A July 12, 2024 news item on ScienceDaily describes a fascinating computer program developed by scientists at Trinity College Dublin,
Scientists from Trinity College Dublin have created a computer program that “paints” the structure of molecules in the style of famous Dutch artist, Piet Mondrian, whose beautiful artworks will be instantly recognizable to many.
Mondrian’s style, whereby he used blocks of primary colors separated by lines of various widths on a white background, has been extensively copied or used as an inspiration in modern culture. But his deceptively simple artworks have also fascinated scientists for decades, finding niche applications in mathematics and statistics.
And now, researchers from the School of Chemistry are opening eyes and minds to the beauty of molecular structure, as well as posing new questions about the form and function of the molecules themselves.
Their computer program, which can be accessed at http://www.sengegroup.eu/nsd, produces a Mondrianesque plot of any molecule. It does so by following an artistic algorithm that marries the laws of chemistry that describe the 3D structure of a molecule based on its components with the 2D style of one of the most influential painters of the Modern era.
For the scientist, it helps to rapidly assess and demonstrate molecular symmetry, allowing for deeper insights than would emerge from traditional representations. And for the artist, it provides a visually pleasing image of contrasting interpretations of symmetry, hopefully providing inspiration for the incorporation of scientific ideas into work.
Mathias O Senge, Professor of Organic Chemistry in Trinity and Hans Fischer Senior Fellow at the Institute for Advanced Study of TU Munich [Technische Universität München or Technical University of Munich] is the senior author of a just-published article in the leading international journal, Angewandte Chemie, in which this creation is shared with the world. He said:
“For some years we have been working on this project, initially for fun, to output the structure of a molecule in an artistically pleasing manner as a painting in the style of Mondrian. The ‘paintings’ obtained are unique for each molecule and juxtapose what Mondrian and others aimed to do with the De Stijl artistic movement.
“Symmetry and shape are essential aspects of molecular structure and how we interpret molecules and their properties, but very often relationships between chemical structure and derived values are obscured. Taking our inspiration from Mondrian’s Compositions, we have depicted the symmetry information encoded within 3D data as blocks of colour, to show clearly how chemical arguments may contribute to symmetry.”
Christopher Kingsbury, postdoctoral researcher in TBSI, who conceived the project, is first author of the journal article. He said: “In chemistry, it is useful to have a universal way of displaying molecular structure, so as to help ‘blueprint’ how a molecule is likely to behave in different environments and how it may react and change shape when in the presence of other molecules. But a certain amount of nuance is inevitably lost.
“This concept of increasing abstraction by removing minor details and trying to present a general form is mimicked by the early work of Mondrian and in some senses this is what scientists intuitively do when reducing complex phenomena to a ‘simpler truth’. Thanks to our new approach very complex science is fed through an artistic lens, which might make it more accessible to a wider range of people.”
In recent years Professor Senge and his team have greatly enhanced our understanding of porphyrins, a unique class of intensely coloured pigments – also known as the “colours of life”. In one piece of work they created a suite of new biological sensors by chemically re-engineering these pigments to act like tiny Venus flytraps and grab specific molecules, such as pollutants. And now the new direction, in which science and art collide, may further develop our understanding of how porphyrins work.
“Great art gives us a new perspective on the world,” added Prof. Senge. “As a pastiche, this art may allow us to look at familiar molecules, such as porphyrins, in a new light, and help us to better understand how their shape and properties are intertwined. More generally, we believe that contemporary initiatives in ‘Art and Science’ require a transformative break of discipline boundaries and merger to ‘ArtScience’. There is a subtle interplay between science and art and mixing of both aspects in our respective fields of endeavour and this should be a focus for future developments in both areas.”
An April 15, 2024 news item on phys.org announces research into how an Arab scientist’s studies into optics established the basis for modern day physics,
Scientists from the University of Sharjah [United Arab Emirates] and the Warburg Institute [University of London, UK] are poring over the writings of an 11th-century Arab-Muslim polymath to demonstrate their impact on the development of optical sciences and how they have fundamentally transformed the history of physics from the Middle Ages up to modern times in Europe.
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A May 6, 2024 University of Sharjah press release on EurekAlert, which originated the news item, delves further into the topic, Note 1: Why there’s such a large discrepancy in the publication dates for the press release is a mystery to me; Note 2: Links have been removed,
Their research focuses on the legacy of al-Ḥasan Ibn al-Haytham known in Latin as “Alhazen” and particularly his most influential work titled Book of Optics, reputed in Arabic as Kitab al-Manazir and first circulated in Europe via its Latin translation dubbed ‘Perspectiva’. Ibn al-Haytham was born in the southern Iraqi city of Basra in 965 during the Abbasid Caliphate.
The divisions IV-V of this authoritative book have been recently translated into English from Arabic and published by the Warburg Institute under the title “The Optics of Ibn al-Haytham, Books IV–V: On Reflection and Images Seen by Reflection”. Having already rendered divisions I-III into English, the Warburg Institute is bringing together a wide-ranging network of scientists “for a collaborative humanities-science investigation of [Ibn] al-Haytham and the questions his work provokes.“
The role of Alhazen [Ibn al-Haytham] in these processes is simultaneously well-known, but limited; only half of his scientific works have English translation and a quarter are not yet edited.”
Introducing the new translation, the Warburg Institute describes Ibn al-Haytham as “perhaps the greatest mathematician and physicist of the medieval Arabic/Islamic world. His reputation is based not only on the vast amount of material he was able to process, but also on his rigorous scientific methodology.
“He (Ibn al-Haytham) deals with both the mathematics of rays of light and the physical aspects of the eye in seven comprehensive books. His reinstatement of the entire science of optics sets the scene for the whole of the subsequent development of the subject … influencing figures such as William of Ockham, [Johannes] Kepler, [René] Descartes, and Christaan Huygens.”
Professor Nader El-Bizri of Sharjah University’s College of Arts, Humanities, and Social Sciences has just published an academic review of the Warburg Institute’s translation of Ibn al-Haytham. The article, printed in the International Journal of the Classical Tradition, highlights the strong influence the Arab-Muslim optical scientist has exerted over the ages up to the present day.
Ibn al-Haytham’s Book of Optics, Prof. El-Bizri writes, “constituted a monumental foundational opus in the history of science and the visual arts from the Middle Ages to the early modern period in the European milieu and the Islamicate context … The reception of Ibn al-Haytham’s Optics in the European milieu took place from the High Middle Ages via Gerard of Cremona’s Toledo circle in terms of its Latinate translations, and subsequent influence on Franciscan, Dominican, and Jesuit opticians across Europe.“
It influenced François d’Aguilon’s Opticorum libri sex within the Antwerp Jesuit mathematical school and had a direct impact on Johannes Hevelius’s Selenographia. The Optics was also consulted by Girard Desargues, René Descartes, Johannes Kepler and Christaan Huygens.”
