Brainlike transistor and human intelligence

This brainlike transistor (not a memristor) is important because it functions at room temperature as opposed to others, which require cryogenic temperatures.

A December 20, 2023 Northwestern University news release (received via email; also on EurekAlert) fills in the details,

  • Researchers develop transistor that simultaneously processes and stores information like the human brain
  • Transistor goes beyond categorization tasks to perform associative learning
  • Transistor identified similar patterns, even when given imperfect input
  • Previous similar devices could only operate at cryogenic temperatures; new transistor operates at room temperature, making it more practical

EVANSTON, Ill. — Taking inspiration from the human brain, researchers have developed a new synaptic transistor capable of higher-level thinking.

Designed by researchers at Northwestern University, Boston College and the Massachusetts Institute of Technology (MIT), the device simultaneously processes and stores information just like the human brain. In new experiments, the researchers demonstrated that the transistor goes beyond simple machine-learning tasks to categorize data and is capable of performing associative learning.

Although previous studies have leveraged similar strategies to develop brain-like computing devices, those transistors cannot function outside cryogenic temperatures. The new device, by contrast, is stable at room temperatures. It also operates at fast speeds, consumes very little energy and retains stored information even when power is removed, making it ideal for real-world applications.

The study was published today (Dec. 20 [2023]) in the journal Nature.

“The brain has a fundamentally different architecture than a digital computer,” said Northwestern’s Mark C. Hersam, who co-led the research. “In a digital computer, data move back and forth between a microprocessor and memory, which consumes a lot of energy and creates a bottleneck when attempting to perform multiple tasks at the same time. On the other hand, in the brain, memory and information processing are co-located and fully integrated, resulting in orders of magnitude higher energy efficiency. Our synaptic transistor similarly achieves concurrent memory and information processing functionality to more faithfully mimic the brain.”

Hersam is the Walter P. Murphy Professor of Materials Science and Engineering at Northwestern’s McCormick School of Engineering. He also is chair of the department of materials science and engineering, director of the Materials Research Science and Engineering Center and member of the International Institute for Nanotechnology. Hersam co-led the research with Qiong Ma of Boston College and Pablo Jarillo-Herrero of MIT.

Recent advances in artificial intelligence (AI) have motivated researchers to develop computers that operate more like the human brain. Conventional, digital computing systems have separate processing and storage units, causing data-intensive tasks to devour large amounts of energy. With smart devices continuously collecting vast quantities of data, researchers are scrambling to uncover new ways to process it all without consuming an increasing amount of power. Currently, the memory resistor, or “memristor,” is the most well-developed technology that can perform combined processing and memory function. But memristors still suffer from energy costly switching.

“For several decades, the paradigm in electronics has been to build everything out of transistors and use the same silicon architecture,” Hersam said. “Significant progress has been made by simply packing more and more transistors into integrated circuits. You cannot deny the success of that strategy, but it comes at the cost of high power consumption, especially in the current era of big data where digital computing is on track to overwhelm the grid. We have to rethink computing hardware, especially for AI and machine-learning tasks.”

To rethink this paradigm, Hersam and his team explored new advances in the physics of moiré patterns, a type of geometrical design that arises when two patterns are layered on top of one another. When two-dimensional materials are stacked, new properties emerge that do not exist in one layer alone. And when those layers are twisted to form a moiré pattern, unprecedented tunability of electronic properties becomes possible.

For the new device, the researchers combined two different types of atomically thin materials: bilayer graphene and hexagonal boron nitride. When stacked and purposefully twisted, the materials formed a moiré pattern. By rotating one layer relative to the other, the researchers could achieve different electronic properties in each graphene layer even though they are separated by only atomic-scale dimensions. With the right choice of twist, researchers harnessed moiré physics for neuromorphic functionality at room temperature.

“With twist as a new design parameter, the number of permutations is vast,” Hersam said. “Graphene and hexagonal boron nitride are very similar structurally but just different enough that you get exceptionally strong moiré effects.”

To test the transistor, Hersam and his team trained it to recognize similar — but not identical — patterns. Just earlier this month, Hersam introduced a new nanoelectronic device capable of analyzing and categorizing data in an energy-efficient manner, but his new synaptic transistor takes machine learning and AI one leap further.

“If AI is meant to mimic human thought, one of the lowest-level tasks would be to classify data, which is simply sorting into bins,” Hersam said. “Our goal is to advance AI technology in the direction of higher-level thinking. Real-world conditions are often more complicated than current AI algorithms can handle, so we tested our new devices under more complicated conditions to verify their advanced capabilities.”

First the researchers showed the device one pattern: 000 (three zeros in a row). Then, they asked the AI to identify similar patterns, such as 111 or 101. “If we trained it to detect 000 and then gave it 111 and 101, it knows 111 is more similar to 000 than 101,” Hersam explained. “000 and 111 are not exactly the same, but both are three digits in a row. Recognizing that similarity is a higher-level form of cognition known as associative learning.”

In experiments, the new synaptic transistor successfully recognized similar patterns, displaying its associative memory. Even when the researchers threw curveballs — like giving it incomplete patterns — it still successfully demonstrated associative learning.

“Current AI can be easy to confuse, which can cause major problems in certain contexts,” Hersam said. “Imagine if you are using a self-driving vehicle, and the weather conditions deteriorate. The vehicle might not be able to interpret the more complicated sensor data as well as a human driver could. But even when we gave our transistor imperfect input, it could still identify the correct response.”

The study, “Moiré synaptic transistor with room-temperature neuromorphic functionality,” was primarily supported by the National Science Foundation.

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

Moiré synaptic transistor with room-temperature neuromorphic functionality by Xiaodong Yan, Zhiren Zheng, Vinod K. Sangwan, Justin H. Qian, Xueqiao Wang, Stephanie E. Liu, Kenji Watanabe, Takashi Taniguchi, Su-Yang Xu, Pablo Jarillo-Herrero, Qiong Ma & Mark C. Hersam. Nature volume 624, pages 551–556 (2023) DOI: https://doi.org/10.1038/s41586-023-06791-1 Published online: 20 December 2023 Issue Date: 21 December 2023

This paper is behind a paywall.

