Nanobots—at last

Who can resist Etta James? Getting to the point of the post, I’ve been reading about nanobots for years but this is the first time I’ve seen something that resembles what lived in my imagination—at last. From a Sept. 20 , 2017 news item on phys.org (Note: Links have been removed),

Scientists at The University of Manchester have created the world’s first ‘molecular robot’ that is capable of performing basic tasks including building other molecules.

The tiny robots, which are a millionth of a millimetre in size, can be programmed to move and build molecular cargo, using a tiny robotic arm.

Each individual robot is capable of manipulating a single molecule and is made up of just 150 carbon, hydrogen, oxygen and nitrogen atoms. To put that size into context, a billion billion of these robots piled on top of each other would still only be the same size as a single grain of salt.

The robots operate by carrying out chemical reactions in special solutions which can then be controlled and programmed by scientists to perform the basic tasks.

In the future such robots could be used for medical purposes, advanced manufacturing processes and even building molecular factories and assembly lines. …

A Sept. 20, 2017 University of Manchester press release (also on EurekAlert), which originated the news item, provides (perhaps) a little more explanation than is absolutely necessary,

Professor David Leigh, who led the research at University’s School of Chemistry, explains: ‘All matter is made up of atoms and these are the basic building blocks that form molecules. [emphasis mine] Our robot is literally a molecular robot constructed of atoms just like you can build a very simple robot out of Lego bricks. The robot then responds to a series of simple commands that are programmed with chemical inputs by a scientist.

‘It is similar to the way robots are used on a car assembly line. Those robots pick up a panel and position it so that it can be riveted in the correct way to build the bodywork of a car. So, just like the robot in the factory, our molecular version can be programmed to position and rivet components in different ways to build different products, just on a much smaller scale at a molecular level.’

The benefit of having machinery that is so small is it massively reduces demand for materials, can accelerate and improve drug discovery, dramatically reduce power requirements and rapidly increase the miniaturisation of other products. Therefore, the potential applications for molecular robots are extremely varied and exciting.

Prof Leigh says: ‘Molecular robotics represents the ultimate in the miniaturisation of machinery. Our aim is to design and make the smallest machines possible. This is just the start but we anticipate that within 10 to 20 years molecular robots will begin to be used to build molecules and materials on assembly lines in molecular factories.’

Whilst building and operating such tiny machine is extremely complex, the techniques used by the team are based on simple chemical processes.

Prof Leigh added: ‘The robots are assembled and operated using chemistry. This is the science of how atoms and molecules react with each other and how larger molecules are constructed from smaller ones.

‘It is the same sort of process scientists use to make medicines and plastics from simple chemical building blocks. Then, once the nano-robots have been constructed, they are operated by scientists by adding chemical inputs which tell the robots what to do and when, just like a computer program.’

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

Stereodivergent synthesis with a programmable molecular machine by Salma Kassem, Alan T. L. Lee, David A. Leigh, Vanesa Marcos, Leoni I. Palmer, & Simone Pisano. Nature 549,
374–378 (21 September 2017) doi:10.1038/nature23677 Published online 20 September 2017

This paper is behind a paywall.

There’s a rather attractive image accompanying the news release which manages to be both quite informative and wholly unrealistic,

Courtesy: University of Manchester

Nanobots first made their way into popular science with K. Eric Drexler’s book 1986, Engines of Creation, which also provoked a spirited academic debate. See Drexler’s Wikipedia entry for more. One final comment, this would seem to be a promising start to the long-held dream of bottom-up engineering of materials.

Simon Fraser University (Vancouver, Canada) and its president’s (Andrew Petter) dream colloquium: women in technology

I’m a little late with this event news (sadly,. I only received the information yesterday, Sept. 20, 2017) but even with two event dates already past (happily, videos for the two events have been posted), there are still several “Women in Technology” events to attend or view live according to the Simon Fraser University (SFU) President’s Dream Colloquium: Women in Technology; Attaining, Retaining, and Promoting Diverse Talent’s webpage text by Wan Yee Lok,

Women in Technology: Attracting, Retaining and Promoting Diverse Talent is a seven-part public [emphasis mine] lecture series beginning on Sept. 13. Key experts from around the world will identify challenges to gender equity and discover solutions for improving recruitment, retention and leadership options for women.

Diversity and inclusion are critical to high-tech corporate success. Yet statistics reveal that less than 25 per cent of those working in the science, technology, engineering and math sectors (STEM) are women, and that they earn seven-and-a-half per cent less than men.

“There is a crucial need to achieve gender equality in the tech sector, especially at a time when it is growing faster than ever,” says colloquium organizer Lesley Shannon, an SFU engineering science professor. She holds the Natural Sciences and Engineering Research Council (NSERC) Chair for Women in Science and Engineering for the B.C. and Yukon region.

“We hope the colloquium will help people engage in a multidisciplinary dialogue about the value of creating more space in technology for women and other under-represented groups.”

Six of the lectures are free, except for Cathy O’Neil’s lecture on Oct. 26.

The President’s Dream Colloquium schedule is as follows:

Sept. 13: SFU KEY presents: We the Data
Juliette Powell, founder, Turing AI and WeTheData.org, author of 33 Million People in the Room

Sept. 14: Diversity 101: The Case for Diversity in Technology
Maria Klawe, president, Harvey Mudd College

Sept. 21: Women in Media and Advertising
Shari Graydon, catalyst, Informed Opinions

Oct. 12: Social Psychological Phenomena
Steven Spencer, the Robert K. and Dale J. Weary Chair in Social Psychology, Ohio State University

Oct. 26: Gender and Bias in Algorithmic Design
Cathy O’Neil, author, Weapons of Math Destruction [tickets are $5 for students; $15 for the rest of us; go here to buy tickets, click on green button in the upper right, below the banner; the event will be held at SFU’s Harbour Centre Vancouver location]

Nov 9: Gendered Language
Danielle Gaucher, associate professor, Department of Psychology, University of Winnipeg

Nov. 23: Women as Leaders and Innovators
Jo Miller, founder, Be Leaderly

Lectures will be webcast live and available on the President’s Dream Colloquium website, www.sfu.ca/womenintech.

SFU engineering science professor Lesley Shannon is the colloquium organizer as well as the Natural Sciences and Engineering Research Council (NSERC) Chair for Women in Science and Engineering for the B.C. and Yukon region.

 

As a part of the colloquium, students can enroll in a graduate course covering a broad range of topics related to diversity in the technology sector. Shannon says the course will focus on women and their role in technology as well as issues that affect other under‐represented groups.