Prof. El-Bizri works closely with the Warburg Institute assisting its attempts to reintroduce Ibn al-Haytham to the west. “A remarkable thinker, not only did Ibn al-Haytham revolutionize optical thought by mathematising its study, [but] his thinking also went on to have similar revolutionary effects in medieval Europe.”
The Warburg Institute is investing in rendering the writings of Ibn al-Haytham on optics into English, which Prof. El-Bizri describes as “voluminous”. “Ibn al-Haytham’s Book of Optics indicates with evidence the impact of Arabic sciences and philosophy on the history of science and the architectural and visual arts in Europe, as well as demonstrating how science and the arts influence each other in the manner the studies of optics in their mathematized physics inspired the invention of projective geometric constructions of perspective as a novel Renaissance method of painting and architectural design.”
Prof. El-Bizri adds “The impact of this book is fundamental not only in the history of science from the High Middle Ages till the early-modern period in Europe, but it was also foundational for architecture and the visual arts in the Italian Renaissance and up till the late Baroque era. Moreover, it has further significance in modern conceptions of the mathematization of physics, the reliance on experimentation in science, and the philosophical analysis of perception.”
Asked about the importance of translating Ibn al-Haytham into English despite the lapse of nearly 1000 years, Prof. El-Bizri says the Arab-Muslim scientist’s theories and methodologies, specifically those dealing with optics are still considered “seminal” in the literature. Ibn al-Haytham has had a “foundational impact on the history of science and the arts in Europe.”
The influence of Ibn al-Haytham’s writings in the European milieu, according to Prof. El-Bizri, cannot be overlooked. The Arab-Muslim scientist had “a notable effect on Biagio Pelacani da Parma’s Questiones super perspectiva communi, Leon Battista Alberti’s De pictura, Lorenzo Ghiberti’s Commentarii, culminating in the first printed Latin version in the publication of Friedrich Risner’s Opticae thesaurus in the sixteenth century.“
Then, in the seventeenth century, it influenced François d’Aguilon’s Opticorum libri sex within the Antwerp Jesuit mathematical school and had a direct impact on Johannes Hevelius’s Selenographia.”.
In the Book of Optics, notes Prof. El-Bizri, Ibn al-Haytham establishes an “inventive and precise scientific experimental method (al-iʿtibār al-muḥarrar) with its controlled verificative repeated testing, as framed by isomorphic compositions between physics and mathematics.”
He adds that Ibn al-Haytham in his Optics “aims at elucidating the nature of visual perception through studies on the anatomy and physiology of the eyes, the optic nerves and the frontal part of the brain, along with cognitive psychology and the analysis of psychosomatic ocular motor kinaesthetic acts”
Here’s a link to and a citation for the paper, Note: This is one of the more unusual citation I have hrere,
The Optics of Ibn al-Haytham, Books IV–V: On Reflection and Image by N. El-Bizri. Seen by Reflection, translated from the Arabic by Abdelhamid I. Sabra and prepared for publication by Jan P. Hogendijk (Warburg Institute Studies and Texts, 8), London: University of London Press in association with the Warburg Institute, 2023, pp. xiv+343, ISBN 978-1908590589, £90. Int class trad 31, 116–119 (2024). https://doi.org/10.1007/s12138-024-00654-4 Published: 20 February 2024 Issue Date: March 2024
The Warburg Institute is one of the world’s leading centres for the study of art and culture. Its collections, courses and programmes are dedicated to the study of global cultural history and the role of images in society. Founded in Hamburg at the turn of the twentieth century by historian Aby Warburg (1866-1929), the Institute was established to trace the roots of the Renaissance in ancient civilisations and ended up changing the way we see the world around us.
The Warburg Institute owes its mission—and its very existence—to the open movement of people, collections and ideas. Sent into exile when the Nazis came to power, the Institute was transferred to England in 1933 and became part of the University of London in 1944. It has served, during a turbulent century, as a creative crucible for scholars, curators, artists and all those whose work sits outside traditional academic structures.
The Warburg’s unique Library, Archive and Photographic Collection form a holistic, associative engine for exploring the histories of the arts and sciences—linking the textual and the visual, the intellectual and the social, the scientific and the magical. Following an extensive renovation of the Institute’s building in Bloomsbury, new spaces for exhibitions and events have restored the Institute’s original emphasis on discovery, display and debate and are bringing its holdings and programmes to new audiences.
Building on Aby Warburg’s belief that the memory of the past activates the present, the Warburg examines the movement of culture across barriers – of time, space and discipline -to inspire, inform and connect.
It seems that physicists are having a moment in the pop culture scene and they are excited about two television series (Fallout and 3 Body Problem) televised earlier this year in US/Canada.
The world ends on Oct. 23, 2077, in a series of radioactive explosions—at least in the world of “Fallout,” a post-apocalyptic video game series that has now been adapted into a blockbuster TV show on Amazon’s Prime Video.
The literal fallout that ensues creates a post-apocalyptic United States that is full of mutated monstrosities, irradiated humans called ghouls and hard scrabble survivors who are caught in the middle of it all. It’s the material of classic Atomic Age sci-fi, the kind of pulp stories “Fallout” draws inspiration from for its retro-futuristic version of America.
But there is more science in this science fiction story than you might think, according to Pran Nath, Matthews distinguished university professor of physics at Northeastern University.
In the opening moments of “Fallout,” which debuted on April 10 [2024], Los Angeles is hit with a series of nuclear bombs. Although it takes place in a clearly fictional version of La La Land –– the robots and glistening, futuristic skyscrapers in the distance are dead giveaways –– the nuclear explosions themselves are shockingly realistic.
Nath says that when a nuclear device is dropped there are three stages.
“When the nuclear blast occurs, because of the chain reaction, in a very short period of time, a lot of energy and radiation is emitted,” Nath says. “In the first instance, a huge flash occurs, which is the nuclear reaction producing gamma rays. If you are exposed to it, people, for example, in Hiroshima were essentially evaporated, leaving shadows.”
Depending on how far someone is from the blast, even those who are partially protected will have their body rapidly heat up to 50 degrees Celsius, or 122 degrees Fahrenheit, causing severe burns. The scalded skin of the ghouls in “Fallout” are not entirely unheard of (although their centuries-long lifespan stretches things a bit).
The second phase is a shockwave and heat blast –– what Nath calls a “fireball.” The shockwave in the first scene of “Fallout” quickly spreads from the blast, but Nath says it would probably happen even faster and less cinematically. It would travel around the speed of sound, around 760 miles per hour.