Striking similarity between memory processing of artificial intelligence (AI) models and hippocampus of the human brain

A December 18, 2023 news item on ScienceDaily shifted my focus from hardware to software when considering memory in brainlike (neuromorphic) computing,

An interdisciplinary team consisting of researchers from the Center for Cognition and Sociality and the Data Science Group within the Institute for Basic Science (IBS) [Korea] revealed a striking similarity between the memory processing of artificial intelligence (AI) models and the hippocampus of the human brain. This new finding provides a novel perspective on memory consolidation, which is a process that transforms short-term memories into long-term ones, in AI systems.

A November 28 (?), 2023 IBS press release (also on EurekAlert but published December 18, 2023, which originated the news item, describes how the team went about its research,

In the race towards developing Artificial General Intelligence (AGI), with influential entities like OpenAI and Google DeepMind leading the way, understanding and replicating human-like intelligence has become an important research interest. Central to these technological advancements is the Transformer model [Figure 1], whose fundamental principles are now being explored in new depth.

The key to powerful AI systems is grasping how they learn and remember information. The team applied principles of human brain learning, specifically concentrating on memory consolidation through the NMDA receptor in the hippocampus, to AI models.

The NMDA receptor is like a smart door in your brain that facilitates learning and memory formation. When a brain chemical called glutamate is present, the nerve cell undergoes excitation. On the other hand, a magnesium ion acts as a small gatekeeper blocking the door. Only when this ionic gatekeeper steps aside, substances are allowed to flow into the cell. This is the process that allows the brain to create and keep memories, and the gatekeeper’s (the magnesium ion) role in the whole process is quite specific.

The team made a fascinating discovery: the Transformer model seems to use a gatekeeping process similar to the brain’s NMDA receptor [see Figure 1]. This revelation led the researchers to investigate if the Transformer’s memory consolidation can be controlled by a mechanism similar to the NMDA receptor’s gating process.

In the animal brain, a low magnesium level is known to weaken memory function. The researchers found that long-term memory in Transformer can be improved by mimicking the NMDA receptor. Just like in the brain, where changing magnesium levels affect memory strength, tweaking the Transformer’s parameters to reflect the gating action of the NMDA receptor led to enhanced memory in the AI model. This breakthrough finding suggests that how AI models learn can be explained with established knowledge in neuroscience.

C. Justin LEE, who is a neuroscientist director at the institute, said, “This research makes a crucial step in advancing AI and neuroscience. It allows us to delve deeper into the brain’s operating principles and develop more advanced AI systems based on these insights.”

CHA Meeyoung, who is a data scientist in the team and at KAIST [Korea Advanced Institute of Science and Technology], notes, “The human brain is remarkable in how it operates with minimal energy, unlike the large AI models that need immense resources. Our work opens up new possibilities for low-cost, high-performance AI systems that learn and remember information like humans.”

What sets this study apart is its initiative to incorporate brain-inspired nonlinearity into an AI construct, signifying a significant advancement in simulating human-like memory consolidation. The convergence of human cognitive mechanisms and AI design not only holds promise for creating low-cost, high-performance AI systems but also provides valuable insights into the workings of the brain through AI models.

Fig. 1: (a) Diagram illustrating the ion channel activity in post-synaptic neurons. AMPA receptors are involved in the activation of post-synaptic neurons, while NMDA receptors are blocked by magnesium ions (Mg²⁺) but induce synaptic plasticity through the influx of calcium ions (Ca²⁺) when the post-synaptic neuron is sufficiently activated. (b) Flow diagram representing the computational process within the Transformer AI model. Information is processed sequentially through stages such as feed-forward layers, layer normalization, and self-attention layers. The graph depicting the current-voltage relationship of the NMDA receptors is very similar to the nonlinearity of the feed-forward layer. The input-output graph, based on the concentration of magnesium (α), shows the changes in the nonlinearity of the NMDA receptors. Courtesy: IBS

This research was presented at the 37th Conference on Neural Information Processing Systems (NeurIPS 2023) before being published in the proceedings, I found a PDF of the presentation and an early online copy of the paper before locating the paper in the published proceedings.

PDF of presentation: Transformer as a hippocampal memory consolidation model based on NMDAR-inspired nonlinearity

PDF copy of paper:

Transformer as a hippocampal memory consolidation model based on NMDAR-inspired nonlinearity by Dong-Kyum Kim, Jea Kwon, Meeyoung Cha, C. Justin Lee.

This paper was made available on OpenReview.net:

OpenReview is a platform for open peer review, open publishing, open access, open discussion, open recommendations, open directory, open API and open source.

It’s not clear to me if this paper is finalized or not and I don’t know if its presence on OpenReview constitutes publication.

Finally, the paper published in the proceedings,

Transformer as a hippocampal memory consolidation model based on NMDAR-inspired nonlinearity by Dong Kyum Kim, Jea Kwon, Meeyoung Cha, C. Justin Lee. Part of Advances in Neural Information Processing Systems 36 (NeurIPS 2023) Main Conference Track

This link will take you to the abstract, access the paper by clicking on the Paper tab.

Transformative potential of Martian nanomaterials

Yes, nanomaterials from Mars! A December 21, 2023 news item on Nanowerk makes the proposition, Note: A link has been removed,

Researchers at the University of Sussex have discovered the transformative potential of Martian nanomaterials, potentially opening the door to sustainable habitation on the red planet. They published their findings in (“Quasi–1D Anhydrite Nanobelts from the Sustainable Liquid Exfoliation of Terrestrial Gypsum for Future Martian-Based Electronics”).

Using resources and techniques currently applied on the International Space Station [ISS] and by NASA [US National Aeronautics and Space Administration], Dr Conor Boland, a Lecturer in Materials Physics at the University of Sussex, led a research group that investigated the potential of nanomaterials – incredibly tiny components thousands of times smaller than a human hair – for clean energy production and building materials on Mars.

