Category Archives: water

The cost of building ChatGPT

After seeing the description for Laura U. Marks’s recent work ‘Streaming Carbon Footprint’ (in my October 13, 2023 posting about upcoming ArtSci Salon events in Toronto), where she focuses on the environmental impact of streaming media and digital art, I was reminded of some September 2023 news.

A September 9, 2023 news item (an Associated Press article by Matt O’Brien and Hannah Fingerhut) on phys.org and also published September 12, 2023 on the Iowa Public Radio website, describe an unexpected cost for building ChatGPT and other AI agents, Note: Links have been removed,

The cost of building an artificial intelligence product like ChatGPT can be hard to measure.

But one thing Microsoft-backed OpenAI needed for its technology was plenty of water [emphases mine], pulled from the watershed of the Raccoon and Des Moines rivers in central Iowa to cool a powerful supercomputer as it helped teach its AI systems how to mimic human writing.

As they race to capitalize on a craze for generative AI, leading tech developers including Microsoft, OpenAI and Google have acknowledged that growing demand for their AI tools carries hefty costs, from expensive semiconductors to an increase in water consumption.

But they’re often secretive about the specifics. Few people in Iowa knew about its status as a birthplace of OpenAI’s most advanced large language model, GPT-4, before a top Microsoft executive said in a speech it “was literally made next to cornfields west of Des Moines.”

In its latest environmental report, Microsoft disclosed that its global water consumption spiked 34% from 2021 to 2022 (to nearly 1.7 billion gallons , or more than 2,500 Olympic-sized swimming pools), a sharp increase compared to previous years that outside researchers tie to its AI research. [emphases mine]

“It’s fair to say the majority of the growth is due to AI,” including “its heavy investment in generative AI and partnership with OpenAI,” said Shaolei Ren, [emphasis mine] a researcher at the University of California, Riverside who has been trying to calculate the environmental impact of generative AI products such as ChatGPT.

If you have the time, do read the O’Brien and Fingerhut article in it entirety. (Later in this post, I have a citation for and a link to a paper by Ren.)

Jason Clayworth’s September 18, 2023 article for AXIOS describes the issue from the Iowan perspective, Note: Links have been removed,

Future data center projects in West Des Moines will only be considered if Microsoft can implement technology that can “significantly reduce peak water usage,” the Associated Press reports.

Why it matters: Microsoft’s five WDM data centers — the “epicenter for advancing AI” — represent more than $5 billion in investments in the last 15 years.

Yes, but: They consumed as much as 11.5 million gallons of water a month for cooling, or about 6% of WDM’s total usage during peak summer usage during the last two years, according to information from West Des Moines Water Works.

This information becomes more intriguing (and disturbing) after reading a February 10, 2023 article for the World Economic Forum titled ‘This is why we can’t dismiss water scarcity in the US‘ by James Rees and/or an August 11, 2020 article ‘Why is America running out of water?‘ by Jon Heggie published by the National Geographic, which is a piece of paid content. Note: Despite the fact that it’s sponsored by Finish Dish Detergent, the research in Heggie’s article looks solid.

From Heggie’s article, Note: Links have been removed,

In March 2019, storm clouds rolled across Oklahoma; rain swept down the gutters of New York; hail pummeled northern Florida; floodwaters forced evacuations in Missouri; and a blizzard brought travel to a stop in South Dakota. Across much of America, it can be easy to assume that we have more than enough water. But that same a month, as storms battered the country, a government-backed report issued a stark warning: America is running out of water.

As the U.S. water supply decreases, demand is set to increase. On average, each American uses 80 to 100 gallons of water every day, with the nation’s estimated total daily usage topping 345 billion gallons—enough to sink the state of Rhode Island under a foot of water. By 2100 the U.S. population will have increased by nearly 200 million, with a total population of some 514 million people. Given that we use water for everything, the simple math is that more people mean more water stress across the country.

And we are already tapping into our reserves. Aquifers, porous rocks and sediment that store vast volumes of water underground, are being drained. Nearly 165 million Americans rely on groundwater for drinking water, farmers use it for irrigation―37 percent of our total water usage is for agriculture—and industry needs it for manufacturing. Groundwater is being pumped faster than it can be naturally replenished. The Central Valley Aquifer in California underlies one of the nation’s most agriculturally productive regions, but it is in drastic decline and has lost about ten cubic miles of water in just four years.

Decreasing supply and increasing demand are creating a perfect water storm, the effects of which are already being felt. The Colorado River carved its way 1,450 miles from the Rockies to the Gulf of California for millions of years, but now no longer reaches the sea. In 2018, parts of the Rio Grande recorded their lowest water levels ever; Arizona essentially lives under permanent drought conditions; and in South Florida’s freshwater aquifers are increasingly susceptible to salt water intrusion due to over-extraction.

The focus is on individual use of water and Heggie ends his article by suggesting we use less,

… And every American can save more water at home in multiple ways, from taking shorter showers to not rinsing dishes under a running faucet before loading them into a dishwasher, a practice that wastes around 20 gallons of water for each load. …

As an advertising pitch goes, this is fairly subtle as there’s no branding in the article itself and it is almost wholly informational.

Attempts to stave off water shortages as noted in Heggie’s and other articles include groundwater pumping both for individual use and industrial use. This practice has had an unexpected impact according to a June 16, 2023 article by Warren Cornwall for Science (magazine),

While spinning on its axis, Earth wobbles like an off-kilter top. Sloshing molten iron in Earth’s core, melting ice, ocean currents, and even hurricanes can all cause the poles to wander. Now, scientists have found that a significant amount of the polar drift results from human activity: pumping groundwater for drinking and irrigation.

“The very way the planet wobbles is impacted by our activities,” says Surendra Adhikari, a geophysicist at NASA’s Jet Propulsion Laboratory and an expert on Earth’s rotation who was not involved in the study. “It is, in a way, mind boggling.”

Clark R. Wilson, a geophysicist at the University of Texas at Austin, and his colleagues thought the removal of tens of gigatons of groundwater each year might affect the drift. But they knew it could not be the only factor. “There’s a lot of pieces that go into the final budget for causing polar drift,” Wilson says.

The scientists built a model of the polar wander, accounting for factors such as reservoirs filling because of new dams and ice sheets melting, to see how well they explained the polar movements observed between 1993 and 2010. During that time, satellite measurements were precise enough to detect a shift in the poles as small as a few millimeters.