“I hope the course will establish a foundation for future managers, supervisors, sponsors, mentors and others wanting to pursue leadership roles to work towards creating a level playing field in technology and other industries,” says Shannon.

The colloquium course (SAR 897) is still accepting students. Visit go.sfu.ca to enroll.

A reminder after the last few paragraphs of the event text, you don’t actually have to be a student to attend the lectures although for anyone who doesn’t want to make the trek up the hill (SFU is located on a hill in Burnaby, BC) for the majority of the events, there is the livestream video. For those who can’t make the scheduled times, given that both the Sept. 13 and Sept. 14, 2017 event videos have been posted, they are being pretty quick about uploading the videos afterwards.

I have mentioned Cathy O’Neil here a couple of times, more substantively in a Feb. 28, 2017 posting about a major’ big data’ collaboration between the province of BC and the state of Washington (for Cathy O’Neil, scroll down to the subsection titled: Algorithms and big data) and briefly at the end in a May 24, 2017 posting that was chiefly concerned with bias in algorithms.

Measurably fewer nanoparticles in São Paulo’s (Brazil) air after ethanol use

An Aug. 28, 2017 news item on Nanotechnology Now features news about nanoparticles and the environment in São Paulo, Brazil,

When ethanol prices at the pump rise for whatever reason, it becomes economically advantageous for drivers of dual-fuel vehicles to fill up with gasoline. However, the health of the entire population pays a high price: substitution of gasoline for ethanol leads to a 30% increase in the atmospheric concentration of ultrafine particulate matter, which consists of particles with a diameter of less than 50 nanometers (nm).

An Aug. 23, 2017 Fundação de Amparo à Pesquisa do Estado de São Paulo (The São Paulo Research Foundation [FAPESP]) press release, which originated the news item, explains further,

The phenomenon was detected in São Paulo City, Brazil, in a study supported by FAPESP and published in July 2017 in Nature Communications.

“These polluting nanoparticles are so tiny that they behave like gas molecules. When inhaled, they can penetrate the respiratory system’s defensive barriers and reach the pulmonary alveoli, so that potentially toxic substances enter the bloodstream and may increase the incidence of respiratory and cardiovascular problems,” said Paulo Artaxo, Full Professor at the University of São Paulo’s Physics Institute (IF-USP) and a co-author of the study.

Levels of ultrafine particulate matter in the atmosphere are neither monitored nor regulated by environmental agencies not only in Brazil but practically anywhere in the world, according to Artaxo. The São Paulo State Environmental Corporation (CETESB), for example, routinely monitors only solid particles with diameters of 10,000 nm (PM10) and 2,500 nm (PM2.5) – as well as other gaseous pollutants such as ozone (O3), carbon monoxide (CO) and nitrogen dioxide (NO2).

“Between 75% and 80% of the mass of the nanoparticles we measured in this study corresponds to organic compounds emitted by motor vehicles – carbon in different chemical forms. What these compounds are exactly and how they affect health are questions that require further research,” Artaxo said.

He added that a consensus is forming in the United States and Europe based on recent research indicating that these emissions are a potential health hazard and should be regulated. Several US states, such as California, have laws requiring a 20%-30% ethanol blend in gasoline, which also helps reduce emissions of ultrafine particulate matter.

Methodology

The data analyzed in the study were collected during the period of January-May 2011, when ethanol prices fluctuated sharply compared with gasoline prices, owing to macroeconomic factors such as variations in the international price of sugar (Brazilian ethanol is made from sugarcane).

Collection was performed at the top of a ten-story building belonging to IF-USP in the western part of São Paulo City. According to Artaxo, the site was chosen because it is relatively distant from the main traffic thoroughfares so that the aerosols there are “older” in the sense that they have already interacted with other substances present in the atmosphere.

“Generally speaking, the pollution we inhale every day at home or at work isn’t what comes out of vehicular exhaust pipes but particles already processed in the atmosphere,” he explained. “For this reason, we chose a site that isn’t directly impacted by primary vehicle emissions.”

The study was conducted during Joel Ferreira de Brito’s postdoctoral research, which Artaxo supervised. The model used to analyze the data was developed by Brazilian economist Alberto Salvo, a professor at the National University of Singapore and first author of the article. Franz Geiger, a chemist at Northwestern University in the US, also collaborated.

“We adapted a sophisticated statistical model originally developed for economic analysis and used here for the first time to analyze the chemistry of atmospheric nanoparticles,” Artaxo said. “The main strength of this tool is that it can work with a large number of variables, such as the presence or absence of rainfall, wind direction, traffic intensity, and levels of ozone, carbon monoxide and other pollutants.”

Analyses were performed before, during and after a sharp fluctuation in ethanol prices leading consumers to switch motor fuels in São Paulo City. While no significant changes were detected in levels of inhalable fine particulate matter (PM2.5 and PM10), the study proved in a real, day-to-day situation that choosing ethanol reduces emissions of ultrafine particles. To date, this phenomenon had only been observed in the laboratory.

“These results reinforce the need for public policies to encourage the use of biofuels, as they clearly show that the public lose in health what they save at the pump when opting for gasoline,” Artaxo said.

In São Paulo, a city with 7 million motor vehicles and the largest urban fleet of flexible-fuel cars, it would be feasible to run all buses on biofuel. “We have the technology for this in Brazil – and at a competitive price,” he said.

The fact that the city’s bus fleet still depends on diesel, Artaxo warned, creates an even worse health hazard in the shape of emissions of black carbon, one of the main components of soot and a pollutant that contributes to global warming. Alongside electricity generation, the transportation sector is the largest emitter of pollutants produced by the burning of fossil fuels.

For Artaxo, incentives for electric, hybrid or biofuel vehicles are vital to reduce greenhouse gas emissions. “By incentivizing biofuels, we could solve several problems at once,” he said. “We could combat climate change, reduce harm to health and foster advances in automotive technology by offering a stimulus for auto makers to develop more economical and efficient cars fueled by ethanol.”

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

Reduced ultrafine particle levels in São Paulo’s atmosphere during shifts from gasoline to ethanol use by Alberto Salvo, Joel Brito, Paulo Artaxo, & Franz M. Geiger. Nature Communications 8, Article number: 77 (2017) doi:10.1038/s41467-017-00041-5 Published online: 18 July 2017

This paper is open access.