Taking what was considered a waste product by NASA and applying only sustainable production methods, including water-based chemistry and low-energy processes, the researchers have successfully identified electrical properties within gypsum nanomaterials – opening the door to potential clean energy and sustainable technology production on Mars.

A December 21, 2023 University of Sussex press release (also on EurekAlert) by Stephanie Allen, which originated the news item, features the lead researcher’s hopes for the discovery, Note: A link has been removed,

Dr Conor Boland, said: 

“This study shows that the potential is quite literally out of this world for nanomaterials. Our study builds off recent research performed by NASA and takes what was considered waste, essentially lumps of rock, and turns it into transformative nanomaterials for a range of applications from creating clean hydrogen fuel to developing an electronic device similar to a transistor, to creating an additive to textiles to increase their robustness.

“This opens avenues for sustainable technology – and building – on Mars but also highlights the broader potential for eco-friendly breakthroughs here on Earth.”

To make the breakthrough the researchers used NASA’s innovative method for extracting water from Martian gypsum, which is dehydrated by the agency to get water for human consumption. This produces a byproduct called anhydrite—considered waste material by NASA, but now shown to be hugely valuable.

The Sussex researchers processed anhydrite into nanobelts –  essentially tagliatelle-shaped materials – demonstrating their potential to provide clean energy and sustainable electronics. Furthermore, at every step of their process, water could be continuously collected and recycled.

Dr Boland added: 

“We are optimistic of the feasibility of this process on Mars, as it requires only naturally occurring materials – everything we used could, in theory, be replicated on the red planet. Arguably this is the most important goal in making the Martian colony sustainable from the outset.”

While full-scale electronics production may be impractical on Mars due to the lack of clean rooms and sterile conditions, the anhydrite nanobelts hold promise for clean energy production on Earth, and could, later down the line, still have a profound effect on sustainable energy production on Mars.

Here’s what a Martian nanomaterial looks like,

Caption: Two raw rocks used by the researchers (left). Vials show the nanobelts in water, with a close up of the actual nanobelts (right). Credit: University of Sussex

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

Quasi–1D Anhydrite Nanobelts from the Sustainable Liquid Exfoliation of Terrestrial Gypsum for Future Martian-Based Electronics by Cencen Wei, Abhijit Roy, Adel K. A. Aljarid, Yi Hu, S. Mark Roe, Dimitrios G. Papageorgiou, Raul Arenal, Conor S. Boland. Advanced Functional Materials DOI: https://doi.org/10.1002/adfm.202310600 First published: 14 December 2023

This paper is open access.

Brain-inspired (neuromrophic) computing with twisted magnets and a patent for manufacturing permanent magnets without rare earths

I have two news bits both of them concerned with magnets.

Patent for magnets that can be made without rare earths

I’m starting with the patent news first since this is (as the company notes in its news release) a “Landmark Patent Issued for Technology Critically Needed to Combat Chinese Monopoly.”

For those who don’t know, China supplies most of the rare earths used in computers, smart phones, and other devices. On general principles, having a single supplier dominate production of and access to a necessary material for devices that most of us rely on can raise tensions. Plus, you can’t mine for resources forever.

This December 19, 2023 Nanocrystal Technology LP news release heralds an exciting development (for the impatient, further down the page I have highlighted the salient sections),

Nanotechnology Discovery by 2023 Nobel Prize Winner Became Launch Pad to Create Permanent Magnets without Rare Earths from China

NEW YORK, NY, UNITED STATES, December 19, 2023 /EINPresswire.com/ — Integrated Nano-Magnetics Corp, a wholly owned subsidiary of Nanocrystal Technology LP, was awarded a patent for technology built upon a fundamental nanoscience discovery made by Aleksey Yekimov, its former Chief Scientific Officer.

This patent will enable the creation of strong permanent magnets which are critically needed for both industrial and military applications but cannot be manufactured without certain “rare earth” elements available mostly from China.

At a glittering awards ceremony held in Stockholm on December10, 2023, three scientists, Aleksey Yekimov, Louis Brus (Professor at Columbia University) and Moungi Bawendi (Professor at MIT) were honored with the Nobel Prize in Chemistry for their discovery of the “quantum dot” which is now fueling practical applications in tuning the colors of LEDs, increasing the resolution of TV screens, and improving MRI imaging.

As stated by the Royal Swedish Academy of Sciences, “Quantum dots are … bringing the greatest benefits to humankind. Researchers believe that in the future they could contribute to flexible electronics, tiny sensors, thinner solar cells, and encrypted quantum communications – so we have just started exploring the potential of these tiny particles.”

Aleksey Yekimov worked for over 19 years until his retirement as Chief Scientific Officer of Nanocrystals Technology LP, an R & D company in New York founded by two Indian-American entrepreneurs, Rameshwar Bhargava and Rajan Pillai.

Yekimov, who was born in Russia, had already received the highest scientific honors for his work before he immigrated to USA in 1999. Yekimov was greatly intrigued by Nanocrystal Technology’s research project and chose to join the company as its Chief Scientific Officer.

During its early years, the company worked on efficient light generation by doping host nanoparticles about the same size as a quantum dot with an additional impurity atom. Bhargava came up with the novel idea of incorporating a single impurity atom, a dopant, into a quantum dot sized host, and thus achieve an extraordinary change in the host material’s properties such as inducing strong permanent magnetism in weak, readily available paramagnetic materials. To get a sense of the scale at which nanotechnology works, and as vividly illustrated by the Nobel Foundation, the difference in size between a quantum dot and a soccer ball is about the same as the difference between a soccer ball and planet Earth.

Currently, strong permanent magnets are manufactured from “rare earths” available mostly in China which has established a near monopoly on the supply of rare-earth based strong permanent magnets. Permanent magnets are a fundamental building block for electro-mechanical devices such as motors found in all automobiles including electric vehicles, trucks and tractors, military tanks, wind turbines, aircraft engines, missiles, etc. They are also required for the efficient functioning of audio equipment such as speakers and cell phones as well as certain magnetic storage media.