Dams and ice changes were not enough to match the observed polar motion. But when the researchers also put in 2150 gigatons of groundwater that hydrologic models estimate were pumped between 1993 and 2010, the predicted polar motion aligned much more closely with observations. Wilson and his colleagues conclude that the redistribution of that water weight to the world’s oceans has caused Earth’s poles to shift nearly 80 centimeters during that time. In fact, groundwater removal appears to have played a bigger role in that period than the release of meltwater from ice in either Greenland or Antarctica, the scientists reported Thursday [June 15, 2023] in Geophysical Research Letters.

The new paper helps confirm that groundwater depletion added approximately 6 millimeters to global sea level rise between 1993 and 2010. “I was very happy” that this new method matched other estimates, Seo [Ki-Weon Seo geophysicist at Seoul National University and the study’s lead author] says. Because detailed astronomical measurements of the polar axis location go back to the end of the 19th century, polar drift could enable Seo to trace the human impact on the planet’s water over the past century.

Two papers: environmental impact from AI and groundwater pumping wobbles poles

I have two links and citations for Ren’s paper on AI and its environmental impact,

Towards Environmentally Equitable AI via Geographical Load Balancing by Pengfei Li, Jianyi Yang, Adam Wierman, Shaolei Ren. Subjects: Artificial Intelligence (cs.AI); Computers and Society (cs.CY) Cite as: arXiv:2307.05494 [cs.AI] (or arXiv:2307.05494v1 [cs.AI] for this version) DOI: https://doi.org/10.48550/arXiv.2307.05494 Submitted June 20, 2023

Towards Environmentally Equitable AI via Geographical Load Balancing by Li, Pengfei; Yang, Jianyi; Wierman, Adam; Ren, Shaolei. UC Riverside. Retrieved from https://escholarship.org/uc/item/79c880vf Publication date: 2023-06-27

Both links offer open access to the paper. Should you be interested in more, you can find Shaolei Ren’s website here.

Now for the wobbling poles,

Drift of Earth’s Pole Confirms Groundwater Depletion as a Significant Contributor to Global Sea Level Rise 1993–2010 by Ki-Weon Seo, Dongryeol Ryu, Jooyoung Eom, Taewhan Jeon, Jae-Seung Kim, Kookhyoun Youm, Jianli Chen, Clark R. Wilson. Geophysical Research Letters Volume 50, Issue 12, 28 June 2023 e2023GL103509 DOI: https://doi.org/10.1029/2023GL103509 First published online: 15 June 2023

This paper too is open access.

Water talks to electrons in graphene (i.e., carbon)?

Institutions from Spain, Germany, and England collaborated on the study announced in this June 23, 2023 news item on Nanowerk, Note: A link has been removed,

For the last 20 years, scientists have been puzzled by how water behaves near carbon surfaces. It may flow much faster than expected from conventional flow theories or form strange arrangements such as square ice.

Now, an international team of researchers from the Max Plank Institute for Polymer Research of Mainz (Germany), the Catalan Institute of Nanoscience and Nanotechnology (ICN2, Spain), and the University of Manchester (England), reports in a study published in Nature Nanotechnology (“Electron cooling in graphene enhanced by plasmon–hydron resonance”) that water can interact directly with the carbon’s electrons: a quantum phenomenon that is very unusual in fluid dynamics.

Pictured above: Water-graphene quantum friction (Credits: Lucy Reading-Ikkanda / Simons Foundation)

There are two press releases with almost identical text, the June 22, 2023 Max Planck Institute press release with its additional introductory paragraph is below,

Water and carbon make a quantum couple: the flow of water on a carbon surface is governed by an unusual phenomenon dubbed quantum friction. A work published in ‘Nature Nanotechnology’ experimentally demonstrates this phenomenon – which was predicted in a previous theoretical study— at the interface between liquid water and graphene, a single layer of carbon atoms. Advanced ultrafast techniques were used to perform this study. These results could lead to applications in water purification and desalination processes and maybe even to liquid-based computers.

A liquid, such as water, is made up of small molecules that randomly move and constantly collide with each other. A solid, in contrast, is made of neatly arranged atoms that bathe in a cloud of electrons. The solid and the liquid worlds are assumed to interact only through collisions of the liquid molecules with the solid’s atoms: the liquid molecules do not “see” the solid’s electrons. Nevertheless, just over a year ago, a paradigm-shifting theoretical study proposed that at the water-carbon interface, the liquid’s molecules and the solid’s electrons push and pull on each other, slowing down the liquid flow: this new effect was called quantum friction. However, the theoretical proposal lacked experimental verification.

“We have now used lasers to see quantum friction at work,” explains study lead author Dr Nikita Kavokine, a researcher at the Max Planck Institute in Mainz and the Flatiron Institute in New York. The team studied a sample of graphene – a single monolayer of carbon atoms arranged in a honeycomb pattern. They used ultrashort red laser pulses (with a duration of only a millionth of a billionth of a second) to instantaneously heat up the graphene’s electron cloud. They then monitored its cooling with terahertz laser pulses, which are sensitive to the temperature of the graphene electrons. This technique is called optical pump – terahertz probe (OPTP) spectroscopy.

To their surprise, the electron cloud cooled faster when the graphene was immersed in water, while immersing the graphene in ethanol made no difference to the cooling rate. “This was yet another indication that the water-carbon couple is somehow special, but we still had to understand what exactly was going on,” Kavokine says. A possible explanation was that the hot electrons push and pull on the water molecules to release some of their heat: in other words, they cool through quantum friction. The researchers delved into the theory, and indeed: water-graphene quantum friction could explain the experimental data.

“It’s fascinating to see that the carrier dynamics of graphene keep surprising us with unexpected mechanisms, this time involving solid-liquid interactions with molecules none other than the omnipresent water,” comments Prof Klaas-Jan Tielrooij from ICN2 (Spain) and TU Eindhoven (The Netherlands). What makes water special here is that its vibrations, called hydrons, are in sync with the vibrations of the graphene electrons, called plasmons, so that the graphene-water heat transfer is enhanced through an effect known as resonance.

The experiments thus confirm the basic mechanism of solid-liquid quantum friction. This will have implications for filtration and desalination processes, in which quantum friction could be used to tune the permeation properties of the nanoporous membranes. “Our findings are not only interesting for physicists, but they also hold potential implications for electrocatalysis and photocatalysis at the solid-liquid interface,” says Xiaoqing Yu, PhD student at the Max Planck Institute in Mainz and first author of the work.