The shockwave also has a huge amount of pressure, “so huge … that it can collapse concrete buildings.” It’s followed by a “fireball” that would burn every building in the blast area with an intense heatwave.
“The blast area is defined as the area where the shockwaves and the fireball are the most intense,” Nath says. “For Hiroshima, that was between 1 and 2 miles. Basically, everything is destroyed in that blast area.”
The third phase of the nuclear blast is the fallout, which lasts for much longer and has even wider ranging impacts than the blast and shockwave. The nuclear blast creates a mushroom cloud, which can reach as high as 10 miles into the atmosphere. Carried by the wind, the cloud spreads radioactivity far outside the blast area.
“In a nuclear blast, up to 100 different radioactive elements are produced,” Nath says. “These radioactive elements have lifetimes which could be a few seconds, and they could be up to millions of years. … It causes pollution and damage to the body and injuries over a longer period, causing cancer and leukemia, things like this.”
A key part of the world of “Fallout” is the Vaults, massive underground bunkers the size of small towns that the luckiest of people get to retreat into when the world ends. The Vaults are several steps above most real-world fallout shelters, but Nath says that kind of protection would be necessary if you wanted to stay safe from the kind of radiation released by nuclear weapons, particularly gamma rays that can penetrate several feet of concrete.
“If you are further away and you keep inside and behind concrete, then you can avoid both the initial flash of the nuclear blast and also could probably withstand the shockwaves and the heatwave that follows, so the survivability becomes larger,” Nath says.
But what about all the radioactive mutants wandering around the post-apocalyptic wasteland?
It might seem like the colossal, monstrous mutant salamanders and giant cockroaches of “Fallout” are a science fiction fabrication. But there is a real-world basis for this, Nath says.
“There are various kinds of abnormalities that occur [with radiation,]” Nath says. “They can also be genetic. Radiation can create mutations, which are similar to spontaneous mutation, in animals and humans. In Chernobyl, for example, they are discovering animals which are mutated.”
In the Chernobyl Exclusion Zone, the genetics of wild dogs have been radically altered. Scientists hypothesize that thewolves near Chernobyl may have developed to be more resistant to radiation, which could make them “cancer resistant,” or at least less impacted by cancer. And frogs have adapted to have more melanin in their bodies, a form of protection against radiation, turning them black.
“Fallout” takes the horrifying reality of nuclear war and spins a darkly comic sci-fi yarn, but Nath says it’s important to remember how devastating these real-world forces are.
It’s estimated that as many as 146,000 people in Hiroshima and 80,000 people in Nagasaki were killed by the effects of the bombs dropped by the U.S. Today’s nuclear weapons are so much more powerful that there is very little understanding of the impact these weapons could have. Nath says the fallout could even exacerbate global warming.
“Thermonuclear war would be a global problem,” Nath says.
Although “Fallout” is a piece of science fiction, the reality of its world-ending scenario is terrifyingly real, says Pran Nath, Matthews distinguished university professor of physics at Northeastern University. Photo by Adam Glanzman/Northeastern University
Kudos to the photographer!
3 Body Problem (television series)
This one seems to have a lit a fire in the breasts of physicists everywhere. I have a number of written pieces and a video about this this show, which is based on a book by Liu Cixn. (You can find out more about Cixin and his work in his Wikipedia entry.)
“3 Body Problem,” Netflix’s new big-budget adaptation of Liu Cixin’s book series helmed by the creators behind “Game of Thrones,” puts the science in science fiction.
The series focuses on scientists as they attempt to solve a mystery that spans decades, continents and even galaxies. That means “3 Body Problem” throws some pretty complicated quantum mechanics and astrophysics concepts at the audience as it, sometimes literally, tries to bring these ideas down to earth.
However, at the core of the series is the three-body problem, a question that has stumped scientists for centuries.
What exactly is the three-body problem, and why is it still unsolvable? Jonathan Blazek, an assistant professor of physics at Northeastern University, explains that systems with two objects exerting gravitational force on one another, whether they’re particles or stars and planets, are predictable. Scientists have been able to solve this two-body problem and predict the orbits of objects since the days of Isaac Newton. But as soon as a third body enters the mix, the whole system gets thrown into chaos.
“The three-body problem is the statement that if you have three bodies gravitating toward each other under Newton’s law of gravitation, there is no general closed-form solution for that situation,” Blazek says. “Little differences get amplified and can lead to wildly unpredictable behavior in the future.”
In “3 Body Problem,” like in Cixin’s book, this is a reality for aliens that live in a solar system with three suns. Since all three stars are exerting gravitational forces on each other, they end up throwing the solar system into chaos as they fling each other back and forth. For the Trisolarans, the name for these aliens, it means that when a sun is jettisoned far away, their planet freezes, and when a sun is thrown extremely close to their planet, it gets torched. Worse, because of the three-body problem, these movements are completely unpredictable.
For centuries, scientists have pondered the question of how to determine a stable starting point for three gravitational bodies that would result in predictable orbits. There is still no generalizable solution that can be taken out of theory and modeled in reality, although recently scientists have started to find some potentially creative solutions, including with models based on the movements of drunk people.
“If you want to [predict] what the solar system’s going to do, we can put all the planets and as many asteroids as we know into a computer code and basically say we’re going to calculate the force between everything and move everything forward a little bit,” Blazek says. “This works, but to the extent that you’re making some approximations … all of these things will eventually break down and your prediction is going to become inaccurate.”
Blazek says the three-body problem has captivated scientific minds because it’s a seemingly simple problem. Most high school physics students learn Newton’s law of gravity and can reasonably calculate and predict the movement of two bodies.
Three-body systems, and more than three-body systems, also show up throughout the universe, so the question is incredibly relevant. Look no further than our solar system.
The relationship between the sun, Earth and our moon is a three-body system. But Blazek says since the sun exerts a stronger gravitational force on Earth and Earth does the same on the moon, it creates a pair of two-body systems with stable, predictable orbits –– for now.
Blazek says that although our solar system appears stable, there’s no guarantee that it will stay that way in the far future because there are still multi-body systems at play. Small changes like an asteroid hitting one of Jupiter’s moons and altering its orbit ever so slightly could eventually spiral into larger changes.
That doesn’t mean humanity will face a crisis like the one the Trisolarans face in “3 Body Problem.” These changes happen extremely slowly, but Blazek says it’s another reminder of why these concepts are interesting and important to think about in both science and science fiction.
“I don’t think anything is going to happen on the time scale of our week or even probably our species –– we have bigger problems than the instability of orbits in our solar system,” Blazek says. “But, that said, if you think about billions of years, during that period we don’t know that the orbits will stay as they currently are. There’s a good chance there will be some instability that changes how things look in the solar system.”