Yarns that harvest and generate energy

The researchers involved in this work are confident enough about their prospects that they will be  patenting their research into yarns. From an August 25, 2017 news item on Nanowerk,

An international research team led by scientists at The University of Texas at Dallas and Hanyang University in South Korea has developed high-tech yarns that generate electricity when they are stretched or twisted.

In a study published in the Aug. 25 [2017] issue of the journal Science (“Harvesting electrical energy from carbon nanotube yarn twist”), researchers describe “twistron” yarns and their possible applications, such as harvesting energy from the motion of ocean waves or from temperature fluctuations. When sewn into a shirt, these yarns served as a self-powered breathing monitor.

“The easiest way to think of twistron harvesters is, you have a piece of yarn, you stretch it, and out comes electricity,” said Dr. Carter Haines, associate research professor in the Alan G. MacDiarmid NanoTech Institute at UT Dallas and co-lead author of the article. The article also includes researchers from South Korea, Virginia Tech, Wright-Patterson Air Force Base and China.

An August 25, 2017 University of Texas at Dallas news release, which originated the news item, expands on the theme,

Yarns Based on Nanotechnology

The yarns are constructed from carbon nanotubes, which are hollow cylinders of carbon 10,000 times smaller in diameter than a human hair. The researchers first twist-spun the nanotubes into high-strength, lightweight yarns. To make the yarns highly elastic, they introduced so much twist that the yarns coiled like an over-twisted rubber band.

In order to generate electricity, the yarns must be either submerged in or coated with an ionically conducting material, or electrolyte, which can be as simple as a mixture of ordinary table salt and water.

“Fundamentally, these yarns are supercapacitors,” said Dr. Na Li, a research scientist at the NanoTech Institute and co-lead author of the study. “In a normal capacitor, you use energy — like from a battery — to add charges to the capacitor. But in our case, when you insert the carbon nanotube yarn into an electrolyte bath, the yarns are charged by the electrolyte itself. No external battery, or voltage, is needed.”

When a harvester yarn is twisted or stretched, the volume of the carbon nanotube yarn decreases, bringing the electric charges on the yarn closer together and increasing their energy, Haines said. This increases the voltage associated with the charge stored in the yarn, enabling the harvesting of electricity.

Stretching the coiled twistron yarns 30 times a second generated 250 watts per kilogram of peak electrical power when normalized to the harvester’s weight, said Dr. Ray Baughman, director of the NanoTech Institute and a corresponding author of the study.

“Although numerous alternative harvesters have been investigated for many decades, no other reported harvester provides such high electrical power or energy output per cycle as ours for stretching rates between a few cycles per second and 600 cycles per second.”

Lab Tests Show Potential Applications

In the lab, the researchers showed that a twistron yarn weighing less than a housefly could power a small LED, which lit up each time the yarn was stretched.

To show that twistrons can harvest waste thermal energy from the environment, Li connected a twistron yarn to a polymer artificial muscle that contracts and expands when heated and cooled. The twistron harvester converted the mechanical energy generated by the polymer muscle to electrical energy.

“There is a lot of interest in using waste energy to power the Internet of Things, such as arrays of distributed sensors,” Li said. “Twistron technology might be exploited for such applications where changing batteries is impractical.”

The researchers also sewed twistron harvesters into a shirt. Normal breathing stretched the yarn and generated an electrical signal, demonstrating its potential as a self-powered respiration sensor.

“Electronic textiles are of major commercial interest, but how are you going to power them?” Baughman said. “Harvesting electrical energy from human motion is one strategy for eliminating the need for batteries. Our yarns produced over a hundred times higher electrical power per weight when stretched compared to other weavable fibers reported in the literature.”

Electricity from Ocean Waves

“In the lab we showed that our energy harvesters worked using a solution of table salt as the electrolyte,” said Baughman, who holds the Robert A. Welch Distinguished Chair in Chemistry in the School of Natural Sciences and Mathematics. “But we wanted to show that they would also work in ocean water, which is chemically more complex.”

In a proof-of-concept demonstration, co-lead author Dr. Shi Hyeong Kim, a postdoctoral researcher at the NanoTech Institute, waded into the frigid surf off the east coast of South Korea to deploy a coiled twistron in the sea. He attached a 10 centimeter-long yarn, weighing only 1 milligram (about the weight of a mosquito), between a balloon and a sinker that rested on the seabed.

Every time an ocean wave arrived, the balloon would rise, stretching the yarn up to 25 percent, thereby generating measured electricity.

Even though the investigators used very small amounts of twistron yarn in the current study, they have shown that harvester performance is scalable, both by increasing twistron diameter and by operating many yarns in parallel.

“If our twistron harvesters could be made less expensively, they might ultimately be able to harvest the enormous amount of energy available from ocean waves,” Baughman said. “However, at present these harvesters are most suitable for powering sensors and sensor communications. Based on demonstrated average power output, just 31 milligrams of carbon nanotube yarn harvester could provide the electrical energy needed to transmit a 2-kilobyte packet of data over a 100-meter radius every 10 seconds for the Internet of Things.”

Researchers from the UT Dallas Erik Jonsson School of Engineering and Computer Science and Lintec of America’s Nano-Science & Technology Center also participated in the study.

The investigators have filed a patent on the technology.

In the U.S., the research was funded by the Air Force, the Air Force Office of Scientific Research, NASA, the Office of Naval Research and the Robert A. Welch Foundation. In Korea, the research was supported by the Korea-U.S. Air Force Cooperation Program and the Creative Research Initiative Center for Self-powered Actuation of the National Research Foundation and the Ministry of Science.

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

Harvesting electrical energy from carbon nanotube yarn twist by Shi Hyeong Kim, Carter S. Haines, Na Li, Keon Jung Kim, Tae Jin Mun, Changsoon Choi, Jiangtao Di, Young Jun Oh, Juan Pablo Oviedo, Julia Bykova, Shaoli Fang, Nan Jiang, Zunfeng Liu, Run Wang, Prashant Kumar, Rui Qiao, Shashank Priya, Kyeongjae Cho, Moon Kim, Matthew Steven Lucas, Lawrence F. Drummy, Benji Maruyama, Dong Youn Lee, Xavier Lepró, Enlai Gao, Dawood Albarq, Raquel Ovalle-Robles, Seon Jeong Kim, Ray H. Baughman. Science 25 Aug 2017: Vol. 357, Issue 6353, pp. 773-778 DOI: 10.1126/science.aam8771

This paper is behind a paywall.