The discovery was down to bringing together an experimental system, a measurement tool and a theoretical framework that seldom go hand in hand. The key challenge is now to gain control over the water-electron interaction. “Our dream is to switch quantum friction on and off on demand,” Kavokine says. “This way, we could design smarter water filtration processes, or perhaps even fluid-based computers.”   

The almost identical June 26, 2023 University of Manchester press release is here.

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

Electron cooling in graphene enhanced by plasmon–hydron resonance by Xiaoqing Yu, Alessandro Principi, Klaas-Jan Tielrooij, Mischa Bonn & Nikita Kavokine. Nature Nanotechnology (2023) DOI: https://doi.org/10.1038/s41565-023-01421-3 Published: 22 June 2023

This paper is open access.

Remove 80 percent of dye pollutants from wastewater with wood nanocrystals

They’re usually known as cellulose nanocrystals (CNCs) but the term wood nanocrystals works too. From a March 23, 2023 news item on Nanowerk,

Researchers at Chalmers University of Technology, Sweden, have developed a new method that can easily purify contaminated water using a cellulose-based material. This discovery could have implications for countries with poor water treatment technologies and combat the widespread problem of toxic dye discharge from the textile industry.

Clean water is a prerequisite for our health and living environment, but far from a given for everyone. According to the World Health Organization, WHO, there are currently over two billion people living with limited or no access to clean water.

This global challenge is at the centre of a research group at Chalmers University of Technology, which has developed a method to easily remove pollutants from water. The group, led by Gunnar Westman, Associate Professor of Organic Chemistry focuses on new uses for cellulose and wood-based products and is part of the Wallenberg Wood Science Center.

The researchers have built up solid knowledge about cellulose nanocrystals* – and this is where the key to water purification lies. These tiny nanoparticles have an outstanding adsorption capacity, which the researchers have now found a way to utilise.

“We have taken a unique holistic approach to these cellulose nanocrystals, examining their properties and potential applications. We have now created a biobased material, a form of cellulose powder with excellent purification properties that we can adapt and modify depending on the types of pollutants to be removed,” says Gunnar Westman.

Caption: Researchers at Chalmers University of Technology, Sweden, have developed a new biobased material, a form of powder based on cellulose nanocrystals to purify water from pollutants, including textile dyes. When the polluted water passes through the filter with cellulose powder, the pollutants are absorbed, and the sunlight entering the treatment system causes them to break down quickly and efficiently. Laboratory tests have shown that at least 80 percent of the dye pollutants are removed with the new method and material, and the researchers see good opportunities to further increase the degree of purification. Credit: Chalmers University of Technology, Sweden | David Ljungberg

A March 23, 2023 Chalmers University of Technology press release (also on EurekAlert), which originated the news item, describes the water treatment in more detail including how it will be tested in field conditions,

Absorbs and breaks down toxins
In a study recently published in the scientific journal Industrial & Engineering Chemistry Research, the researchers show how toxic dyes can be filtered out of wastewater using the method and material developed by the group. The research was conducted in collaboration with the Malaviya National Institute of Technology Jaipur in India, where dye pollutants in textile industry wastewater are a widespread problem.

The treatment requires neither pressure nor heat and uses sunlight to catalyse the process. Gunnar Westman likens the method to pouring raspberry juice into a glass with grains of rice, which soak up the juice to make the water transparent again. 

“Imagine a simple purification system, like a portable box connected to the sewage pipe. As the contaminated water passes through the cellulose powder filter, the pollutants are absorbed and the sunlight entering the treatment system causes them to break down quickly and efficiently. It is a cost-effective and simple system to set up and use, and we see that it could be of great benefit in countries that currently have poor or non-existent water treatment,” he says. 

The method will be tested in India
India is one of the developing countries in Asia with extensive textile production, where large amounts of dyes are released into lakes, rivers and streams every year. The consequences for humans and the environment are serious. Water contaminant contains dyes and heavy metals and can cause skin damage with direct contact and increase the risk of cancer and organ damage when they enter into the food chain. Additionally, nature is affected in several ways, including the impairment of photosynthesis and plant growth.

Conducting field studies in India is an important next step, and the Chalmers researchers are now supporting their Indian colleagues in their efforts to get some of the country’s small-scale industries to test the method in reality. So far, laboratory tests with industrial water have shown that more than 80 percent of the dye pollutants are removed with the new method, and Gunnar Westman sees good opportunities to further increase the degree of purification.

“Going from discharging completely untreated water to removing 80 percent of the pollutants is a huge improvement, and means significantly less destruction of nature and harm to humans. In addition, by optimising the pH and treatment time, we see an opportunity to further improve the process so that we can produce both irrigation and drinking water. It would be fantastic if we can help these industries to get a water treatment system that works, so that people in the surrounding area can use the water without risking their health,” he says.

Can be used against other types of pollutants
Gunnar Westman also sees great opportunities to use cellulose nanocrystals for the treatment of other water pollutants than dyes. In a previous study, the research group has shown that pollutants of toxic hexavalent chromium, which is common in wastewater from mining, leather and metal industries, could be successfully removed with a similar type of cellulose-based material. The group is also exploring how the research area can contribute to the purification of antibiotic residues.

“There is great potential to find good water purification opportunities with this material, and in addition to the basic knowledge we have built up at Chalmers, an important key to success is the collective expertise available at the Wallenberg Wood Science Center,” he says.

More about the scientific article
Read the full article in Industrial & Engineering Chemistry Research: Cellulose nanocrystals derived from microcrystalline cellulose for selective removal of Janus Green Azo Dye. The authors of the article are Gunnar Westman and Amit Kumar Sonker of Chalmers University of Technology, and Ruchi Aggarwal, Anjali Kumari Garg, Deepika Saini, and Sumit Kumar Sonkar of Malaviya National Institute of Technology Jaipur in India. The research is funded by the Wallenberg Wood Science Center, WWSC and the Indian group research is funded by Science and Engineering Research Board under Department of Science and Technology (DST-SERB) Government of India. 

*Nanocrystals 
Nanocrystals are nanoparticles in crystal form that are extremely small: a nanoparticle is between 1 and 100 nanometres in at least one dimension, i.e. along one axis. (one nanometre = one billionth of a metre).

Wallenberg Wood Science Center
•    The Wallenberg Wood Science Center, WWSC, is a research centre that aims to develop new sustainable biobased materials using raw materials from the forest. The WWSC is a multidisciplinary collaboration between Chalmers University of Technology, KTH Royal Institute of Technology and Linköping University, and is based on a donation from the Knut and Alice Wallenberg Foundation.
•    The centre involves about 95 researchers and faculty members and 50 doctoral students. Eight research groups from Chalmers are part of the centre.