The existing market for permanent magnets is $28 billion and is projected to reach $50 billion by 2030 in view of the huge increase in usage of electric vehicles. China’s overwhelming dominance in this field has become a matter of great concern to governments of all Western and other industrialized nations. As the Wall St. Journal put it, China’s now has a “stranglehold” on the economies and security of other countries.

The possibility of making permanent magnets without the use of any rare earths mined in China has intrigued leading physicists and chemists for nearly 30 years. On December 19, 2023, a U.S. patent with the title ‘’Strong Non Rare Earth Permanent Magnets from Double Doped Magnetic Nanoparticles” was granted to Integrated Nano-Magnetics Corp. [emphasis mine] Referring to this major accomplishment Bhargava said, “The pioneering work done by Yekimov, Brus and Bawendi has provided the foundation for us to make other discoveries in nanotechnology which will be of great benefit to the world.”

I was not able to find any company websites. The best I could find is a Nanocrystals Technology LinkedIn webpage and some limited corporate data for Integrated Nano-Magnetics on opencorporates.com.

Twisted magnets and brain-inspired computing

This research offers a pathway to neuromorphic (brainlike) computing with chiral (or twisted) magnets, which, as best as I understand it, do not require rare earths. From a November13, 2023 news item on ScienceDaily,

A form of brain-inspired computing that exploits the intrinsic physical properties of a material to dramatically reduce energy use is now a step closer to reality, thanks to a new study led by UCL [University College London] and Imperial College London [ICL] researchers.

In the new study, published in the journal Nature Materials, an international team of researchers used chiral (twisted) magnets as their computational medium and found that, by applying an external magnetic field and changing temperature, the physical properties of these materials could be adapted to suit different machine-learning tasks.

A November 9, 2023 UCL press release (also on EurekAlert but published November 13, 2023), which originated the news item, fill s in a few more details about the research,

Dr Oscar Lee (London Centre for Nanotechnology at UCL and UCL Department of Electronic & Electrical Engineering), the lead author of the paper, said: “This work brings us a step closer to realising the full potential of physical reservoirs to create computers that not only require significantly less energy, but also adapt their computational properties to perform optimally across various tasks, just like our brains.

“The next step is to identify materials and device architectures that are commercially viable and scalable.”

Traditional computing consumes large amounts of electricity. This is partly because it has separate units for data storage and processing, meaning information has to be shuffled constantly between the two, wasting energy and producing heat. This is particularly a problem for machine learning, which requires vast datasets for processing. Training one large AI model can generate hundreds of tonnes of carbon dioxide.

Physical reservoir computing is one of several neuromorphic (or brain inspired) approaches that aims to remove the need for distinct memory and processing units, facilitating more efficient ways to process data. In addition to being a more sustainable alternative to conventional computing, physical reservoir computing could be integrated into existing circuitry to provide additional capabilities that are also energy efficient.

In the study, involving researchers in Japan and Germany, the team used a vector network analyser to determine the energy absorption of chiral magnets at different magnetic field strengths and temperatures ranging from -269 °C to room temperature.

They found that different magnetic phases of chiral magnets excelled at different types of computing task. The skyrmion phase, where magnetised particles are swirling in a vortex-like pattern, had a potent memory capacity apt for forecasting tasks. The conical phase, meanwhile, had little memory, but its non-linearity was ideal for transformation tasks and classification – for instance, identifying if an animal is a cat or dog.

Co-author Dr Jack Gartside, of Imperial College London, said: “Our collaborators at UCL in the group of Professor Hidekazu Kurebayashi recently identified a promising set of materials for powering unconventional computing. These materials are special as they can support an especially rich and varied range of magnetic textures. Working with the lead author Dr Oscar Lee, the Imperial College London group [led by Dr Gartside, Kilian Stenning and Professor Will Branford] designed a neuromorphic computing architecture to leverage the complex material properties to match the demands of a diverse set of challenging tasks. This gave great results, and showed how reconfiguring physical phases can directly tailor neuromorphic computing performance.”

The work also involved researchers at the University of Tokyo and Technische Universität München and was supported by the Leverhulme Trust, Engineering and Physical Sciences Research Council (EPSRC), Imperial College London President’s Excellence Fund for Frontier Research, Royal Academy of Engineering, the Japan Science and Technology Agency, Katsu Research Encouragement Award, Asahi Glass Foundation, and the DFG (German Research Foundation).

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

Task-adaptive physical reservoir computing by Oscar Lee, Tianyi Wei, Kilian D. Stenning, Jack C. Gartside, Dan Prestwood, Shinichiro Seki, Aisha Aqeel, Kosuke Karube, Naoya Kanazawa, Yasujiro Taguchi, Christian Back, Yoshinori Tokura, Will R. Branford & Hidekazu Kurebayashi. Nature Materials volume 23, pages 79–87 (2024) DOI: https://doi.org/10.1038/s41563-023-01698-8 Published online: 13 November 2023 Issue Date: January 2024

This paper is open access.

Science, Scepticism and Free Speech: a series of three lectures in London, UK and online starting March 27, 2024

I received a March 1, 2024 announcement (email) from Sense about Science about a new lecture series starting in late March 2024,

Critical thinking, open inquiry and the freedom to question have been fundamental to the development of the scientific method and the expansion of knowledge. To explore these ideas further, we’re pleased to invite you to a series of lectures and discussions we are running in partnership with the Free Speech Union.

In Science, Scepticism and Free Speech, Professor Alan Sokal and Professor Paul Garner will make the case for why we should care about science but also question it, concluding with our director Tracey Brown and Toby Young discussing the relationship between science, the public and democratic decision-making.

Events will take place at 7.30pm on 27 March, 27 April and 29 May [2024] at the Art Workers’ Guild in central London. Tickets include a glass of wine, and each event will include plenty of time for audience questions.

f you can’t attend in person, we will send you a Zoom link to join online, free of charge, shortly before each event. Please put the dates in your diary now.

Here’s more from the events page,

We are holding a series of three lectures and discussions in partnership with The Free Speech Union, a public interest body that stands up for the speech rights of its members and campaigns for free speech more widely.