An April 12, 2024 news item on phys.org covers some of the same ground, Note: A link has been removed.
The science fiction television series 3 Body Problem, the latest from the creators of HBO’s Game of Thrones, has become the most watched show on Netflix since its debut last month. Based on the bestselling book trilogy Remembrance of Earth’s Past by Chinese computer engineer and author Cixin Liu, 3 Body Problem introduces viewers to advanced concepts in physics in service to a suspenseful story involving investigative police work, international intrigue, and the looming threat of an extraterrestrial invasion.
Yet how closely does the story of 3 Body Problem adhere to the science that it’s based on? The very name of the show comes from the three-body problem, a mathematical problem in physics long considered to be unsolvable.
Virginia Tech physicist Djordje Minic says, “The three-body problem is a very famous problem in classical and celestial mechanics, which goes back to Isaac Newton. It involves three celestial bodies interacting via the gravitational force—that is, Newton’s law of gravity. Unlike mathematical predictions of the motions of two-body systems, such as Earth-moon or Earth-sun, the three-body problem does not have an analytic solution.”
“At the end of the 19th century, the great French mathematician Henri Poincaré’s work on the three-body problem gave birth to what is known as chaos theory and the concept of the ‘butterfly effect.'”
Both the novels and the Netflix show contain a visualization of the three-body problem in action: a solar system made up of three suns in erratic orbit around one another. Virginia Tech aerospace engineer and mathematics expert Shane Ross discussed liberties the story takes with the science that informs it.
“There are no known configurations of three massive stars that could maintain an erratic orbit,” Ross said. “There was a big breakthrough about 20 years ago when a figure eight solution of the three-body problem was discovered, in which three equal-sized stars chase each other around on a figure eight-shaped course. In fact, Cixin Liu makes reference to this in his books. Building on that development, other mathematicians found other solutions, but in each case the movement is not chaotic.”
Ross elaborated, “It’s even more unlikely that a fourth body, a planet, would be in orbit around this system of three stars, however erratically — it would either collide with one or be ejected from the system. The situation in the book would therefore be a solution of the ‘four-body problem,’ which I guess didn’t have quite the right ring to use as a title.
“Furthermore, a stable climate is unlikely even on an Earth-like planet. At last count, there are at least a hundred independent factors that are required to create an Earth-like planet that supports life as we know it,” Ross said. “We have been fortunate to have had about 10,000 years of the most stable climate in Earth’s history, which makes us think climate stability is the norm, when in fact, it’s the exception. It’s likely no coincidence that this has corresponded with the rise of advanced human civilization.”
About Ross A professor of Aerospace and Ocean Engineering at Virginia Tech, Shane Ross directs the Ross Dynamics Lab, which specializes in mathematical modeling, simulation, visualization, and experiments involving oceanic and atmospheric patterns, aerodynamic gliding, orbital mechanics, and many other disciplines. He has made fundamental contributions toward finding chaotic solutions to the three-body problem. Read his bio …
About Minic Djordje Minic teaches physics at Virginia Tech. A specialist in string theory and quantum gravity, he has collaborated on award-winning research related to dark matter and dark energy. His most recent investigation involves the possibility that in the context of quantum gravity the geometry of quantum theory might be dynamical in analogy with the dynamical nature of spacetime geometry in Einstein’s theory of gravity. View his full bio …
For the last ‘3 Body Problem’ essay, there’s this April 5, 2023 article by Tara Bitran and Phillipe Thao for Netflix.com featuring comments from a physicist concerning a number of science questions,, Note: Links have been removed,
If you’ve raced through 3 Body Problem, the new series from Game of Thrones creators David Benioff and D.B. Weiss and True Blood writer Alexander Woo, chances are you want to know more about everything from Sophons and nanofibers to what actually constitutes a three-body problem. After all, even the show’s scientists are stumped when they witness their well-known theories unravel at the seams.
But for physicists like 3 Body Problem’s Jin (Jess Hong) and real-life astrophysicist Dr. Becky Smethurst (who researches how supermassive black holes grow at the University of Oxford and explains how scientific phenomena work in viral videos), answering the universe’s questions is a problem they’re delighted to solve. In fact, it’s part of the fun. “I feel like scientists look at the term ‘problem’ more excitedly than anybody else does,” Smethurst tells Tudum. “Every scientist’s dream is to be told that they got it wrong before and here’s some new data that you can now work on that shows you something different where you can learn something new.”
The eight-episode series, based on writer Cixin Liu’s internationally celebrated Remembrance of Earth’s Past trilogy, repeatedly defies human science standards and forces the characters to head back to the drawing board to figure out how to face humanity’s greatest threat. Taking us on a mind-boggling journey that spans continents and timelines, the story begins in ’60s China, when a young woman makes a fateful decision that reverberates across space and time into the present day. With humanity’s future in danger, a group of tight-knit scientists, dubbed the Oxford Five, must work against time to save the world from catastrophic consequences.
Dr. Matt Kenzie, associate professor of physics at University of Cambridge and 3 Body Problem’s science advisor, sits down with Tudum to dive into the science behind the series. So if you can’t stop thinking about stars blinking and chaotic eras, keep reading for all the answers to your burning scientific questions. Education time!
What is a Cherenkov tank?
In Episode 1, the Oxford Five’s former college professor, Dr. Vera Ye (Vedette Lim), walks out onto a platform at the top of a large tank and plunges to her death in a shallow pool of water below. If you were wondering what that huge tank was, it’s called a particle detector (sometimes also known as a Cherenkov tank). It’s used to observe, measure, and identify particles, including, in this case, neutrinos, a common particle that comes largely from the sun. “Part of the reason that they’re kind of interesting is that we don’t really understand much about them, and we suspect that they could be giving us clues to other types of physics in the universe that we don’t yet understand,” Dr. Kenzie told Netflix.
When a neutrino interacts with the water molecules stored inside the tank, it sets off a series of photomultiplier tubes — the little circles that line the tank Vera jumps into. Because Vera’s experiment is shut down and the water is reduced to a shallow level, the fall ends up killing her.
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What are nanofibers?
In the show, Auggie’s a trailblazer in nanofiber technology. She runs a company that designs self-assembling synthetic polymer nanofibers and hopes to use her latest innovation to solve world problems, like poverty and disease. But what are nanofibers and how do they work? Dr. Kenzie describes nanofiber technology as “any material with a width of nanometers” — in other words, one millionth of a millimeter in thickness. Nanofibers can be constructed out of graphene (a one-atom thick layer of carbon) and are often very strong. “They can be very flexible,” he adds. “They tend to be very good conductors of both heat and electricity.”
Is nanofiber technology real, and can it actually cut through human flesh?
