol Voltaics AB. Glo was forced to move to Silicon Valley, however, to launch large-scale mass production.

The infrastructure would be intended for companies and researchers in the whole of Sweden who want to develop products with industry standards without needing to invest in expensive equipment themselves.

Samuelson sees more business opportunities for nanowires. In addition to Glo’s light-emitting diodes and Sol Voltaics’ solar cells, Lars Samuelson believes there is potential for new companies focused on applications within electronics, UV light-emitting diodes and biomedicine.

Alongside this project, Lund University is working to extend the Lund Nano Lab which is a pure research laboratory for research on nanowires. This is run by Lund University, whereas the industrial facility is a project outside the University. Together, these two initiatives constitute a way of generating the whole value chain from research to market.

The preliminary study into the facility, funded by Vinnova [Sweden’s innovation agency] and Region Skåne and initiated by the Nanometer Structure Consortium at Lund University, is to result in an estimate of investment requirements and market potential, as well as a proposal for a business model. The aim is to become internationally competitive and financially self-sufficient.

A cluster of companies and services, close to the University’s research, is expected to develop around the common equipment for nanoproduction.

About the Nanometer Structure Consortium at Lund University nmC@LU

The Nanometer Structure Consortium at Lund University was founded in 1989. Today, it is one of Sweden’s Strategic Research Areas, engaging more than 250 researchers at the Faculties of Engineering, Science and Medicine. The research focuses on the materials science of nanostructures and its applications within fundamental science, electronics, optoelectronics, energy conversion and life sciences. Former start-ups from the Nanometer Structure Consortium currently employ around 150 people and have attracted private investments of over one billion Swedish crowns.

I suspect this announcement is intended to both raise awareness and, more importantly, attract potential investors as it goes on to provide a number of contacts,

Initiator: Lars Samuelson, Professor, Nanometer Structure Consortium, Lund University, tel. +46 46 222 76 79, lars.samuelson@ftf.lth.se

Chair of the project’s steering group: Heiner Linke, Professor, Coordinator of the Nanometer Structure Consortium, Lund University, tel. +46 46 222 42 45, heiner.linke@ftf.lth.se

Project manager: Yvonne Mårtensson, Nanova, tel. +46 708 337782, yvonne.martensson@nanova.se

Daniel Kronmann, Innovation Systems Unit, Region Skåne, 040-675 34 36, 0706-15 28 10, Daniel.Kronmann@skane.se

International Media Officer
lotte.billing@er.lu.se
+46 72 7074546

I wish them good luck with their plans.

The business of nano; the business of graphene

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There are a couple of recent columns by Tim Harper, a well known and longstanding figure in the ‘nano community’, about business predictions and the nanotechnology and graphene markets, respectively I want to feature here. (See my July 15, 2011 interview with Harper about his report on global funding of nanotechnology for a description of him, his then-business, Cientifica, and his perspective on the nanotechnology enterprise at that time.)

One of Harper’s most recent writings, in a Jan. 2, 2015 column on Azonano, is a look back at business predictions for nanotechnology (Note: Links have been removed). What makes this particularly interesting is that Tim was part of the UK effort in its earliest days and has consulted with governments (including Canada) on their nanotechnology and commercialization efforts,

One of the most widely repeated predictions for nanotechnologies was its role in the creation of a trillion dollar industry by 2015, predicted by Mike Roco [one of the moving forces behind the US National Nanotechnology Initiative enacted in 2000] and his colleagues at the National Science Foundation.2

Looking back at the original National Nanotechnology Initiative forecasts, the biggest economic contributions of nanotechnology came from materials ($340bn), electronics ($300bn), pharmaceuticals ($180bn), chemicals ($100bn), transportation ($70bn) and sustainability ($100bn).

But as is often the case with headline numbers, these were not the product of a huge data collection exercise, but estimates based on a few reports and private communications (see below).

….

The large numbers caused some debate at the time as to whether it was the value of the nanotechnology, or the value of the product, that should be used. One oft-cited example was that in some analyses, the addition of a nanotech-based anti-scratch paint to an automobile would result in the entire value of the car being added to the “nanotechnology market’ column, while in others it would be just the value of the nanoparticles used.

My preference at the time was to use the value of something that would not have existed without the nanotechnology; the automobile clearly would have done, but the anti-scratch paint would not.

While market numbers are always speculative I can still point to one prediction I got right: “there is not, and never will be, a nanotechnology industry”.3

Fifteen years on from the inception of the National Nanotechnology Initiative, there’s not much to carp about. Nanotechnology research is well funded globally, and leading to exactly the kind of breakthroughs that were envisaged back in the late 90’s. As nobody managed to predict the iPhone, Twitter or Facebook, that is remarkable.

The greatest legacy of the mythical “trillion dollar market” was the fear of missing out (or even of allowing the US to dominate), and that was sufficient to spur many similar efforts in other countries. This, combined with widespread adoption of the Internet, made nanotechnology the first truly global scientific revolution.

For anyone who likes to research, Tim provides a list of references used to support his contentions.

He then writes a Feb. 4, 2015 column on Azonano about graphene , which provides an interesting contrast (Note: Links have been removed),

The discussion of the trillion dollar market for nanotechnologies has generated quite a bit of interest and discussion. Anyone who remembers nanotechnology a decade ago will notice that graphene is going through a similar period of hype.

The one thing missing from all the discussion of graphene is any inflated market numbers. In fact, compared to the frenzied overhyping of nanotechnologies, the estimates for graphene markets tend to be conservative in the extreme.

A rash of recent market estimates towards the end of last year put the international market for graphene in the range of a few hundred million dollars. That’s pretty much the same amount as has been raised by or invested in graphene producers around the world, and investing $150 million to unlock a market worth $150 million doesn’t seem to make very much sense to me. So are graphene producers completely wrong, or are the market estimates wildly inaccurate?

Confusingly, it appears that everybody is right. It just happens that we are talking about different kinds of graphene at different points in the value chain.

… Some have bought pure graphene to play with themselves, but in reality industry wants to buy inks, dispersions and master batches, rather than have the hassle of taking a bag of black powder and adapting it for applications which may be rather ill-defined at this point. Providing those ready-to-use products is what will unlock the market for graphene.

This turns out to be rather good news for graphene producers, because in general an ink containing perhaps a 20% loading of graphene nano platelets (GNPs) can represent a 5000% markup over the cost of the raw material. A rather simplistic extrapolation from this suggests a $1 billion graphene intermediates market within five years.

And it gets better. Some of the GNPs show good potential as a carbon black substitute – a 2% loading of GNP could perform at least as well as a 20% loading of carbon black. Even if the GNP price is 7-8 times higher than carbon black, there is still a significant margin for the end user to play with.

Woohoo! Now that’s something I can probably talk to investors about without being shown the door after my second PowerPoint slide. And when the inevitable comment, “you predict a market of a billion while these guys say 100 million,” comes up, I’ll have a snappy comeback.

There’s more information about Tim and there are more posts on his website, timharper.net. While, he does offer three different links to additional biographical information from timharper.net, I have a particular affection for his Visualize.me bio page.