Critical thinking, open inquiry and the freedom to question have been fundamental to the development of the scientific method and the expansion of knowledge. The ideal of objectivity and the goal of truth require the discipline to abstract itself from individuals, from interests and from sentiment, all of which may explain why science is always subject to pressures on its integrity. 

SCIENCE, SCEPTICISM and FREE SPEECH is a unique series of three events – two lectures from eminent scientists and a final session bringing together public figures concerned with the relationship between science, the public and democratic decision-making. Each session will include plenty of time for audience Q and A. 

You are welcome to attend the entire series or individual events. It will also be possible to join online for free – sign up to our mailing list and we’ll send you a link shortly before each event. Join our mailing list to watch online

In-person tickets for each event are £10 for FSU Members, £16 for members of the public, £12 for under-25s. Tickets include a glass of wine on arrival.

The individual events:

What is Science and Why Should We Care?

Wednesday 27 March, 2024, 7.30pm, The Hall, Art Workers’ Guild, 6 Queen Square, London, WC1N 3AT. 

With Professor Alan Sokal,Professor of Mathematics, University College London and Professor Emeritus of Physics, New York University. 

Professor Sokal will draw out the unique contribution of the scientific method to human progress and address contemporary trends which threaten to undermine it, in particular, politicisation and censorship.  

About our speaker 

Famous for his 1996 hoax [emphasis mine; more info. about the hoax follows after the descriptions for the events], Professor Alan Sokal is one of the most powerful voices in the continuing debate about the status of evidence-based knowledge. He is co-author (with Jean Bricmont) of Intellectual Impostures: Postmodernist Philosophers’ Abuse of Science, and author of Beyond the Hoax: Science, Philosophy and Culture.  

Get tickets

How We Learned to Question Medicine

Wednesday 24 April, 2024, 7.30pm, The Hall, Art Workers’ Guild, 6 Queen Square, London, WC1N 3AT. 

With Professor Paul Garner, professor emeritus in Evidence Synthesis in Global Health at the Liverpool School of Tropical Medicine.  

Professor Garner will argue that scepticism is integral to good science and make the case for using the tools of science to hold authority to account. Building on the themes of Professor Sokal’s first lecture, Professor Garner will share noteworthy examples where an insistence on robust evidence and research has led not only to scientific breakthroughs but to the exposure of malpractice. 

About our speaker 

Professor Garner stepped back from full-time employment in 2022 but continues as emeritus. He supports academic staff carrying out systematic reviews on infectious diseases, developing further research on post-viral syndrome, and continued collaborative work in developing guideline methods. He was previously Coordinator of the Centre for Evidence Synthesis in Global Health, Co-ordinating Editor of the Cochrane Infectious Diseases Group, and Director of the Research, Evidence and Development Initiative. Professor Garner is also on the Board of Trustees of Sense about Science. 

Get tickets

Science Under Pressure: Restoring Public Confidence

Wednesday 29th May, 2024, 7.30pm, The Hall, Art Workers’ Guild, 6 Queen Square, London, WC1N 3AT. 

In this concluding conversation, our two speakers, Tracey Brown, Director of Sense about Science, and Toby Young, General Secretary of the Free Speech Union and Editor-in-Chief of the Daily Sceptic, will reflect on the issues raised in the earlier lectures and debate how the relationship between science and the public might be improved. When does healthy scepticism become a refusal to accept well-evidenced truth? How can we uphold science without succumbing to ‘scientism’? How can the public distinguish between relevant expertise and those who merely have strong opinions and loud voices? 

About our speakers 

Tracey Brown OBE is the director of Sense about Science, where she has turned the case for sound science and evidence into popular campaigns, including AllTrials, a global campaign for the reporting of all clinical trial outcomes. Tracey leads Sense about Science’s work on transparency of decisions, to ensure the public has access to the same evidence as decision-makers. This has included drafting the Principles for the Treatment of Independent Scientific Advice, and the Transparency of Evidence framework, now internationally emulated. In 2022 she led the What Counts? inquiry, and a national survey of the public’s experience of policy information during the pandemic, calling for all policy announcements to meet an evidence transparency standard. Tracey is honorary Professor, Science, Technology and Engineering in Public Policy at UCL.  

Toby Young is the General Secretary of the Free Speech Union, a non-partisan, mass membership public interest body that stands up for the speech rights of its members. He co-founded four schools and a multi-academy trust in West London, served as a Fulbright Commissioner and is the author of four books, the best known of which is How to Lose Friends & Alienate People (2001). He is an associate editor of the Spectator, where he’s written a weekly column since 1998, and Editor-in-Chief of the Daily Sceptic. He was formerly an Associate Editor of Quillette and is the author or co-author of three peer reviewed academic articles. 

Get tickets

Sokal Affair

As promised, here’s more about the hoax that Professor Alan Sokal perpetrated, from the Sokal affair Wikipedia entry, Note: Links have been removed,

The Sokal affair, also called the Sokal hoax,[1] was a demonstrative scholarly hoax performed by Alan Sokal, a physics professor at New York University and University College London. In 1996, Sokal submitted an article to Social Text, an academic journal of cultural studies. The submission was an experiment to test the journal’s intellectual rigor, specifically to investigate whether “a leading North American journal of cultural studies—whose editorial collective includes such luminaries as Fredric Jameson and Andrew Ross—[would] publish an article liberally salted with nonsense if (a) it sounded good and (b) it flattered the editors’ ideological preconceptions.”[2]

The article, “Transgressing the Boundaries: Towards a Transformative Hermeneutics of Quantum Gravity”,[3] was published in the journal’s spring/summer 1996 “Science Wars” issue. It proposed that quantum gravity is a social and linguistic construct. The journal did not practice academic peer review and it did not submit the article for outside expert review by a physicist.[3][4] Three weeks after its publication in May 1996, Sokal revealed in the magazine Lingua Franca that the article was a hoax.[2]

The hoax caused controversy about the scholarly merit of commentary on the physical sciences by those in the humanities; the influence of postmodern philosophy on social disciplines in general; and academic ethics, including whether Sokal was wrong to deceive the editors or readers of Social Text; and whether Social Text had abided by proper scientific ethics.