Dexter Johnson in an Aug. 25, 2017 posting on his Nanoclast blog (on the IEEE [Institute of Electrical and Electronics Engineers] website) delves further into the research,

“Basically what’s happening is when we stretch the yarn, we’re getting a change in capacitance of the yarn. It’s that change that allows us to get energy out,” explains Carter Haines, associate research professor at UT Dallas and co-lead author of the paper describing the research, in an interview with IEEE Spectrum.

This makes it similar in many ways to other types of energy harvesters. For instance, in other research, it has been demonstrated—with sheets of rubber with coated electrodes on both sides—that you can increase the capacitance of a material when you stretch it and it becomes thinner. As a result, if you have charge on that capacitor, you can change the voltage associated with that charge.

“We’re more or less exploiting the same effect but what we’re doing differently is we’re using an electric chemical cell to do this,” says Haines. “So we’re not changing double layer capacitance in normal parallel plate capacitors. But we’re actually changing the electric chemical capacitance on the surface of a super capacitor yarn.”

While there are other capacitance-based energy harvesters, those other devices require extremely high voltages to work because they’re using parallel plate capacitors, according to Haines.

Dexter asks good questions and his post is very informative.

For first time: high-dimensional quantum encryption performed in real world city conditions

Having congratulated China on the world’s first quantum communication network a few weeks ago (August 22, 2017 posting), this quantum encryption story seems timely. From an August 24, 2017 news item on phys.org,

For the first time, researchers have sent a quantum-secured message containing more than one bit of information per photon through the air above a city. The demonstration showed that it could one day be practical to use high-capacity, free-space quantum communication to create a highly secure link between ground-based networks and satellites, a requirement for creating a global quantum encryption network.

Quantum encryption uses photons to encode information in the form of quantum bits. In its simplest form, known as 2D encryption, each photon encodes one bit: either a one or a zero. Scientists have shown that a single photon can encode even more information—a concept known as high-dimensional quantum encryption—but until now this has never been demonstrated with free-space optical communication in real-world conditions. With eight bits necessary to encode just one letter, for example, packing more information into each photon would significantly speed up data transmission.

This looks like donuts on a stick to me,

For the first time, researchers have demonstrated sending messages in a secure manner using high dimensional quantum cryptography in realistic city conditions. Image Credit: SQO team, University of Ottawa.

An Aug. 24, 2017 Optical Society news release (also on EurekAlert), which originated the news item, describes the work done by a team in Ottawa, Canada, (Note: The ‘Congratulate China’ piece (August 22, 2017 posting) includes excerpts from an article that gave a brief survey of various national teams [including Canada] working on quantum communication networks; Links have been removed),

“Our work is the first to send messages in a secure manner using high-dimensional quantum encryption in realistic city conditions, including turbulence,” said research team lead, Ebrahim Karimi, University of Ottawa, Canada. “The secure, free-space communication scheme we demonstrated could potentially link Earth with satellites, securely connect places where it is too expensive to install fiber, or be used for encrypted communication with a moving object, such as an airplane.”

For the first time, researchers have demonstrated sending messages in a secure manner using high dimensional quantum cryptography in realistic city conditions. Image Credit: SQO team, University of Ottawa.

As detailed in Optica, The Optical Society’s journal for high impact research, the researchers demonstrated 4D quantum encryption over a free-space optical network spanning two buildings 0.3 kilometers apart at the University of Ottawa. This high-dimensional encryption scheme is referred to as 4D because each photon encodes two bits of information, which provides the four possibilities of 01, 10, 00 or 11.

In addition to sending more information per photon, high-dimensional quantum encryption can also tolerate more signal-obscuring noise before the transmission becomes unsecure. Noise can arise from turbulent air, failed electronics, detectors that don’t work properly and from attempts to intercept the data. “This higher noise threshold means that when 2D quantum encryption fails, you can try to implement 4D because it, in principle, is more secure and more noise resistant,” said Karimi.

Using light for encryption

Today, mathematical algorithms are used to encrypt text messages, banking transactions and health information. Intercepting these encrypted messages requires figuring out the exact algorithm used to encrypt a given piece of data, a feat that is difficult now but that is expected to become easier in the next decade or so as computers become more powerful.

Given the expectation that current algorithms may not work as well in the future, more attention is being given to stronger encryption techniques such as quantum key distribution, which uses properties of light particles known as quantum states to encode and send the key needed to decrypt encoded data.

Although wired and free-space quantum encryption has been deployed on some small, local networks, implementing it globally will require sending encrypted messages between ground-based stations and the satellite-based quantum communication networks that would link cities and countries. Horizontal tests through the air can be used to simulate sending signals to satellites, with about three horizontal kilometers being roughly equal to sending the signal through the Earth’s atmosphere to a satellite.

Before trying a three-kilometer test, the researchers wanted to see if it was even possible to perform 4D quantum encryption outside. This was thought to be so challenging that some other scientists in the field said that the experiment would not work. One of the primary problems faced during any free-space experiment is dealing with air turbulence, which distorts the optical signal.

Real-world testing

For the tests, the researchers brought their laboratory optical setups to two different rooftops and covered them with wooden boxes to provide some protection from the elements. After much trial and error, they successfully sent messages secured with 4D quantum encryption over their intracity link. The messages exhibited an error rate of 11 percent, below the 19 percent threshold needed to maintain a secure connection. They also compared 4D encryption with 2D, finding that, after error correction, they could transmit 1.6 times more information per photon with 4D quantum encryption, even with turbulence.

“After bringing equipment that would normally be used in a clean, isolated lab environment to a rooftop that is exposed to the elements and has no vibration isolation, it was very rewarding to see results showing that we could transmit secure data,” said Alicia Sit, an undergraduate student in Karimi’s lab.

As a next step, the researchers are planning to implement their scheme into a network that includes three links that are about 5.6 kilometers apart and that uses a technology known as adaptive optics to compensate for the turbulence. Eventually, they want to link this network to one that exists now in the city. “Our long-term goal is to implement a quantum communication network with multiple links but using more than four dimensions while trying to get around the turbulence,” said Sit.

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

High-dimensional intracity quantum cryptography with structured photons by Alicia Sit, Frédéric Bouchard, Robert Fickler, Jérémie Gagnon-Bischoff, Hugo Larocque, Khabat Heshami, Dominique Elser, Christian Peuntinger, Kevin Günthner, Bettina Heim, Christoph Marquardt, Gerd Leuchs, Robert W. Boyd, and Ebrahim Karimi. Optica Vol. 4, Issue 9, pp. 1006-1010 (2017) •https://doi.org/10.1364/OPTICA.4.001006

This is an open access paper.