Nanofiber technology does exist, although Dr. Kenzie says it’s curated and grown in labs under very specific conditions. “One of the difficulties is how you hold them in place — the scaffolding it’s called,” he adds. “You have to design molecules which hold these things whilst you’re trying to build them.”
After being tested on a synthetic diamond cube in Episode 2, we see the real horrors of nanofiber technology when it’s used to slice through human bodies in Episode 5. Although the nanofiber technology that exists today is not as mass produced as Auggie’s — due to the cost of producing and containing it — Dr. Kenzie says it’s still strong enough to slice through almost anything.
What can nanofiber technology be used for?
According to Dr. Kenzie, the nanofiber technology being developed today can be used in several ways within the manufacturing and construction industries. “If you wanted a machine that could do some precision cutting, then maybe [nanofiber] would be good,” he says. “I know they’re also tested in the safety of the munitions world. If you need to bulletproof a room or bulletproof a vest, they’re incredibly light and they’re incredibly strong.” He also adds that nanofiber technology is viewed as a material of the future, which can be used for water filtration — just as we see Auggie use it in the season finale.
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The Bitran and Thao piece includes another description of the 3 Body Problem but it’s the first I’ve seen that describes some of the other science.
Also mentioned in one of the excerpts in this posting is The Science and Entertainment Exchange (also known as The Science & Entertainment Exchange or Science & Entertainment Exchange) according to its Wikipedia entry, Note: Links have been removed,
The Science & Entertainment Exchange[1] is a program run and developed by the United States National Academy of Sciences (NAS) to increase public awareness, knowledge, and understanding of science and advanced science technology through its representation in television, film, and other media. It serves as a pro-science movement with the main goal of re-cultivating how science and scientists truly are in order to rid the public of false perceptions on these topics. The Exchange provides entertainment industry professionals with access to credible and knowledgeable scientists and engineers who help to encourage and create effective representations of science and scientists in the media, whether it be on television, in films, plays, etc. The Exchange also helps the science community understand the needs and requirements of the entertainment industry, while making sure science is conveyed in a correct and positive manner to the target audience.
Officially launched in November 2008, the Exchange can be thought of as a partnership between NAS and Hollywood, as it arranges direct consultations between scientists and entertainment professionals who develop science-themed content. This collaboration allows for industry professionals to accurately portray the science that they wish to capture and include in their media production. It also provides scientists and science organizations with the opportunity to communicate effectively with a large audience that may otherwise be hard to reach such as through innovative physics outreach. It also provides a variety of other services, including scheduling briefings, brainstorming sessions, screenings, and salons. The Exchange is based in Los Angeles, California.
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I hadn’t realized the exchange was physics specific. Given the success with physics, I’d expect the biology and chemistry communities would be eager to participate or start their own exchanges.
Back in 2019 Canada was having a problem with Malaysia and the Phillipines over the garbage (this is meant literally) that we were shipping over to those counties, which is why an article about Chinese science fiction writer, Chen Qiufan and his 2013 novel, The Waste Tide, caught my attention and I pubisihed this May 31, 2019 posting, “Chen Qiufan, garbage, and Chinese science fiction stories.” There’s a very brief mention of Liu Cxin in one of the excerpts.
Math and reading scores of Canadian students continue to decline steeply, matching a global trend, according to a new study.
The state of global education was given a bleak appraisal in the Program for International Student Assessment (PISA), which is the first study to examine the academic progress of 15-year-old students in dozens of countries during the pandemic.
Released Tuesday [December 5, 2023], it finds the average international math score fell by the equivalent of 15 points compared to 2018 scores, while reading scores fell 10 points.
The study found Canada’s overall math scores declined 15 points between 2018 and 2022. According to PISA, which defines a drop of 20 points as losing out on a fully year of learning, that means Canada’s math score dropped by an equivalent of three-quarters of a year of learning.
During that same time period, reading scores of Canadian students dropped by 13 points and science by three.
Only 12 per cent of Canadian students were high math achievers, scoring at Level 5 or 6. That’s fewer than some of the top Asian countries and economies: In Singapore, 41 per cent of students performed at the top level; in Hong Kong, 27 per cent; and in Japan and Korea, 23 per cent.
Louis Volante, a professor of education governance at Brock University in St. Catharines, Ont., believes the pandemic had more of a negative effect on math learning than reading and science.
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‘Some provinces declining more than others’
Anna Stokke, a math professor at the University of Winnipeg, notes that math scores in Canada have been trending in the wrong direction since 2003, “with some provinces declining more than others.”
According to the study, the provinces with the largest drop in math scores since 2018 were Newfoundland Labrador with 29, Nova Scotia with 24, New Brunswick with 23 and Manitoba with 22. Meanwhile, Alberta’s score only dropped by seven and B.C.’s just eight.
“I do think part of the problem is the philosophy of how to teach math,” Stokke told CBC News.
“First of all, we’re not spending enough time on math in schools. And second of all, kids just aren’t getting good instruction in a lot of cases. They’re not getting explicit instruction. They’re not getting enough practice. And that really needs to change.”
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A survey of students found about half faced closures of more than three months, but it didn’t always lead to lower scores. There was “no clear difference” in performance trends between countries that had limited closures, including Iceland and Sweden, and those with longer closures, including Brazil and Ireland, according to the report.
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Canada still in top 10
Singapore, long seen as an education powerhouse, had the highest scores by far in every subject. It was joined in the upper echelons by other East Asian countries, including Japan and China.
Despite the declines across the subjects, Canada did well compared to the other countries in the report, placing ninth in math, sixth in reading and seventh in science.
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Usually given every three years, the latest test was delayed a year because of the pandemic. It was administered in 2022 to a sample of 15-year-olds in 37 countries that are OECD members, plus 44 other partner countries. The test has been conducted since 2000.
In 2022, 81 countries participated, with 23,000 Canadian high school students writing the test.
Wendy Hughes (then PhD student) and Sarfaroz Niyozov (then associate professor) both associated with the University of Toronto, presented a critique of PISA in their June 4, 2019 essay on The Conversation,
The Program for International Student Assessment (PISA) — the Organization for Economic Co-operation and Development’s (OECD) global standardized test of student achievement — is frequently used by commentators to compare and rank national or provincial education systems.
PISA, which has now spread into 80 countries as a best education practice, presents itself as a tool to help countries make their systems more inclusive leading to equitable outcomes. But PISA is far more ambiguous and controversial.
Many academics and educators critique PISA as an economic measurement, not an educational one. The media generally use PISA results to blame and shame school systems. And the way that some politicians, policy-makers and researchers have used PISA is more closely aligned to a political process than an educational one.