In 2008, Sokal published Beyond the Hoax, which revisited the history of the hoax and discussed its lasting implications.

So, it’s either in person in London, UK or by Zoom if you are on the mailing list. So you can, Get tickets for Lecture 1; Get tickets for Lecture 2; Get tickets for Lecture 3, or Join Sense about Science mailing list to watch online

Science journalism … ch-ch-ch-ch-changes

Not much has changed (!) since Christmas when this December 19, 2023 article by Rae Hodge for Salon about changes where science journalism is concerned was published, Note; Links have been removed,

Advance Publications is owned by a couple of billionaire families. Condé Nast is owned by Advance Publications. Wired magazine is owned by Condé Nast. And this week — as the world reaches the hottest temperatures on record, as another deadly COVID-19 variant steals into the public’s lungs, as owners of unregulated artificial intelligence threaten to unleash mass unemployment with their article-generating internet toys and the whole world needs increasingly complex topics explained — the science desk at Wired got gutted.

It’s not just Wired, of course. Recurrent Ventures axed 151-year-old Popular Science magazine this year, and presumably the last 13 staffers to steward its cultural legacy, leaving only five editorial staffers to crew the online-only ship. There are no full-time staff writers left at National Geographic after this year, and The Washington Post took a tough hit too. Climate desks at CNBC and Gizmodo got cut down. As did the climate team remaining at CNN, the select beat preserved in 2008 after the outlet axed the general science desk. 

Only a couple of years after buying it, billionaire-owned Red Ventures pummeled CNET with layoffs before making it one of the first major outlets to get caught pushing AI-generated articles. Short-sighted layoffs also hit the science desks at Inverse and FiveThirtyEight. Buzzfeed News, with its powerhouse science desk, was brought down. Fortress Investment Group laid off “under 100” Vice News staffers. And 74 journalists at the L.A. Times got the ax. Great Hill Partners owns G/O Media which burned Jezebel and its editorial staffers right when women’s health is facing greater attack in this country than it has since Roe v. Wade. 

“We stand in solidarity with you. You are valued. Your work matters,” wrote Cassandra Willyard, president of the National Association of Science Writers, in a May release. “​​Only five months in, 2023 has proven to be a year of layoffs and shrinking budgets, threatening science journalists and editors whose expertise is crucially important.”

Private equity catastrophes, faceless hedges and trusts, unchecked conglomerates and the ongoing shell game of parent companies — the wealthy gutted US science journalism in 2023 through a number of opaque and convoluted financial vehicles. And there’s no evidence to suggest that trend will stop. Rather, ad-reliant revenue models of wealthy digital proprietors are now failing so hard that their slash-and-burn newsroom tactics are likely to get more aggressive as short-selling the news ramps up to a fire-sale finale. One recent report holds that news outlets saw 2,681 job cuts this year. That’s more than the totals in 2021 or 2022. 

While it isn’t science-specific, the Canadian government has acted to funnel more money to traditional news organizations from digital platforms. The Canadian government passed the highly criticized Bill C-18, “Bill C-18: An Act respecting online communications platforms that make news content available to persons in Canada,” also known as, the “Online News Act” in June 2023.

I have two explanations of the act, (a) the Canadian federal government’s Explanatory Note (updated November 27, 2023) and (b) CTV news online’s Rachel Aiello and Alexandra Mae Jones wrote this July 20, 2023 article, “Understanding Bill C-18: Canada’s Online News Act and its proposed rules, explained” (updated [coincidentally] December 19, 2023).

Hopefully, some of this money will find its way to science writing/journalism and the legislation will provide a way forward for legislation in other countries.

Collaborative research agreement (CRA) with McMaster University (Canada) for development of catheter coating

I don’t always do as good a job at covering the commercialization of emerging technologies as I’d like, so, this December 13, 2023 news item on Yahoo News was a welcome discovery,

Oakville, Ontario–(Newsfile Corp. – December 13, 2023) – FendX Technologies Inc. (CSE: FNDX) (OTCQB: FDXTF) (FSE: E8D) (the “Company” or “FendX“), a nanotechnology company developing surface protection coatings is pleased to announce it has entered into a Collaborative Research Agreement (“CRA“) dated December 12, 2023 with McMaster University (“McMaster“) which details the research and development plan to create a protective catheter coating using our nanotechnology licensed pursuant to the license agreement dated February 5, 2021, as amended, between the Company and McMaster.

Dr. Carolyn Myers, President and CEO of FendX, stated, “We are excited about the prospect of developing a coating for catheters using our nanotechnology which we believe will reduce catheter blockage caused by either blood clots or bacterial biofilms. Early work conducted at McMaster has demonstrated significant reduction in the adherence of both bacteria and blood which could potentially translate to reduced bacterial biofilm or blood clot formation. [emphasis mine] Our aim is to further this research to tackle the medical need to reduce catheter blockage rates, which can be costly and interfere with patient therapy. We anticipate the development of this coating formulation will also strengthen our overall intellectual property portfolio.”

The CRA outlines more fully the research and development work to be conducted by McMaster on behalf of FendX as well as a payment schedule for the maximum research funding requirements. The term of the CRA is for 24 months commencing on the effective date of December 1, 2023, unless terminated in accordance with the provisions of the CRA. In the first and second year, maximum research funding to McMaster will be $150,547 each year.

About FendX Technologies Inc.

FendX is a Canada-based nanotechnology company focused on developing products to make people’s lives safer by reducing the spread of pathogens. The Company is developing both film and spray products to protect surfaces from contamination. The lead product under development, REPELWRAP™ film, is a protective surface coating film that, due to its repelling properties, prevents the adhesion of pathogens and reduces their transmission on surfaces prone to contamination. The spray nanotechnology is a bifunctional spray coating being developed to reduce contamination on surfaces by repelling and killing pathogens. The Company is conducting research and development activities using its nanotechnology in collaboration with industry-leading partners, including McMaster University. The Company has an exclusive worldwide license to its technology and IP portfolio from McMaster, which encompass both film and spray coating nanotechnology formulations.