“Innovation and its enemies” and “Science in Wonderland”: a commentary on two books and a few thoughts about fish (1 of 2)

There’s more than one way to approach the introduction of emerging technologies and sciences to ‘the public’. Calestous Juma in his 2016 book, ”Innovation and Its Enemies; Why People Resist New Technologies” takes a direct approach, as can be seen from the title while Melanie Keene’s 2015 book, “Science in Wonderland; The Scientific Fairy Tales of Victorian Britain” presents a more fantastical one. The fish in the headline tie together, thematically and tenuously, both books with a real life situation.

Innovation and Its Enemies

Calestous Juma, the author of “Innovation and Its Enemies” has impressive credentials,

  • Professor of the Practice of International Development,
  • Director of the Science, Technology, and Globalization Project at Harvard Kennedy School’s Better Science and International Affairs,
  • Founding Director of the African Centre for Technology Studies in Nairobi (Kenya),
  • Fellow of the Royal Society of London, and
  • Foreign Associate of the US National Academy of Sciences.

Even better, Juma is an excellent storyteller perhaps too much so for a book which presents a series of science and technology adoption case histories. (Given the range of historical time periods, geography, and the innovations themselves, he always has to stop short.)  The breadth is breathtaking and Juma manages with aplomb. For example, the innovations covered include: coffee, electricity, mechanical refrigeration, margarine, recorded sound, farm mechanization, and the printing press. He also covers two recently emerging technologies/innovations: transgenic crops and AquAdvantage salmon (more about the salmon later).

Juma provides an analysis of the various ways in which the public and institutions panic over innovation and goes on to offer solutions. He also injects a subtle note of humour from time to time. Here’s how Juma describes various countries’ response to risks and benefits,

In the United States products are safe until proven risky.

In France products are risky until proven safe.

In the United Kingdom products are risky even when proven safe.

In India products are safe when proven risky.

In Canada products are neither safe nor risky.

In Japan products are either safe or risky.

In Brazil products are both safe and risky.

In sub-Saharan Africa products are risky even if they do not exist. (pp. 4-5)

To Calestous Juma, thank you for mentioning Canada and for so aptly describing the quintessentially Canadian approach to not just products and innovation but to life itself, ‘we just don’t know; it could be this or it could be that or it could be something entirely different; we just don’t know and probably will never know.’.

One of the aspects that I most appreciated in this book was the broadening of the geographical perspective on innovation and emerging technologies to include the Middle East, China, and other regions/countries. As I’ve  noted in past postings, much of the discussion here in Canada is Eurocentric and/or UScentric. For example, the Council of Canadian Academies which conducts assessments of various science questions at the request of Canadian and regional governments routinely fills the ‘international’ slot(s) for their expert panels with academics from Europe (mostly Great Britain) and/or the US (or sometimes from Australia and/or New Zealand).

A good example of Juma’s expanded perspective on emerging technology is offered in Art Carden’s July 7, 2017 book review for Forbes.com (Note: A link has been removed),

In the chapter on coffee, Juma discusses how Middle Eastern and European societies resisted the beverage and, in particular, worked to shut down coffeehouses. Islamic jurists debated whether the kick from coffee is the same as intoxication and therefore something to be prohibited. Appealing to “the principle of original permissibility — al-ibaha, al-asliya — under which products were considered acceptable until expressly outlawed,” the fifteenth-century jurist Muhamad al-Dhabani issued several fatwas in support of keeping coffee legal.

This wasn’t the last word on coffee, which was banned and permitted and banned and permitted and banned and permitted in various places over time. Some rulers were skeptical of coffee because it was brewed and consumed in public coffeehouses — places where people could indulge in vices like gambling and tobacco use or perhaps exchange unorthodox ideas that were a threat to their power. It seems absurd in retrospect, but political control of all things coffee is no laughing matter.

The bans extended to Europe, where coffee threatened beverages like tea, wine, and beer. Predictably, and all in the name of public safety (of course!), European governments with the counsel of experts like brewers, vintners, and the British East India Tea Company regulated coffee importation and consumption. The list of affected interest groups is long, as is the list of meddlesome governments. Charles II of England would issue A Proclamation for the Suppression of Coffee Houses in 1675. Sweden prohibited coffee imports on five separate occasions between 1756 and 1817. In the late seventeenth century, France required that all coffee be imported through Marseilles so that it could be more easily monopolized and taxed.

Carden who teaches economics at Stanford University (California, US) focuses on issues of individual liberty and the rule of law with regards to innovation. I can appreciate the need to focus tightly when you have a limited word count but Carden could have a spared a few words to do more justice to Juma’s comprehensive and focused work.

At the risk of being accused of the fault I’ve attributed to Carden, I must mention the printing press chapter. While it was good to see a history of the printing press and attendant social upheavals noting its impact and discovery in regions other than Europe; it was shocking to someone educated in Canada to find Marshall McLuhan entirely ignored. Even now, I believe it’s virtually impossible to discuss the printing press as a technology, in Canada anyway, without mentioning our ‘communications god’ Marshall McLuhan and his 1962 book, The Gutenberg Galaxy.

Getting back to Juma’s book, his breadth and depth of knowledge, history, and geography is packaged in a relatively succinct 316 pp. As a writer, I admire his ability to distill the salient points and to devote chapters on two emerging technologies. It’s notoriously difficult to write about a currently emerging technology and Juma even managed to include a reference published only months (in early 2016) before “Innovation and its enemires” was published in July 2016.

Irrespective of Marshall McLuhan, I feel there are a few flaws. The book is intended for policy makers and industry (lobbyists, anyone?), he reaffirms (in academia, industry, government) a tendency toward a top-down approach to eliminating resistance. From Juma’s perspective, there needs to be better science education because no one who is properly informed should have any objections to an emerging/new technology. Juma never considers the possibility that resistance to a new technology might be a reasonable response. As well, while there was some mention of corporate resistance to new technologies which might threaten profits and revenue, Juma didn’t spare any comments about how corporate sovereignty and/or intellectual property issues are used to stifle innovation and quite successfully, by the way.

My concerns aside, testimony to the book’s worth is Carden’s review almost a year after publication. As well, Sir Peter Gluckman, Chief Science Advisor to the federal government of New Zealand, mentions Juma’s book in his January 16, 2017 talk, Science Advice in a Troubled World, for the Canadian Science Policy Centre.