About dye pollutants and access to clean water
•    Over two billion people in the world live with limited or no access to clean water. It is estimated that over 3.5 million people die each year from lack of access to clean water and proper sanitation.
•    The global textile industry, which is concentrated in Asia, contributes to widespread water pollution. Production often takes place in low-wage countries, where much of the technology is antiquated and environmental legislation and oversight may be lacking.
•    Emissions contribute to eutrophication and toxic effects in water and soil. There are examples in China and India where groundwater has been contaminated by dye and processing chemicals.
•    Producing one kilogram of new textiles requires between 7,000 and 29,000 litres of water, and between 1.5 and 6.9 kg of chemicals.
•    In 2021, around 327 thousand tonnes of dyes and pigments were produced in India. A large proportion of the country’s dye pollutants is discharged untreated.

Sources 

Swedish Environmental Protection Agency: https://www.naturvardsverket.se/amnesomraden/textil/dagens-textila-floden-ar-en-global-miljoutmaning/ 

WHO: https://www.who.int/news-room/fact-sheets/detail/drinking-water

A critical review on the treatment of dye-containing wastewater: Ecotoxicological and health concerns of textile dyes and possible remediation approaches for environmental safety. Ecotoxicology and Environmental Safety, February 2022

https://www.sciencedirect.com/science/article/pii/S0147651321012720

Effects of textile dyes on health and the environment and bioremediation potential of living organisms. Biotechnology Research and Innovation, July–December 2019

https://www.sciencedirect.com/science/article/pii/S2452072119300413

Swedish Chemicals Agency: https://www.kemi.se/kemiska-amnen-och-material/nanomaterial

Statista: https://www.statista.com/statistics/726947/india-dyes-and-pigments-production-volume/#:~:text=In%20fiscal%20year%202021%2C%20the,around%20327%20thousand%20metric%20tons

Even though there’s a link to the research in the press release, here’s my link to and citation for the paper, which specifies a particular dye suggesting this is not a universal treatment,

Cellulose Nanocrystals Derived from Microcrystalline Cellulose for Selective Removal of Janus Green Azo Dye by Ruchi Aggarwal, Anjali Kumari Garg, Deepika Saini, Sumit Kumar Sonkar, Amit Kumar Sonker, and Gunnar Westman. Ind. Eng. Chem. Res. 2023, 62, 1, 649–659 DOI: https://doi.org/10.1021/acs.iecr.2c03365 Publication Date: December 26, 2022 Copyright © 2022 American Chemical Society

This paper is behind a paywall.

Sponge coated with nanoparticles removes lead from water

It doesn’t look like much but who cares when it does the job and is being made available commercially,

Caption: Commercially available cellulose sponge coated in manganese-doped goethite nanoparticles. Credit: Caroline Harms/Northwestern University

A May 11, 2023 news item on Nanowerk announces the research,

Northwestern University engineers have developed a new sponge that can remove metals — including toxic heavy metals like lead and critical metals like cobalt — from contaminated water, leaving safe, drinkable water behind.

In proof-of-concept experiments, the researchers tested their new sponge on a highly contaminated sample of tap water, containing more than 1 part per million of lead. With one use, the sponge filtered lead to below detectable levels.

After using the sponge, researchers also were able to successfully recover metals and reuse the sponge for multiple cycles. The new sponge shows promise for future use as an inexpensive, easy-to-use tool in home water filters or large-scale environmental remediation efforts.

A May 10, 2023 Northwestern University news release on EurekAlert (also received via email) provides more detail, Note: Links have been removed,

The study was published late yesterday (May 10 [2023]) in the journal ACS ES&T Water. The paper outlines the new research and sets design rules for optimizing similar platforms for removing — and recovering — other heavy-metal toxins, including cadmium, arsenic, cobalt and chromium.

“The presence of heavy metals in the water supply is an enormous public health challenge for the entire globe,” said Northwestern’s Vinayak Dravid, senior author of the study. “It is a gigaton problem that requires solutions that can be deployed easily, effectively and inexpensively. That’s where our sponge comes in. It can remove the pollution and then be used again and again.”

Dravid is the Abraham Harris Professor of Materials Science and Engineering at Northwestern’s McCormick School of Engineering and director of global initiatives at the International Institute for Nanotechnology.

Sopping up spills

The project builds on Dravid’s previous work to develop highly porous sponges for various aspects of environmental remediation. In May 2020, his team unveiled a new sponge designed to clean up oil spills. [Note: My June 25, 2020 posting highlights the work and includes an embedded video demonstration of the technology.] The nanoparticle-coated sponge, which is now being commercialized by Northwestern spinoff MFNS Tech, offers a more efficient, economic, ecofriendly and reusable alternative to current approaches to oil spills.

But Dravid knew it wasn’t enough.

“When there is an oil spill, you can remove the oil,” he said. “But there also are toxic heavy metals — like mercury, cadmium, sulfur and lead — in those spills. So, even when you remove the oil, some of the other toxins might remain.

Rinse and repeat

To tackle this aspect of the issue, Dravid’s team, again, turned to sponges coated with an ultrathin layer of nanoparticles. After testing many different types of nanoparticles, the team found that a manganese-doped goethite coating worked best. Not only are manganese-doped goethite nanoparticles inexpensive to make, easily available and nontoxic to human, they also have the properties necessary to selectively remediate heavy metals.

“You want a material with a high surface area, so there’s more room for the lead ions to stick to it,” said Benjamin Shindel, a Ph.D. student in Dravid’s lab and the paper’s first author. “These nanoparticles have high-surface areas and abundant reactive surface sites for adsorption and are stable, so they can be reused many times.”

The team synthesized slurries of manganese-doped goethite nanoparticles, as well as several other compositions of nanoparticles, and coated commercially available cellulose sponges with these slurries. Then, they rinsed the coated sponges with water in order to wash away any loose particles. The final coatings measured just tens of nanometers in thickness.

When submerged into contaminated water, the nanoparticle-coated sponge effectively sequested lead ions. The U.S. Food and Drug Administration requires that bottled drinking water is below 5 parts per billion of lead. In filtration trials, the sponge lowered the amount of lead to approximately 2 parts per billion, making it safe to drink.

“We’re really happy with that,” Shindel said. “Of course, this performance can vary based on several factors. For instance, if you have a large sponge in a tiny volume of water, it will perform better than a tiny sponge in a huge lake.”