A March 4, 2024 news item on phys.org announces research into the physics of using paints and inks in visual art, Note: A link has been removed,
Falling from the tip of a brush suspended in mid-air, an ink droplet touches a painted surface and blossoms into a masterpiece of ever-changing beauty. It weaves a tapestry of intricate, evolving patterns. Some of them resemble branching snowflakes, thunderbolts or neurons, whispering the unique expression of the artist’s vision.
Okinawa Institute of Science and Technology (OIST) researchers set out to analyze the physical principles of this fascinating technique, known as dendritic painting. They took inspiration from the artwork of Japanese media artist, Akiko Nakayama. The work is published in the journal PNAS Nexus.
During her [Akiko Nakayama] live painting performances, she applies colourful droplets of acrylic ink mixed with alcohol atop a flat surface coated with a layer of acrylic paint. Beautiful fractals – tree-like geometrical shapes that repeat at different scales and are often found in nature – appear before the eyes of the audience. This is a captivating art form driven by creativity, but also by the physics of fluid dynamics.
“I have a deep admiration for scientists, such as Ukichiro Nakaya and Torahiko Terada, who made remarkable contributions to both science and art. I was very happy to be contacted by OIST physicist Chan San To. I am envious of his ability ‘to dialogue’ with the dendritic patterns, observing how they change shape in response to different approaches. Hearing this secret conversation was delightful,” explains Nakayama.
“Painters have often employed fluid mechanics to craft unique compositions. We have seen it with David Alfaro Siqueiros, Jackson Pollock, and Naoko Tosa, just to name a few. In our laboratory, we reproduce and study artistic techniques, to understand how the characteristics of the fluids influence the final outcome,” says OIST Professor Eliot Fried of OIST’s Mechanics and Materials Unit, who likes looking at dendritic paintings from artistic and scientific angles.
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In dendritic painting, the droplets made of ink and alcohol experience various forces. One of them is surface tension – the force that makes rain droplets spherical in shape, and allows leaves to float on the surface of a pond. In particular, as alcohol evaporates faster than water, it alters the surface tension of the droplet. Fluid molecules tend to be pulled towards the droplet rim, which has higher surface tension compared to its centre. This is called the Marangoni effect and is the same phenomenon responsible for the formation of wine tears – the droplets or streaks of wine that form on the inside of a wine glass after swirling or tilting.
Secondly, the underlying paint layer also plays an important part in this artistic technique. Dr. Chan tested various types of liquids. For fractals to emerge, the liquid must be a fluid that decreases in viscosity under shear strain, meaning it has to behave somewhat like ketchup. It’s common knowledge that it’s hard to get ketchup out of the bottle unless you shake it. This happens because ketchup’s viscosity changes depending on shear strain. When you shake the bottle, the ketchup becomes less viscous, making it easier to pour it onto your dish. How is this applied to dendritic painting?
“In dendritic painting, the expanding ink droplet shears the underlying acrylic paint layer. It is not as strong as the shaking of a ketchup bottle, but it is still a form of shear strain. As with ketchup, the more stress there is, the easier it is for the ink droplets to flow,” explains Dr. Chan.
“We also showed that the physics behind this dendritic painting technique is similar to how liquid travels in a porous medium, such as soil. If you were to look at the mix of acrylic paint under the microscope, you would see a network of microscopic structures made of polymer molecules and pigments. The ink droplet tends to find its way through this underlying network, travelling through paths of least resistance, that leads to the dendritic pattern,” adds Prof. Fried.
Each dendritic print is one-of-a-kind, but there are at least two key aspects that artists can take into consideration to control the outcome of dendritic painting. The first and most important factor is the thickness of the paint layer spread on the surface. Dr. Chan observed that well-refined fractals appear with paint layer thinner than a half millimetre.
The second factor to experiment with is the concentration of diluting medium and paint in this paint layer. Dr. Chan obtained the most detailed fractals using three parts diluting medium and one part paint, or two parts diluting medium and one part paint. If the concentration of paint is higher, the droplet cannot spread well. Conversely, if the concentration of paint is lower, fuzzy edges will form.
This is not the first science-meets-art project that members of the Mechanics and Materials Unit have embarked on. For example, they designed and installed a mobile sculpture on the OIST campus. The sculpture exemplifies a family of mechanical devices, called Möbius kaleidocycles, invented in the Unit, which may offer guidelines for designing chemical compounds with novel electronic properties.
Currently, Dr. Chan is also developing novel methods of analysing how the complexity of a sketch or painting evolves during its creation. He and Prof. Fried are optimistic that these methods might be applied to uncover hidden structures in experimentally captured or numerically generated images of flowing fluids.
“Why should we confine science to just technological progress?” wonders Dr. Chan. “I like exploring its potential to drive artistic innovation as well. I do digital art, but I really admire traditional artists. I sincerely invite them to experiment with various materials and reach out to us if they’re interested in collaborating and exploring the physics hidden within their artwork.”
Instructions to create dendritic painting at home
Everybody can have fun creating dendritic paintings. The materials needed include a non-absorbent surface (glass, synthetic paper, ceramics, etc.), a brush, a hairbrush, rubbing alcohol (iso-propyl alcohol), acrylic ink, acrylic paint and pouring medium.
Dilute one part of acrylic paint to two or three parts of pouring medium, or test other ratios to see how the result changes
Apply this to the non-absorbent surface uniformly using a hairbrush. OIST physicists have found out that the thickness of the paint affects the result. For the best fractals, a layer of paint thinner than half millimetre is recommended.
Mix rubbing alcohol with acrylic ink. The density of the ink may differ for different brands: have a try mixing alcohol and ink in different ratios
When the white paint is still wet (hasn’t dried yet), apply a droplet of the ink with alcohol mix using a brush or another tool, such as a bamboo stick or a toothpick.
Enjoy your masterpiece as it develops before your eyes.
There are three upcoming Simon Fraser University (SFU) Café Scientifique events (Zoom) and one upcoming Nobel=themed lecture (in person) according to a January 15, 2024 notice (received via email), Note: All the events are free,
Hello SFU Cafe Scientifique friends!
We are back with a brand new line up for our Cafe Scientifique discussion series. Zoom invites will be sent closer to the event dates [emphasis mine]. We hope you can join us.
Café Scientifique: Why Do Babies Get Sick? A Systems Biology Approach to Developing Diagnostics and Therapeutics for Neonatal Sepsis.
Tuesday, January 30, 5:00-6:30pm over Zoom
Around the world five newborn babies die each second from life-threatening infections. Unfortunately there is no fast or easy way to tell which microbes are involved. Molecular Biology and Biochemistry assistant professor Amy Lee will share how we can use genomics and machine learning approaches to tackle this challenge. Register here. https://events.sfu.ca/event/38235-cafe-scientifique-january-why-do-babies-get-sick?