Science in Wonderland

Melanie Keene’s 2015 book, “Science in Wonderland; The scientific fairy tales of Victorian Britain” provides an overview of the fashion for writing and reading scientific and mathematical fairy tales and, inadvertently, provides an overview of a public education programme,

A fairy queen (Victoria) sat on the throne of Victoria’s Britain, and she presided over a fairy tale age. The nineteenth century witnessed an unprecedented interest in fairies and in their tales, as they were used as an enchanted mirror in which to reflection question, and distort contemporary society.30  …  Fairies could be found disporting themselves thought the century on stage and page, in picture and print, from local haunts to global transports. There were myriad ways in which authors, painters, illustrators, advertisers, pantomime performers, singers, and more, capture this contemporary enthusiasm and engaged with fairyland and folklore; books, exhibitions, and images for children were one of the most significant. (p. 13)

… Anthropologists even made fairies the subject of scientific analysis, as ‘fairyology’ determined whether fairies should be part of natural history or part of supernatural lore; just on aspect of the revival of interest in folklore. Was there a tribe of fairy creatures somewhere out thee waiting to be discovered, across the globe of in the fossil record? Were fairies some kind of folks memory of any extinct race? (p. 14)

Scientific engagements with fairyland was widespread, and not just as an attractive means of packaging new facts for Victorian children.42 … The fairy tales of science had an important role to play in conceiving of new scientific disciplines; in celebrating new discoveries; in criticizing lofty ambitions; in inculcating habits of mind and body; in inspiring wonder; in positing future directions; and in the consideration of what the sciences were, and should be. A close reading of these tales provides a more sophisticated understanding of the content and status of the Victorian sciences; they give insights into what these new scientific disciplines were trying to do; how they were trying to cement a certain place in the world; and how they hoped to recruit and train new participants. (p. 18)

Segue: Should you be inclined to believe that society has moved on from fairies; it is possible to become a certified fairyologist (check out the fairyologist.com website).

“Science in Wonderland,” the title being a reference to Lewis Carroll’s Alice, was marketed quite differently than “innovation and its enemies”. There is no description of the author, as is the protocol in academic tomes, so here’s more from her webpage on the University of Cambridge (Homerton College) website,

Role:
Fellow, Graduate Tutor, Director of Studies for History and Philosophy of Science

Getting back to Keene’s book, she makes the point that the fairy tales were based on science and integrated scientific terminology in imaginative ways although some books with more success than other others. Topics ranged from paleontology, botany, and astronomy to microscopy and more.

This book provides a contrast to Juma’s direct focus on policy makers with its overview of the fairy narratives. Keene is primarily interested in children but her book casts a wider net  “… they give insights into what these new scientific disciplines were trying to do; how they were trying to cement a certain place in the world; and how they hoped to recruit and train new participants.”

In a sense both authors are describing how technologies are introduced and integrated into society. Keene provides a view that must seem almost halcyon for many contemporary innovation enthusiasts. As her topic area is children’s literature any resistance she notes is primarily literary invoking a debate about whether or not science was killing imagination and whimsy.

It would probably help if you’d taken a course in children’s literature of the 19th century before reading Keene’s book is written . Even if you haven’t taken a course, it’s still quite accessible, although I was left wondering about ‘Alice in Wonderland’ and its relationship to mathematics (see Melanie Bayley’s December 16, 2009 story for the New Scientist for a detailed rundown).

As an added bonus, fairy tale illustrations are included throughout the book along with a section of higher quality reproductions.

One of the unexpected delights of Keene’s book was the section on L. Frank Baum and his electricity fairy tale, “The Master Key.” She stretches to include “The Wizard of Oz,” which doesn’t really fit but I can’t see how she could avoid mentioning Baum’s most famous creation. There’s also a surprising (to me) focus on water, which when it’s paired with the interest in microscopy makes sense. Keene isn’t the only one who has to stretch to make things fit into her narrative and so from water I move onto fish bringing me back to one of Juma’s emerging technologies

Part 2: Fish and final comments

Vancouver’s (Canada) Fringe Festival (Sept. 7 – 17, 2017) and science

A lot of writers feel the need to comment when art and science are brought together in various artistic/scientific works. Here’s Janet Smith in a Sept. 6, 2017 article about science at Vancouver’s 2017 Fringe Festival for the Georgia Straight,

Science and art are often seen as opposites [emphasis mine], but they seem to be intermingling like never before at this year’s Vancouver Fringe Festival.

Experimental cancer treatments, zoology lectures, cryogenically frozen heads: they’re just some of the topics inspiring theatrical outings.

Smith is right and wrong. She’s right if your perspective ranges from the mid-20th century to the present day. “The Two Cultures” a 1959 lecture (and later a book) by C.P. Snow discusses a divide between two cultures: science and the humanities and he includes the arts in with the humanities. However, if you dive deeper into the past, you’ll find that humanities/arts and sciences have been more closely linked. Science sprang from ‘Natural Philosophy’ and faculties of arts and sciences are still found in universities.

Returning to the 2017 Vancouver Fringe Festival, I found some 17 shows that are science-inflected or using the mention of science as a marketing tool. Here they are:

Distractingly Sexy: Join real life scientist (and writer) Molly Mumford for an interactive, ultra-funny quite wild, pretty-durn-sexy history of how women in science have been f*S%ed over for centuries.

Thursday September 14, 2017 6:45 pm
Friday September 15, 2017 8:35 pm
Saturday Sept. 16, 2017 2:45 pm

Shadowlands: Cells in a petrii dish. A scientist. A ghost. A laboratory mouse. We are on a journey to see what can’t be seen. We are on a quest to find truth in the dark. …

No more showtimes

Interstellar Elder: Meet Kitt, age 96, fierce lone astronaut protecting the last of humankind. Images Ridley Scott’s ‘Aliens’ meets ‘Golden Girls’.

Wednesday September 13, 2017 5:00 pm
Friday September 16, 2017 6:40 pm
Saturday Sept. 16, 2017 12:30 pm
Sunday September 17, 2017 5:15 pm

Let Me Freeze Your Head: Why leave the futture to your children when you can have it for yourself? Attend our short sales presentation to learn how you preserve your brain to live again! This one-person show takes you on a deeply personal journey into the world of human cryonic preservation.

Wednesday September 13, 2017 9:45 pm
Friday September 15, 2017 5:00 pm
Saturday September 16, 2017 6:00 p.m

The Immaculate Big Bang: Sparked by the death of his father birth of his daughter; comedian Bill Santiago goes in search of answers and laughs at the border of science religion exploring the comic nature of the cosmic quest for understanding existence, life, and death (not necessarily in the order).