Recovery bypasses mining

From there, the team rinsed the sponge with mildly acidified water, which Shindel likened to “having the same acidity of lemonade.” The acidic solution caused the sponge to release the lead ions and be ready for another use. Although the sponge’s performance declined after the first use, it still recovered more than 90% of the ions during subsequent use cycles.

This ability to gather and then recover heavy metals is particularly valuable for removing rare, critical metals, such as cobalt, from water sources. A common ingredient in lithium-ion batteries, cobalt is energetically expensive to mine and accompanied by a laundry list of environmental and human costs.

If researchers could develop a sponge that selectively removes rare metals, including cobalt, from water, then those metals could be recycled into products like batteries.

“For renewable energy technologies, like batteries and fuel cells, there is a need for metal recovery,” Dravid said. “Otherwise, there is not enough cobalt in the world for the growing number of batteries. We must find ways to recover metals from very dilute solutions. Otherwise, it becomes poisonous and toxic, just sitting there in the water. We might as well make something valuable with it.”

Standardized scale

As a part of the study, Dravid and his team set new design rules to help others develop tools to target particular metals, including cobalt. Specifically, they pinpointed which low-cost and nontoxic nanoparticles also have high-surface areas and affinities for sticking to metal ions. They studied the performance of coatings of manganese, iron, aluminum and zinc oxides on lead adsorption. Then, they established relationships between the structures of these nanoparticles and their adsorptive properties.

Called Nanomaterial Sponge Coatings for Heavy Metals (or “Nano-SCHeMe”), the environmental remediation platform can help other researchers differentiate which nanomaterials are best suited for particular applications.

“I’ve read a lot of literature that compares different coatings and adsorbents,” said Caroline Harms, an undergraduate student in Dravid’s lab and paper co-author. “There really is a lack of standardization in the field. By analyzing different types of nanoparticles, we developed a comparative scale that actually works for all of them. It could have a lot of implications in moving the field forward.”

Dravid and his team imagine that their sponge could be used in commercial water filters, for environmental clean-up or as an added step in water reclamation and treatment facilities.

“This work may be pertinent to water quality issues both locally and globally,” Shindel said. “We want to see this out in the world, where it can make a real impact.”

The study, “Nano-SCHeME: Nanomaterial Sponge Coatings for Heavy Metals, an environmental remediation platform,” was supported by the National Science Foundation and U.S. Department of Energy.

Editor’s note: Dravid and Northwestern have financial interests (equities, royalties) in MFNS Tech.

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

Nano-SCHeme: Nanomaterial Sponge Coatings for Heavy Metals, an Environmental Remediation Platform by Benjamin Shindel, Stephanie M. Ribet, Caroline Harms, Vikas Nandwana, and Vinayak P. Dravid. ACS EST Water 2023, XXXX, XXX, XXX-XXX DOI: https://doi.org/10.1021/acsestwater.2c00646 Publication Date:May 10, 2023 © 2023 American Chemical Society

This paper is behind a paywall.

You can find the MFNS Tech website here.

Greener cellulose-based products

A May 3, 2023 North Carolina State University news release (also on EurekAlert) describes research into making more environmentally friendly products based on cellulose, Note: A link has been removed,

Water isn’t just a universal solvent that remains unaffected by its interactions. New publications from North Carolina State University show that water can change its solubility characteristics depending upon what it interacts with. Specifically, when water interacts with cellulose, it can stack in layered shells to control chemical reactions within, and physical properties of, the material. The work has implications for more sustainable and efficient design of cellulose-based products.

“Cellulose is the world’s most abundant biopolymer, and it’s used in applications that range from bandages to electronics,” says Lucian Lucia, professor of forest biomaterials and chemistry at NC State and corresponding author of a new study in Matter. “But cellulose processing has been mostly done by trial and error, and some of it utilizes incredibly harsh chemicals. To find better ways to process cellulose, we need to understand its most fundamental interactions – for example, with water.”

To do so, he worked with colleague Jim Martin, professor of chemistry at NC State, who studies the fundamental properties of water as a solvent.

“Water has the uncanny ability to change characteristics depending on what it’s with, which gives it wide range of solubility characteristics,” Martin says. Martin is the author of an opinion piece in Matter that is a companion to Lucia’s study.

“We change the nature of water by what we dissolve in it, and by the concentrations of those solutes in water,” Martin says. “Think of the continuum between Kool-Aid and hard candy. You start with sugar. In Kool-Aid the sugar is completely dissolved. As you remove the water, you get taffy, then hard candy, then back to crystalline sugar.”

“We know that water is critical to how cellulose is laid down,” Lucia says. “So in this study we probed how it orients itself and plays a reactive role in mitigating or leveraging chemistry.”

The researchers physically manipulated different types of wood fibers and looked at how water bound to itself and other molecules within the resulting structures. They saw that at lower water contents, the water distribution and resulting molecular interactions between the water and the fibers create bridging structures within the material that cause it to lose flexibility.

In fact, they saw that the water can “hide” itself within the cellulose network, forming strong hydrogen bonds. This bonding in turn dictates the tightness or looseness of the bridging structures.

“The water forms shells around the fibers that can stack, like a nesting Russian doll,” Martin says. “The fewer shells, or layers, the harder the fibers. But when you add more layers, the connection between fibers grows farther away and the material becomes softer.”

The researchers hope to explore the variety of bonds water forms within these structures in future work.

“Studying these interactions at the molecular level paves the way toward manipulating water in cellulose to design better products and processes,” Lucian says. “Understanding what is happening from fundamental principles lets us design approaches that take advantage of water’s properties for everything from drug delivery to designing electronics.”

The research paper, “Computational and experimental insights into the molecular architecture of water-cellulose networks,” and the editorial piece, “Water under the influence of solutes: on the non-innocence of a universal solvent,” both appear in the May 3 edition of Matter. The work was supported in part by the National Science Foundation. Former NC State Ph.D. student Kandoker Samaher Salem is first author of the research paper. Co-authors include former NC State Ph.D. student Nelson Barrios, and current NC State faculty Hasan Jameel and Lokendra Pal.

Here are links and citations for the two papers in the news release with the research paper coming first and the editorial coming second,

Computational and experimental insights into the molecular architecture of water-cellulose networks by Khandoker Samaher Salem, Nelson Barrios, Hasan Jameel, Lokendra Pal, Lucian Lucia. Matter Matter Volume 6, Issue 5, 3 May 2023, Pages 1366-1381 DOI: https://doi.org/10.1016/j.matt.2023.03.021

Water under the influence of solutes: On the non-innocence of a universal solvent by James D. Martin. Matter Volume 6, Issue 5, 3 May 2023, Pages 1316-1319 https://doi.org/10.1016/j.matt.2023.03.020

Both research paper and editorial are behind paywalls.