Cafe Scientifique: From data to dollars: A journey through financial modelling Tuesday, February 27, 5:00-6:30 pm over Zoom
Financial modelling involves using mathematical and statistical techniques to understand future financial scenarios, helping individuals and businesses make informed decisions about their investments. Join Dr. Jean-François Bégin as he explores how these models can empower us to navigate the complexities of financial markets.
Cafe Scientifique: Overtraining and the Everyday Athlete Tuesday, April 30, 5:00-6:30 pm over Zoom
What happens when we train too hard, don’t take enough time to recover, or underfuel while exercising, and how that applies to both elite athletes and just your “everyday athlete.” Join Dr. Alexandra Coates from our Biomedical Physiology and Kinesiology Department in this interesting discussion.
Missed our last Café Scientifique talk [Decoding how life senses and responds to carbon dioxide gas] with Dustin King? [SFU Molecular Biology and Biochemistry Assistant Professor Dustin King’s Indigenous background is central to his work and relationship with the biochemical research he conducts. He brings Indigenous ways of knowing and a two-eye seeing approach to critical questions about humanity’s impact upon the natural world …] Watch it on YouTube: https://www.youtube.com/watch?v=xCHTSbF3RVs&list=PLTMt9gbqLurAMfSHQqVAHu7YbyOFq81Ix&index=10
The ‘2023 Nobel Prize Lectures’ being presented by SFU do not feature the 2023 winners but rather, SFU experts in the relevant field, from the January 15, 2024 SFU Café Scientifique notice (received via email),
BACK IN-PERSON AT THE SCIENCE WORLD THEATRE!
Location: Science World Theatre 1455 Quebec Street Vancouver, BC V6A 3Z7
NOBEL PRIZE LECTURES
Wednesday, March 6, 2024
6:30-7:30 pm Refreshments, 7:30-9:30 pm Lectures
Celebrate the 2023 Nobel awardees in Chemistry, Physics, Physiology or Medicine!
SFU experts will explain Nobel laureates’ award-winning research and its significance to our everyday lives.
Featured presenters are
*Mark Brockman from Molecular Biology and Biochemistry for the Nobel Prize in Medicine and Physiology;
*Byron Gates from Chemistry for the Nobel Prize in Chemistry; and
*Shawn Sederberg from the School of Engineering Science for the Nobel Prize in Physics.
There’s an intriguing approach tying together ideas about consciousness, artificial intelligence, and physics in an October 8, 2023 news item on phys.org,
With the rise of brain-interface technology and artificial intelligence that can imitate brain functions, understanding the nature of consciousness and how it interacts with reality is not just an age-old philosophical question but also a salient challenge for humanity.
Can AI become conscious, and how would we know? Should we incorporate human or animal cells, such as neurons, into machines and robots? Would they be conscious and have subjective experiences? Does consciousness reduce to physicalism, or is it fundamental? And if machine-brain interaction influenced you to commit a crime, or caused a crime, would you be responsible beyond a reasonable doubt? Do we have a free will?
AI and computer science specialist Dr Mahendra Samarawickrama, winner of the Australian Computer Society’s Information and Communications Technology (ICT) Professional of the year, has applied his knowledge of physics and artificial neural networks to this thorny topic.
He presented a peer-reviewed paper on fundamental physics and consciousness at the 11th International Conference on Mathematical Modelling in Physical Sciences, Unifying Matter, Energy and Consciousness, which has just been published in the AIP (the American Institute of Physics) Conference Proceedings.
“Consciousness is an evolving topic connected to physics, engineering, neuroscience and many other fields. Understanding the interplay between consciousness, energy and matter could bring important insights to our fundamental understanding of reality,” said Dr Samarawickrama.
“Einstein’s dream of a unified theory is a quest that occupies the minds of many theoretical physicists and engineers. Some solutions completely change existing frameworks, which increases complexity and creates more problems than it solves.
“My theory brings the notion of consciousness to fundamental physics such that it complements the current physics models and explains the time, causality, and interplay of consciousness, energy and matter.
“I propose that consciousness is a high-speed sequential flow of awareness subjected to relativity. The quantised energy of consciousness can interplay with matter creating reality while adhering to laws of physics, including quantum physics and relativity.
“Awareness can be seen in life, AI and even physical realities like entangled particles. Studying consciousness helps us be aware of and differentiate realities that exist in nature,” he said.
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Dr Samarawickrama is an honorary Visiting Scholar in the School of Computer Science at the University of Technology Sydney, where he has contributed to UTS research on data science and AI, focusing on social impact.
“Research in this field could pave the way towards the development of conscious AI, with robots that are aware and have the ability to think becoming a reality. We want to ensure that artificial intelligence is ethical and responsible in emerging solutions,” Dr Samarawickrama said.
Here’s a link to and a citation for the paper Samarawickrama presented at the 11th International Conference on Mathematical Modelling in Physical Sciences, Unifying Matter, Energy and Consciousness,
Unifying matter, energy and consciousness by Mahendra Samarawickrama. AIP Conf. Proc. Volume 2872, Issue 1, 28 September 2023, 110001 (2023) DOI: https://doi.org/10.1063/5.0162815
This paper is open access.
The researcher has made a video of his presentation and further information available,
It’s a little bit over my head but hopefully repeated viewings and readings will help me better understand Dr. Samarawickrama’s work.
Randolph Grace’s (Professor of Psychology, University of Canterbury, England) August 14, 2023 essay for The Conversation delves into an interesting question,
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Why have humans invented the same arithmetic, over and over again? Could arithmetic be a universal truth waiting to be discovered?
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The point is made (from Grace’s August 14, 2023 essay), Note: A link has been removed,
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Humans have been making symbols for numbers for more than 5,500 years. More than 100 distinct notation systems are known to have been used by different civilisations, including Babylonian, Egyptian, Etruscan, Mayan and Khmer.
The remarkable fact is that despite the great diversity of symbols and cultures, all are based on addition and multiplication. For example, in our familiar Hindu-Arabic numerals: 1,434 = (1 x 1000) + (4 x 100) + (3 x 10) + (4 x 1).
Why have humans invented the same arithmetic, over and over again? Could arithmetic be a universal truth waiting to be discovered?
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Grace describes a biological phenomenon to support his proposal (from Grace’s August 14, 2023 essay), Note: Links have been removed,
Bees provide a clue
We proposed a new approach based on the assumption that arithmetic has a biological origin.
Many non-human species, including insects, show an ability for spatial navigation which seems to require the equivalent of algebraic computation. For example, bees can take a meandering journey to find nectar but then return by the most direct route, as if they can calculate the direction and distance home.