Tuesday September 12, 2017 9:30 pm
Friday September 15, 2017 10:25 pm
Sunday September 17, 2017 6:30 pm

Field Zoology, 101: From the untamed wilds of the Vancouver Landfill in the loading bay behind the Burger Kin, Field Zoologist Brad GooseBerry has seen it all. In this introductory course, he shares a lifetime of “knowledge” and “experience” teaching you to thrive and survive in the harrowing world of field zoology.

Wednesday September 13, 2017 9:20 pm
Friday September 15, 2017 5:10 pm
Saturday September 16, 2017 3:50 pm

Scientist Turned Comedian: “Lee, who got his PhD before realizing where his true talents lay, blends science talk (complete with PowerPoint presentations) with comedy. The hilarious result is like what would happen if you crossed your high-school chem teacher with George Carlin.”

Thursday September 14, 2017 6:40 pm
Saturday September 16, 2017 5:25 pm
Sunday September 17, 2017 2:45 pm

Acceleration: It’s 2012. The world’s top physicists are searching for the elusive Higgs boson particle and it’s been a year since Elise’s sister disappeared. Desperate to forget, Elise wraps herself up in the search for the Higgs. But what we’re looking for isn’t always what we find. A moving exploration of how we cope with a world that doesn’t make sense.

Wednesday September 13, 2017 10:15 pm
Friday September 15, 2017 8:30 pm
Saturday September 16, 2017 2:15 pm

Two series (five shows in total) about climate change: Generation Hot Waterborne

O Sandada 150M: 150 million years later … the world stops—and out of the basic elements sand and water, comes … life. Under the sun, Sandadians build beautiful castles, sing the National Sandthem, and glorify the Sandadian flag. Meanwhile under the stars, Wateries plan their attack. On the natural/industrial stage of the grassy knoll on Granville Island, two culture try to make peace. Fantastical Apocalyptic Puppets.

Twenty Feet Away: A site-specific theatrical adventure based on the bank of Vancouver’s False Creek. Two entrepreneurs daringly attempt to bottle themselves a new life while facing difficult ethical questions.

Brothers: Bonds are tested, sides taken, and loyalty is questioned. Two brothers come to terms with progress and preservation while on a fishing trip.

Wednesday September 13, 2017 6:00 pm
Thursday September 14, 2017 6:00 pm
Saturday September 16, 2017 6:00 pm

WYSPA: A group of youth stranded on an urchin-infested island guide the audience through a magic-infused ceremony and explore their world views that have turned them into survivors. Part documentary verbatim script drive by your aged 5-16.

Citlali: A fantastic tale about water by a Mexican poet: A mythological tale about the origins of Mexico and the journey of a demigoddess on a search for water.

Wednesday September 13, 2017 8:00 pm
Thursday September 14, 2017 8:00 pm
Saturday September 16, 2017 8:00 pm

Go, no go: .. the story of 13 barrier-breaking pilots who in 1961 petitioned NASA {US National Aeronautics and Space Administration] to be become the first femal astronatus. And it’s about why you don’t know their names. Welcome to the space race.

Tuesday September 12, 2017 1:30 pm

Kurt Vonnegut’s the Euphio Question: A new adaptation of Kurt Vonnegut’s 1951 short story. A young physicist discovers radio waves from outer space that mage anyone withing earshot completely and utterly euphoric. The Euphio Question asks audiences what the true cost of happiness is when it comes at the mere flick of a switch.

Tuesday September 12, 2017 6:00 pm
Thursday September 14, 2017 7:30 pm
Saturday September 16, 2017 6:30 pm
Sunday September 17, 2017 3:45 pm

Gutenberg: The Musical: In this whirlwind 90-minute musical comedy, Chris Adams and Erik Gow play over 30 characters in two-man spoof . A pair of aspiring playwrights perform a backers’ audition for this new project—a big, splashy musical about printing press inventor Johann [Johannes] Gutenberg. Too bad their musical is terrible.

Tuesday September 12, 2017 6:00 pm
Thursday September 14, 2017 10:45 pm
Friday September 15, 2017 6:00 pm
Saturday September 16, 2017 7:45 pm
Sunday September 17, 2017 2:00 pm

Brain machine: Award-wining monologist Andrew Bailey (The Adversary, Phantom Signal) proudly premieres: “Brain Machine.” Generations of scientists create the web to bring “harmony and understanding” to humanity. Chaos ensues. Bailey attempts to escape technology by moving to a cabin in the woods. While there he accidentally creates a viral video Chaos ensues.

Wednesday September 13, 2017 6:15 pm
Thursday September 14, 2017 8:00 pm
Friday September 15, 2017 9:45 pm
Sunday September 17, 2017 6:15 pm

Admittedly the science or technology element is quite tangential is some of these shows but I think it’s interesting that there’s any mention of science in 17 (16%) of 104 shows at this year’s Fringe. If memory serves, there have been man years where no mention of any kind has been made of science or technology, let alone 1q6% of the programme.

Women in science is a thread linking a number of the shows in this year’s Fringe Festival as Janet Smith notes in her Sept. 6, 2017 article (Women get their science on at the Vancouver Fringe Festival) for the Georgia Straight.

One final comment, I’ve done my best but I was copying the information out of the programme and have likely made errors, as well, schedules can change so do check the festival website or at the Fringe Festival’s updated schedule boards on Granville Island.

Art in the details: A look at the role of art in science—a Sept. 19, 2017 Café Scientifiqueevent in Vancouver, Canada

The Sept. 19, 2017 Café Scientifique event, “Art in the Details A look at the role of art in science,” in Vancouver seems to be part of a larger neuroscience and the arts program at the University of British Columbia. First, the details about the Sept. 13, 2017 event from the eventful Vancouver webpage,

Café Scientifique – Art in the Details: A look at the role of art in science

Art in the Details: A look at the role of art in science With so much beauty in the natural world, why does the misconception that art and science are vastly different persist? Join us for discussion and dessert as we hear from artists, researchers and academic professionals about the role art has played in scientific research – from the formative work of Santiago Ramon Y Cajal to modern imaging, and beyond – and how it might help shape scientific understanding in the future. September 19th, 2017  7:00 – 9:00 pm (doors open at 6:45pm)  TELUS World of Science [also known as Science World], 1455 Quebec St., Vancouver, BC V6A 3Z7 Free Admission [emphasis mine] Experts Dr Carol-Ann Courneya Associate Professor in the Department of Cellular and Physiological Science and Assistant Dean of Student Affairs, Faculty of Medicine, University of British Columbia   Dr Jason Snyder  Assistant Professor, Department of Psychology, University of British Columbia http://snyderlab.com/   Dr Steven Barnes Instructor and Assistant Head—Undergraduate Affairs, Department of Psychology, University of British Columbia http://stevenjbarnes.com/   Moderated By   Bruce Claggett Senior Managing Editor, NEWS 1130   This evening event is presented in collaboration with the Djavad Mowafaghian Centre for Brain Health. Please note: this is a private, adult-oriented event and TELUS World of Science will be closed during this discussion.