The 2023 Canadian federal budget: science & technology of health, the clean economy, reconciliation, and more (1 of 2)

The Canadian federal government released its 2023 budget on Tuesday, March 28, 2023. There were no flashy science research announcements in the budget. Trudeau and his team like to trumpet science initiatives and grand plans (even if they’re reannouncing something from a previous budget) but like last year—this year—not so much.

Consequently, this posting about the annual federal budget should have been shorter than usual. What happened?

Partly, it’s the military spending (chapter 5 of the budget in part 2 of this 2023 budget post). For those who are unfamiliar with the link between military scientific research and their impact on the general population, there are a number of inventions and innovations directly due to military research, e.g., plastic surgery, television, and the internet. (You can check a November 6, 2018 essay for The Conversation by Robert Kirby, Professor of Clinical Education and Surgery at Keele University, for more about the impact of World War 1 and medical research, “World War I: the birth of plastic surgery and modern anaesthesia.”)

So, there’s a lot to be found by inference. Consequently, I found Chapter 3 to also be unexpectedly rich in science and technology efforts.

Throughout both parts of this 2023 Canadian federal budget post, you will find excerpts from individual chapters of the federal budget followed my commentary directly after. My general commentary is reserved for the end.

Sometimes, I have included an item because it piqued my interest. E.g., Canadian agriculture is dependent on Russian fertilizer!!! News to me and I imagine many others. BTW, this budget aims to wean us from this dependency.

Chapter 2: Investing in Public Health Care and Affordable Dental Care

Here goes: from https://www.budget.canada.ca/2023/report-rapport/toc-tdm-en.html,

2.1 Investing in Public Health Care

Improving Canada’s Readiness for Health Emergencies

Vaccines and other cutting-edge life-science innovations have helped us to take control of the COVID-19 pandemic. To support these efforts, the federal government has committed significant funding towards the revitalization of Canada’s biomanufacturing sector through a Biomanufacturing and Life Sciences Strategy [emphasis mine]. To date, the government has invested more than $1.8 billion in 32 vaccine, therapeutic, and biomanufacturing projects across Canada, alongside $127 million for upgrades to specialized labs at universities across the country. Canada is building a life sciences ecosystem that is attracting major investments from leading global companies, including Moderna, AstraZeneca, and Sanofi.

To build upon the progress of the past three years, the government will explore new ways to be more efficient and effective in the development and production of the vaccines, therapies, and diagnostic tools that would be required for future health emergencies. As a first step, the government will further consult Canadian and international experts on how to best organize our readiness efforts for years to come. …

Gold rush in them thar life sciences

I have covered the rush to capitalize on Canadian life sciences research (with a special emphasis on British Columbia) in various posts including (amongst others): my December 30, 2020 posting “Avo Media, Science Telephone, and a Canadian COVID-19 billionaire scientist,” and my August 23, 2021 posting “Who’s running the life science companies’ public relations campaign in British Columbia (Vancouver, Canada)?” There’s also my August 20, 2021 posting “Getting erased from the mRNA/COVID-19 story,” highlighting how brutal the competition amongst these Canadian researchers can be.

Getting back to the 2023 budget, ‘The Biomanufacturing and Life Sciences Strategy’ mentioned in this latest budget was announced in a July 28, 2021 Innovation, Science and Economic Development Canada news release. You can find the strategy here and an overview of the strategy here. You may want to check out the overview as it features links to,

What We Heard Report: Results of the consultation on biomanufacturing and life sciences capacity in Canada

Ontario’s Strategy: Taking life sciences to the next level

Quebec’s Strategy: 2022–2025 Québec Life Sciences Strategy

Nova Scotia’s Strategy: BioFuture2030 Prince Edward Island’s Strategy:

The Prince Edward Island Bioscience Cluster [emphases mine]

2022 saw one government announcement concerning the strategy, from a March 3, 2022 Innovation, Science and Economic Development Canada news release, Note: Links have been removed,

Protecting the health and safety of Canadians and making sure we have the domestic capacity to respond to future health crises are top priorities of the Government of Canada. With the guidance of Canada’s Biomanufacturing and Life Sciences Strategy, the government is actively supporting the growth of a strong, competitive domestic life sciences sector, with cutting-edge biomanufacturing capabilities.

Today [March 3, 2022], the Honourable François-Philippe Champagne, Minister of Innovation, Science and Industry, announced a $92 million investment in adMare BioInnovations to drive company innovation, scale-up and training activities in Canada’s life sciences sector. This investment will help translate commercially promising health research into innovative new therapies and will see Canadian anchor companies provide the training required and drive the growth of Canada’s life science companies.

The real action took place earlier this month (March 2023) just prior to the budget. Oddly, I can’t find any mention of these initiatives in the budget document. (Confession: I have not given the 2023 budget a close reading although I have been through the whole budget once and viewed individual chapters more closely a few times.)

This March 2, 2023 (?) Tri-agency Institutional Programs Secretariat news release kicked things off, Note 1: I found the date at the bottom of their webpage; Note 2: Links have been removed,

The Government of Canada’s main priority continues to be protecting the health and safety of Canadians. Throughout the pandemic, the quick and decisive actions taken by the government meant that Canada was able to scale up domestic biomanufacturing capacity, which had been in decline for over 40 years. Since then, the government is rebuilding a strong and competitive biomanufacturing and life sciences sector brick by brick. This includes strengthening the foundations of the life sciences ecosystem through the research and talent of Canada’s world-class postsecondary institutions and research hospitals, as well as fostering increased collaboration with innovative companies.

Today [March 2, 2023?], the Honourable François-Philippe Champagne, Minister of Innovation, Science and Industry, and the Honourable Jean-Yves Duclos, Minister of Health, announced an investment of $10 million in support of the creation of five research hubs [emphasis mine]:

  • CBRF PRAIRIE Hub, led by the University of Alberta
  • Canada’s Immuno-Engineering and Biomanufacturing Hub, led by The University of British Columbia
  • Eastern Canada Pandemic Preparedness Hub, led by the Université de Montréal
  • Canadian Pandemic Preparedness Hub, led by the University of Ottawa and McMaster University
  • Canadian Hub for Health Intelligence & Innovation in Infectious Diseases, led by the University of Toronto

This investment, made through Stage 1 of the integrated Canada Biomedical Research Fund (CBRF) and Biosciences Research Infrastructure Fund (BRIF) competition, will bolster research and talent development efforts led by the institutions, working in collaboration with their partners. The hubs combine the strengths of academia, industry and the public and not-for-profit sectors to jointly improve pandemic readiness and the overall health and well-being of Canadians.