For more information, please visit https://fendxtech.com/ and the Company’s profile on SEDAR+ at www.sedarplus.ca.

Neither the Canadian Securities Exchange nor the Market Regulator (as that term is defined in the policies of the Canadian Securities Exchange) accepts responsibility for the adequacy or accuracy of this release.

Forward-Looking Statements

This news release contains certain forward-looking statements within the meaning of Canadian securities legislation, including with respect to: the plans of the Company; statements regarding the catheter coating development and anticipated benefits; the Company’s belief that the catheter coating could reduce catheter occlusions caused by either blood clots or bacterial biofilms; statements regarding strengthening the Company’s overall intellectual property portfolio; the Company’s belief that REPELWRAP™ will have applications in healthcare settings and other industries; and products under development and any pathogen reduction benefits related thereto. Although the Company believes that such statements are reasonable, it can give no assurance that such expectations will prove to be correct. Forward-looking statements are statements that are not historical facts; they are generally, but not always, identified by the words “expects,” “plans,” “anticipates,” “believes,” “intends,” “estimates,” “projects,” “aims,” “potential,” “goal,” “objective,” “prospective,” and similar expressions, or that events or conditions “will,” “would,” “may,” “can,” “could” or “should” occur, or are those statements, which, by their nature, refer to future events. The Company cautions that forward-looking statements are based on the beliefs, estimates and opinions of the Company’s management on the date the statements are made and involve several risks and uncertainties. Consequently, there can be no assurances that such statements will prove to be accurate and that actual results and future events could differ materially from those anticipated in such statements.

Important factors that could cause future results to differ materially from those anticipated in these forward-looking statements include: product candidates only being in formulation/reformulation stages; limited operating history; research and development activities; dependence on collaborative partners, licensors and others; effect of general economic and political conditions; and other risk factors set forth in the Company’s public filings which are available on SEDAR+ at www.sedarplus.ca. Accordingly, the reader is urged to refer to the Company’s such filings for a more complete discussion of such risk factors and their potential effects. Except to the extent required by applicable securities laws and the policies of the Canadian Securities Exchange, the Company undertakes no obligation to update these forward-looking statements if management’s beliefs, estimates or opinions, or other factors should change.

FendX offers next to no information about their technology or the proposed work with McMaster as seen in this excerpt from the Our Technology webpage on the FendX website,

Our patent-pending licensed nanotechnology works by combining a hierarchical wrinkled molecular structure with chemical functionalization to create nano-surfaces with repelling properties that prevent adhesion of bacteria, viruses and liquids.

Inspired by the water-resistant surface of the lotus leaf

Our nanotechnology causes both high surface tension (e.g., water) and low surface tension (e.g., oil) liquids to form droplets when they come in contact with the nano-surface.

The repelling properties of our nano-surfaces prevents adhesion of bacteria and viruses.

We believe our technology will have numerous applications and opportunities in healthcare and other industries.

That’s it. No technical details and not a single research study is cited.

While McMaster University doesn’t seem to have issued any news releases about their joint research effort with FendX, there are two research papers that I’m reasonably confident are relevant. From the Didar Lab Publications webpage, here are links and citation for both papers,

An omniphobic lubricant-infused coating produced by chemical vapor deposition of hydrophobic organosilanes attenuates clotting on catheter surfaces by Maryam Badv, Iqbal H. Jaffer, Jeffrey I. Weitz & Tohid F. Didar. Scientific Reports volume 7, Article number: 11639 (2017) DOI: https://doi.org/10.1038/s41598-017-12149-1 Published: 14 September 2017

This paper is open access.

Highly Stable Hierarchically Structured All-Polymeric Lubricant-Infused Films Prevent Thrombosis and Repel Multidrug-Resistant Pathogens by Elisabet Afonso, Fereshteh Bayat, Liane Ladouceur, Shadman Khan, Aránzazu Martínez-Gómez, Jeffrey I. Weitz, Zeinab Hosseinidoust, Pilar Tiemblo, Nuria García, and Tohid F. Didar. CS Appl. Mater. Interfaces 2022, 14, 48, 53535–53545 DOI: https://doi.org/10.1021/acsami.2c17309 Publication Date: November 22, 2022 Copyright © 2022 American Chemical Society

This paper is behind a paywall.

Interweave: A multi-sensory show (March 21, 2024 in Vancouver, Canada) where fashion, movement, & music come together though wearable instruments.

Interweave is a free show at The Kent in the gallery in downtown Vancouver, Canada. Here’s more from a Simon Fraser University (SFU) announcement (received via email),

SFU School for the Contemporary Arts (SCA) alumnus, Kimia Koochakzadeh-Yazdi, is hosting Interweave, a multi-sensory show where fashion, movement, and music come together though wearable instruments.

Embrace the fusion of creativity and expression alongside your fellow alumni in a setting that celebrates innovation and the uncharted synergy between fashion, music, and movement. This is a great opportunity to mingle and reconnect with your peers.

Event Details:

Date: March 21, 2024
Time: Doors 7:30pm, Show 8:00pm
Location: The Kent Vancouver, 534 Cambie Street
Free Entry, RSVP required

Interweave is the first event from Fashion x Electronics (FXE), a collective created by Kimia Koochakzadeh-Yazdi, SCA alumnus, composer, and performer, and designer Kayla Yazdi. FXE is an interdisciplinary collective that is building multi-sensory experiences for their community, bridging together a diverse range of disciplines.

This is a 19+ event. ID will be checked at the door.

RSVP Now!

I wasn’t able to discern much more about the event or the Yazdi sisters from their Fashion x Electronics (FXE) website but there is this about Kayla Yazdi on her FXE profile,

Kayla Yazdi

Designer / Co-Producer

Kayla Yazdi is an Iranian-Canadian designer based in Vancouver, Canada. Her upbringing in Iran immersed her in a world of culture, art, and color. Holding a diploma in painting and a bachelor’s degree in design with a specialization in fashion and technology, Kayla has cultivated the skill set that merges her artistic sensibilities with innovative design concepts.