How their miniature brain (about 960,000 neurons) achieves this is unknown. These calculations might be the non-symbolic precursors of addition and multiplication, honed by natural selection as the optimal solution for navigation.
Arithmetic may be based on biology and special in some way because of evolution’s fine-tuning.
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He goes on to describe how he and his colleagues tested their hypothesis (read the essay) and concludes with this (from Grace’s August 14, 2023 essay), Note: A link has been removed,
Although this structure [how our perception is structured] is shared with other animals, only humans have invented mathematics. It is humanity’s most intimate creation, a realisation in symbols of the fundamental nature and creativity of the mind.
In this sense, mathematics is both invented (uniquely human) and discovered (biologically-based). The seemingly miraculous success of mathematics in the physical sciences hints that our mind and the world are not separate, but part of a common unity.
The arc of mathematics and science points toward non-dualism, a philosophical concept that describes how the mind and the universe as a whole are connected, and that any sense of separation is an illusion. This is consistent with many spiritual traditions (Taoism, Buddhism) and Indigenous knowledge systems such as mātauranga Māori.
Here’s a link to (or PDF for Grace’s paper) and a citation for the paper,
The Psychological Scaffolding of Arithmetic by Matt Grice, Simon Kemp, Nicola J. Morton, Randolph C. Grace. Psychological Review DOI: https://doi.org/10.1037/rev0000431 Advance online publication June 26, 2023
Thanks to Rebecca Bollwitt and the October 24, 2023 posting on her Miss 604 blog for the news about the 2023 (or 6th annual) Girls and STEAM (science, technology, engineering, arts, and math) Summit. From Alexis Miles’s October 24, 2023 post,
The 6th annual Girls and STEAM (science, technology, engineering, arts and design, and math), presented by STEMCELL Technologies, is taking place at Science World November 4th [2023].
Girls and STEAM at Science World Date: Saturday, November 4, 2023 Time: 7:45am to 4:00pm Location: Science World (1455 Quebec Street, Vancouver) Admission: Registration is open online for girls aged 12 to 14.
300 young girls, aged 12-14, will take over the Science World dome in a day of hands-on activities, enriching workshops, inspiring mentorship sessions and a keynote presentation.
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This year’s keynote presentation features Andini Makosinski, Filipina-Polish Canadian inventor best known for her invention of the Hollow Flashlight that runs off the heat of the human hand, and theeDrink, a coffee mug that harvests the excess heat of a hot drink and converts it into electricity to charge a phone. The inspiration for Andini’s flashlight came from her friend in the Philippines, who had failed a grade in school because she had no light or electricity to study with at night.
STEMCELL Technologies, Canada’s largest biotechnology company, is pleased to announce it will be the presenting partner of the Girls and STEAM Summit at Science World in Vancouver.
The Summit, which takes place on November 4, 2023, is a full-day event with workshops, hands-on activities, a keynote presentation, and sessions with experienced mentors who work in STEAM (science, technology, engineering, art and design, and math).
“Science is about so much more than what happens in the laboratory. It provides a lens that can instill a deep-seated curiosity in young minds and enrich every aspect of our lives,” said Sharon Louis, Senior Vice President of Research and Development, STEMCELL. “Scientific education – in the classroom and out in the world – can lead to life-changing experiences and limitless opportunities for young women and girls. STEMCELL is proud to support the Girls and STEAM program to make science more accessible, and help ignite the passion of the next generation of scientists and leaders.”
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About STEMCELL Technologies
STEMCELL Technologies supports life sciences research with more than 2,500 specialized reagents, tools, and services. STEMCELL offers high-quality cell culture media, cell separation technologies, instruments, accessory products, educational resources, and contract assay services that are used by scientists performing stem cell, immunology, cancer, regenerative medicine, and cellular therapy research globally.
Two molecular languages at the origin of life have been successfully recreated and mathematically validated, thanks to pioneering work by Canadian scientists at Université de Montréal.
Published this week in the Journal of American Chemical Society, the breakthrough opens new doors for the development of nanotechnologies with applications ranging from biosensing, drug delivery and molecular imaging.
Living organisms are made up of billions of nanomachines and nanostructures that communicate to create higher-order entities able to do many essential things, such as moving, thinking, surviving and reproducing.
“The key to life’s emergence relies on the development of molecular languages – also called signalling mechanisms – which ensure that all molecules in living organisms are working together to achieve specific tasks,” said the study’s principal investigator, UdeM bioengineering professor Alexis Vallée-Bélisle.
In yeasts, for example, upon detecting and binding a mating pheromone, billions of molecules will communicate and coordinate their activities to initiate union, said Vallée-Bélisle, holder of a Canada Research Chair in Bioengineering and Bionanotechnology.
“As we enter the era of nanotechnology, many scientists believe that the key to designing and programming more complex and useful artificial nanosystems relies on our ability to understand and better employ molecular languages developed by living organisms,” he said.
Two types of languages
One well-known molecular language is allostery. The mechanism of this language is “lock-and-key”: a molecule binds and modifies the structure of another molecule, directing it to trigger or inhibit an activity.
Another, lesser-known molecular language is multivalency, also known as the chelate effect. It works like a puzzle: as one molecule binds to another, it facilitates (or not) the binding of a third molecule by simply increasing its binding interface.
Although these two languages are observed in all molecular systems of all living organisms, it is only recently that scientists have started to understand their rules and principles – and so use these languages to design and program novel artificial nanotechnologies.
“Given the complexity of natural nanosystems, before now nobody was able to compare the basic rules, advantage or limitations of these two languages on the same system,” said Vallée-Bélisle.
To do so, his doctoral student Dominic Lauzon, first author of the study, had the idea of creating a DNA-based molecular system that could function using both languages. “DNA is like Lego bricks for nanoengineers,” said Lauzon. “It’s a remarkable molecule that offers simple, programmable and easy-to-use chemistry.”
Simple mathematical equations to detect antibodies
The researchers found that simple mathematical equations could well describe both languages, which unravelled the parameters and design rules to program the communication between molecules within a nanosystem.
For example, while the multivalent language enabled control of both the sensitivity and cooperativity of the activation or deactivation of the molecules, the corresponding allosteric translation only enabled control of the sensitivity of the response.
With this new understanding at hand, the researchers used the language of multivalency to design and engineer a programmable antibody sensor that allows the detection of antibodies over different ranges of concentration.
“As shown with the recent pandemic, our ability to precisely monitor the concentration of antibodies in the general population is a powerful tool to determine the people’s individual and collective immunity,” said Vallée-Bélisle.
In addition to expanding the synthetic toolbox to create the next generation of nanotechnology, the scientist’s discovery also shines a light on why some natural nanosystems may have selected one language over another to communicate chemical information.