The multidisciplinary research hubs will accelerate the research and development of next-generation vaccines and therapeutics and diagnostics, while supporting training and development to expand the pipeline of skilled talent. The hubs will also accelerate the translation of promising research into commercially viable products and processes. This investment helps to strengthen the resilience of Canada’s life sciences sector by supporting leading Canadian research in innovative technologies that keep us safe and boost our economy.

Today’s [March 2, 2023?] announcement also launched Stage 2 of the CBRF-BRIF competition. This is a national competition that includes $570 million in available funding for proposals, aimed at cutting-edge research, talent development and research infrastructure projects associated with the selected research hubs. By strengthening research and talent capacity and leveraging collaborations across the entire biomanufacturing ecosystem, Canada will be better prepared to face future pandemics, in order to protect Canadian’s health and safety. 

Then, the Innovation, Science and Economic Development Canada’s March 9, 2023 news release made this announcement, Note: Links have been removed,

Since March 2020, major achievements have been made to rebuild a vibrant domestic life sciences ecosystem to protect Canadians against future health threats. The growth of the sector is a top priority for the Government of Canada, and with over $1.8 billion committed to 33 projects to boost our domestic biomanufacturing, vaccine and therapeutics capacity, we are strengthening our resiliency for current health emergencies and our readiness for future ones.

The COVID-19 Vaccine Task Force played a critical role in guiding and supporting the Government of Canada’s COVID-19 vaccine response. Today [March 9, 2023], recognizing the importance of science-based decisions, the Honourable François-Philippe Champagne, Minister of Innovation, Science and Industry, and the Honourable Jean-Yves Duclos, Minister of Health, are pleased to announce the creation of the Council of Expert Advisors (CEA). The 14 members of the CEA, who held their first official meeting earlier this week, will advise the Government of Canada on the long-term, sustainable growth of Canada’s biomanufacturing and life sciences sector, and on how to enhance our preparedness and capacity to protect the health and safety of Canadians.

The membership of the CEA comprises leaders with in-depth scientific, industrial, academic and public health expertise. The CEA co-chairs are Joanne Langley, Professor of Pediatrics and of Community Health and Epidemiology at the Dalhousie University Faculty of Medicine, and Division Head of Infectious Diseases at the IWK Health Centre; and Marco Marra, Professor in Medical Genetics at the University of British Columbia (UBC), UBC Canada Research Chair in Genome Science and distinguished scientist at the BC Cancer Foundation.

The CEA’s first meeting focused on the previous steps taken under Canada’s Biomanufacturing and Life Sciences Strategy and on its path forward. The creation of the CEA is an important milestone in the strategy, as it continues to evolve and adapt to new technologies and changing conditions in the marketplace and life sciences ecosystem. The CEA will also inform on investments that enhance capacity across Canada to support end-to-end production of critical vaccines, therapeutics and essential medical countermeasures, and to ensure that Canadians can reap the full economic benefits of the innovations developed, including well-paying jobs.

As I’m from British Columbia, I’m highlighting this University of British Columbia (UBC) March 17, 2023 news release about their involvement, Note: Links have been removed,

Canada’s biotech ecosystem is poised for a major boost with the federal government announcement today that B.C. will be home to Canada’s Immuno-Engineering and Biomanufacturing Hub (CIEBH).

The B.C.-based research and innovation hub, led by UBC, brings together a coalition of provincial, national and international partners to position Canada as a global epicentre for the development and manufacturing of next-generation immune-based therapeutics.

A primary goal of CIEBH is to establish a seamless drug development pipeline that will enable Canada to respond to future pandemics and other health challenges in fewer than 100 days.

This hub will build on the strengths of B.C.’s biotech and life sciences industry, and those of our national and global partners, to make Canada a world leader in the development of lifesaving medicines,” said Dr. Deborah Buszard, interim president and vice-chancellor of UBC. “It’s about creating a healthier future for all Canadians. Together with our outstanding alliance of partners, we will ensure Canada is prepared to respond rapidly to future health challenges with homegrown solutions.”

CIEBH is one of five new research hubs announced by the federal government that will work together to improve pandemic readiness and the overall health and well-being of Canadians. Federal funding of $570 million is available over the next four years to support project proposals associated with these hubs in order to advance Canada’s Biomanufacturing and Life Sciences Strategy.

More than 50 organizations representing the private, public, not-for-profit and academic sectors have come together to form the hub, creating a rich environment that will bolster biomedical innovation in Canada. Among these partners are leading B.C. biotech companies that played a key role in Canada’s COVID-19 pandemic response and are developing cutting-edge treatments for a range of human diseases.

CIEBH, led by UBC, will further align the critical mass of biomedical research strengths concentrated at B.C. academic institutions, including the B.C. Institute of Technology, Simon Fraser University and the University of Victoria, as well as the clinical expertise of B.C. research hospitals and health authorities. With linkages to key partners across Canada, including Dalhousie University, the University of Waterloo, and the Vaccine and Infectious Disease Organization, the hub will create a national network to address gaps in Canada’s drug development pipeline.

In recent decades, B.C. has emerged as a global leader in immuno-engineering, a field that is transforming how society treats disease by harnessing and modulating the immune system.

B.C. academic institutions and prominent Canadian companies like Precision NanoSystems, Acuitas Therapeutics and AbCellera have developed significant expertise in advanced immune-based therapeutics such as lipid nanoparticle- and mRNA-based vaccines, engineered antibodies, cell therapies and treatments for antimicrobial resistant infections. UBC professor Dr. Pieter Cullis, a member of CIEBH’s core scientific team, has been widely recognized for his pioneering work developing the lipid nanoparticle delivery technology that enables mRNA therapeutics such as the highly effective COVID-19 mRNA vaccines.

As noted previously, I’m a little puzzled that the federal government didn’t mention the investment in these hubs in their budget. They usually trumpet these kinds of initiatives.