The Art in the Details event page on the Science World website provides a bit more information about the speakers (mostly in the form of links to their webpage),,

Experts

Dr Carol-Ann Courneya
Associate Professor in the Department of Cellular and Physiological Science and Assistant Dean of Student Affairs, Faculty of Medicine, University of British Columbia

Dr Jason Snyder 

Assistant Professor, Department of Psychology, University of British Columbi

Dr Steven Barnes

Instructor, Department of Psychology, University of British Columbia

Moderated By  

Bruce Claggett

Senior Managing Editor, NEWS 1130

Should you click though to obtain tickets from either the eventful Vancouver or Science World websites, you’ll find the event is sold out but perhaps the organizers will include a waitlist.

Even if you can’t get a ticket, there’s an exhibition of Santiago Ramon Y Cajal’s work (from the Djavad Mowafaghian Centre for Brain Health’s Beautiful brain’s webpage),

Drawings of Santiago Ramón y Cajal to be shown at UBC

Santiago Ramón y Cajal, injured Purkinje neurons, 1914, ink and pencil on paper. Courtesy of Instituto Cajal (CSIC).

Pictured: Santiago Ramón y Cajal, injured Purkinje neurons, 1914, ink and pencil on paper. Courtesy of Instituto Cajal (CSIC).

The Beautiful Brain is the first North American museum exhibition to present the extraordinary drawings of Santiago Ramón y Cajal (1852–1934), a Spanish pathologist, histologist and neuroscientist renowned for his discovery of neuron cells and their structure, for which he was awarded the Nobel Prize in Physiology and Medicine in 1906. Known as the father of modern neuroscience, Cajal was also an exceptional artist. He combined scientific and artistic skills to produce arresting drawings with extraordinary scientific and aesthetic qualities.

A century after their completion, Cajal’s drawings are still used in contemporary medical publications to illustrate important neuroscience principles, and continue to fascinate artists and visual art audiences. Eighty of Cajal’s drawings will be accompanied by a selection of contemporary neuroscience visualizations by international scientists. The Morris and Helen Belkin Art Gallery exhibition will also include early 20th century works that imaged consciousness, including drawings from Annie Besant’s Thought Forms (1901) and Charles Leadbeater’s The Chakras (1927), as well as abstract works by Lawren Harris that explored his interest in spirituality and mysticism.

After countless hours at the microscope, Cajal was able to perceive that the brain was made up of individual nerve cells or neurons rather than a tangled single web, which was only decisively proven by electron microscopy in the 1950s and is the basis of neuroscience today. His speculative drawings stemmed from an understanding of aesthetics in their compressed detail and lucid composition, as he laboured to clearly represent matter and processes that could not be seen.

In a special collaboration with the Morris and Helen Belkin Art Gallery and the VGH & UBC Hospital Foundation this project will encourage meaningful dialogue amongst artists, curators, scientists and scholars on concepts of neuroplasticity and perception. Public and Academic programs will address the emerging field of art and neuroscience and engage interdisciplinary research of scholars from the sciences and humanities alike.

“This is an incredible opportunity for the neuroscience and visual arts communities at the University and Vancouver,” says Dr. Brian MacVicar, who has been working diligently with Director Scott Watson at the Morris and Helen Belkin Art Gallery and with his colleagues at the University of Minnesota for the past few years to bring this exhibition to campus. “Without Cajal’s impressive body of work, our understanding of the anatomy of the brain would not be so well-formed; Cajal’s legacy has been of critical importance to neuroscience teaching and research over the past century.”

A book published by Abrams accompanies the exhibition, containing full colour reproductions of all 80 of the exhibition drawings, commentary on each of the works and essays on Cajal’s life and scientific contributions, artistic roots and achievements and contemporary neuroscience imaging techniques.

Cajal’s work will be on display at the Morris and Helen Belkin Art Gallery from September 5 to December 3, 2017.

Join the UBC arts and neuroscience communities for a free symposium and dance performance celebrating The Beautiful Brain at UBC on September 7. [link removed]

The Beautiful Brain: The Drawings of Santiago Ramón y Cajal was developed by the Frederick R. Weisman Art Museum, University of Minnesota with the Instituto Cajal. The exhibition at the Morris and Helen Belkin Art Gallery, University British Columbia is presented in partnership with the Djavad Mowafaghian Centre for Brain Health with support from the VGH & UBC Hospital Foundation. We gratefully acknowledge the generous support of the Canada Council for the Arts, the British Columbia Arts Council and Belkin Curator’s Forum members.

The Morris and Helen Belkin Art Gallery’s Beautiful Brain webpage has a listing of upcoming events associated with the exhibition as well as instructions on how to get there (if you click on About),

SEMINAR & READING GROUP: Plasticity at SFU Vancouver and 221A: Wednesdays, October 4, 18, November 1, 15 and 21 at 7 pm

CONVERSATION with Anthony Phillips and Timothy Taylor: Wednesday, October 11, 2017 at 7 pm

LECTURE with Catherine Malabou at the Liu Institute: Thursday, November 23 at 6 pm

CONCERT with UBC Contemporary Players: Friday, December 1 at 2 pm

Cajal was also an exceptional artist and studied as a teenager at the Academy of Arts in Huesca, Spain. He combined scientific and artistic skills to produce arresting drawings with extraordinary scientific and aesthetic qualities. A century after their completion, his drawings are still used in contemporary medical publications to illustrate important neuroscience principles, and continue to fascinate artists and visual art audiences. Eighty of Cajal’s drawings are accompanied by a selection of contemporary neuroscience visualizations by international scientists.

Organizationally, this seems a little higgledy piggledy with the Cafe Scientifique event found on some sites, the Belkin Gallery events found on one site, and no single listing of everything on any one site for the Beautiful Brain. Please let me know if you find something I’ve missed.