Kayla is dedicated to the creation of “almost” zero-waste garments. With design, technology, and experimentation, Kayla seeks to minimize environmental impacts while delivering unique styles.

Kimia Koochakzadeh-Yazdi’s FXE profile has this,

Kimia Koochakzadeh-Yazdi

Sound Artist / Co-Producer

Kimia Koochakzadeh-Yazdi(b. 1997 Tehran, Iran) is a California/Vancouver-based composer and performer. She writes for hybrid instrumental/electronic ensembles, creates electroacoustic and audiovisual works, and performs electronic music. Kimia explores the unfamiliar familiar while constantly being driven by the concepts of motion, interaction, and growth in both human life and in the sonic world. Being a cross-disciplinary artist, she has actively collaborated on projects evolving around dance, film, and theatre. Kimia’s work has been showcased by organizations such as Iranian Female Composer Association, Music on Main, Western Front, Vancouver New Music, and Media Arts Committee. She has been featured in The New York Times, Georgia Straight, MusicWorks Magazine, Vancouver Sun, and Sequenza 21. Her work has been performed at festivals around the world including Ars Electronica Festival, Festival Ecos Urbanos, Tehran Contemporary Sounds, AudioVisual Frontiers Virtual Exhibition, The New York City Electroacoustic Music Festival, Yarn/Wire Institute, Ensemble Evolution, New Music on the Point, wasteLAnd Summer Academy, EQ: Evolution of the String Quartet, Modulus Festival, and SALT New Music Festival. She holds a BFA in Music Composition from Simon Fraser University’s Interdisciplinary School for the Contemporary Arts, having studied with Sabrina Schroeder and Mauricio Pauly. Kimia is currently pursuing her DMA in Music Composition at Stanford University.

For more details about the sisters and the performance, Marilyn R. Wilson has written up a February 21, 2024 interview with both sisters for her Olio blog,

Can you share a little bit about your background, the life, work, experiences that led you to who you are today?
Kayla: I’m a visual artist with a focus on fashion design, and textile development. I like to explore ways to create wearable art with minimal waste produced in the process. I studied painting at Azadehgan School of Art in Iran and fashion design & technology at Wilson School of Design in Vancouver. My interest in fashion is rooted in creating functional art. I enjoy the business aspect of fashion however, I want to push boundaries of how fashion can be seen as art rather than solely as production.

Kimia: I’m a composer of acoustic and electronic music, I perform and build instruments, and a lot of times I combine these components together. Working with various disciplines is also an important part of my practice. I studied piano performance at Tehran Music School before moving to Vancouver to study composition at Simon Fraser University. I am currently a doctorate candidate in music composition at Stanford University. I love electronic music, food, and sports! My family, partner, and friends are a huge part of my life!

You have your premier event called “Interweave” coming up on March 21st at The Kent Gallery in Vancouver. What can guests attending expect this evening?

Kayla & Kimia: Interweave is a multidisciplinary performance that bridges fashion, music, technology, and dance. Our dancers will be performing in garments designed by Kayla, that are embedded with microcontrollers and sensors developed by Kimia. The dancers control various musical parameters through their movements and their interaction with the sensors that are incorporated within the garments. Along with works for movement and dance, there will be a live electronic music performance made for costume-made instruments. So far we have received an amazing amount of support and RSVP’s from the art industry in Vancouver and look forward to welcoming many local creative individuals.

We’d love to know about the team of professionals who are working hard to create this unique experience. 

Kayla & Kimia: We are working with the amazing choreographers/dancers Anya Saugstad and Daria Mikhailiuk. We are thankful for Laleh Zandi’s help for creating a sculpture for one of our instruments which will be performed by Kimia. Celeste Betancur and Richard Lee have been our amazing audio tech assistants. We are very appreciative of everyone involved in FXE’s premiere and can’t wait to showcase our hard work.

I have a bit more about Kimia Koochakzadeh-Yazdi and her work in music from a February 27, 2024 profile on the SFU School for the Contemporary Arts website, Note: Links have been removed,

Please introduce yourself.

I’m a composer of acoustic and electronic music, I perform and build instruments, and a lot of times, I combine these components together. Working with various disciplines is also an important part of my practice. I studied piano performance at Tehran Music School before moving to Vancouver to study composition at Simon Fraser University, graduating from the SCA in 2020. I am currently a doctoral student in music composition at Stanford University, where I spend most of my time.

Tell us about your current studies.

I’m in the third year of the DMA (Doctor of Musical Arts) program at Stanford University. I do the majority of my work at the Center for Computer Research in Music and Acoustics (CCRMA). I’m currently trying to learn and to experiment as much as possible! The amount of resources and ideas that I have been exposed to during the last couple of years has been quite significant and wonderful. I have been taking courses in subjects that I never thought I would study, from classes in the computer science and the mechanical engineering departments, to ones in education and theatre. I’m grateful to have been given a supportive platform to truly experiment and to learn.

As for my compositions, they are more melodic than before, and that currently makes me happy. I have started to perform more again (piano and electronics), and it makes me question: why did I ever stop…?

Koochakzadeh-Yazdi’s mention of building instruments reminded me of Icelandic musician, Bjork and Biophilia, which was an album, various art projects, and a film (Biophilia Live), which featured a number of musical instruments she created.

Getting back to Interweave, it’ s on March 21, 2024 at The Kent, specifically the gallery, which has,

… 14 foot ceilings boasts 50 track lights with the ability to transform the vacuous hall from candlelight to daylight. The lights are fully dimmable in an array of playful hues, according to your whim.   A full array of DMX Lighting and control systems live alongside the track light system and our recently installed (Vancouvers only) immersive projection system [emphasis mine] is ready for your vision.  This is your show.

I wonder if ‘multi-sensory’ includes an immersive experience.

Don’t forget, you have to RSVP for Interweave, which is free.