On a related track, I’m even more puzzled that the province of British Columbia does not have its own life sciences research strategy in light of that sector’s success. Certainly it seems that Ontario, Quebec, Nova Scotia, and Prince Edward are all eager to get a piece of the action. Still, there is a Life Sciences in British Columbia: Sector Profile dated June 2020 and an undated (likely from some time between July 2017 to January 2020 when Bruce Ralston whose name is on the document was the relevant cabinet minister) British Columbia Technology and Innovation Policy Framework.

In case you missed the link earlier, see my August 23, 2021 posting “Who’s running the life science companies’ public relations campaign in British Columbia (Vancouver, Canada)?” which includes additional information about the BC life sciences sector, federal and provincial funding, the City of Vancouver’s involvement, and other related matters.

Chapter 3: A Made-In-Canada Plan: Affordable Energy, Good Jobs, and a Growing Clean Economy

The most science-focused information is in Chapter 3, from https://www.budget.canada.ca/2023/report-rapport/toc-tdm-en.html,

3.2 A Growing, Clean Economy

More than US$100 trillion in private capital is projected to be spent between now and 2050 to build the global clean economy.

Canada is currently competing with the United States, the European Union, and countries around the world for our share of this investment. To secure our share of this global investment, we must capitalize on Canada’s competitive advantages, including our skilled and diverse workforce, and our abundance of critical resources that the world needs.

The federal government has taken significant action over the past seven years to support Canada’s net-zero economic future. To build on this progress and support the growth of Canada’s clean economy, Budget 2023 proposes a range of measures that will encourage businesses to invest in Canada and create good-paying jobs for Canadian workers.

This made-in-Canada plan follows the federal tiered structure to incent the development of Canada’s clean economy and provide additional support for projects that need it. This plan includes:

  • Clear and predictable investment tax credits to provide foundational support for clean technology manufacturing, clean hydrogen, zero-emission technologies, and carbon capture and storage;
  • The deployment of financial instruments through the Canada Growth Fund, such as contracts for difference, to absorb certain risks and encourage private sector investment in low-carbon projects, technologies, businesses, and supply chains; and,
  • Targeted clean technology and sector supports delivered by Innovation, Science and Economic Development Canada to support battery manufacturing and further advance the development, application, and manufacturing of clean technologies.

Canada’s Potential in Critical Minerals

As a global leader in mining, Canada is in a prime position to provide a stable resource base for critical minerals [emphasis mine] that are central to major global industries such as clean technology, auto manufacturing, health care, aerospace, and the digital economy. For nickel and copper alone, the known reserves in Canada are more than 10 million tonnes, with many other potential sources at the exploration stage.

The Buy North American provisions for critical minerals and electric vehicles in the U.S. Inflation Reduction Act will create opportunities for Canada. In particular, U.S. acceleration of clean technology manufacturing will require robust supply chains of critical minerals that Canada has in abundance. However, to fully unleash Canada’s potential in critical minerals, we need to ensure a framework is in place to accelerate private investment.

Budget 2022 committed $3.8 billion for Canada’s Critical Minerals Strategy to provide foundational support to Canada’s mining sector to take advantage of these new opportunities. The Strategy was published in December 2022.

On March 24, 2023, the government launched the Critical Minerals Infrastructure Fund [emphasis mine; I cannot find a government announcement/news release for this fund]—a new fund announced in Budget 2022 that will allocate $1.5 billion towards energy and transportation projects needed to unlock priority mineral deposits. The new fund will complement other clean energy and transportation supports, such as the Canada Infrastructure Bank and the National Trade Corridors Fund, as well as other federal programs that invest in critical minerals projects, such as the Strategic Innovation Fund.

The new Investment Tax Credit for Clean Technology Manufacturing proposed in Budget 2023 will also provide a significant incentive to boost private investment in Canadian critical minerals projects and create new opportunities and middle class jobs in communities across the country.

An Investment Tax Credit for Clean Technology Manufacturing

Supporting Canadian companies in the manufacturing and processing of clean technologies, and in the extraction and processing of critical minerals, will create good middle class jobs for Canadians, ensure our businesses remain competitive in major global industries, and support the supply chains of our allies around the world.

While the Clean Technology Investment Tax Credit, first announced in Budget 2022, will provide support to Canadian companies adopting clean technologies, the Clean Technology Manufacturing Investment Tax Credit will provide support to Canadian companies that are manufacturing or processing clean technologies and their precursors.

  • Budget 2023 proposes a refundable tax credit equal to 30 per cent of the cost of investments in new machinery and equipment used to manufacture or process key clean technologies, and extract, process, or recycle key critical minerals, including:
    • Extraction, processing, or recycling of critical minerals essential for clean technology supply chains, specifically: lithium, cobalt, nickel, graphite, copper, and rare earth elements;
    • Manufacturing of renewable or nuclear energy equipment;
    • Processing or recycling of nuclear fuels and heavy water; [emphases mine]
    • Manufacturing of grid-scale electrical energy storage equipment;
    • Manufacturing of zero-emission vehicles; and,
    • Manufacturing or processing of certain upstream components and materials for the above activities, such as cathode materials and batteries used in electric vehicles.

The investment tax credit is expected to cost $4.5 billion over five years, starting in 2023-24, and an additional $6.6 billion from 2028-29 to 2034-35. The credit would apply to property that is acquired and becomes available for use on or after January 1, 2024, and would no longer be in effect after 2034, subject to a phase-out starting in 2032.

3.4 Reliable Transportation and Resilient Infrastructure

Supporting Resilient Infrastructure Through Innovation

The Smart Cities Challenge [emphasis mine] was launched in 2017 to encourage cities to adopt new and innovative approaches to improve the quality of life for their residents. The first round of the Challenge resulted in $75 million in prizes across four winning applicants: Montreal, Quebec; Guelph, Ontario; communities of Nunavut; and Bridgewater, Nova Scotia.

New and innovative solutions are required to help communities reduce the risks and impacts posed by weather-related events and disasters triggered by climate change. To help address this issue, the government will be launching a new round of the Smart Cities Challenge later this year, which will focus on using connected technologies, data, and innovative approaches to improve climate resiliency.

3.5 Investing in Tomorrow’s Technology

With the best-educated workforce on earth, world-class academic and research institutions, and robust start-up ecosystems across the country, Canada’s economy is fast becoming a global technology leader – building on its strengths in areas like artificial intelligence. Canada is already home to some of the top markets for high-tech careers in North America, including the three fastest growing markets between 2016 and 2021: Vancouver, Toronto, and Quebec City.

However, more can be done to help the Canadian economy reach its full potential. Reversing a longstanding trend of underinvestment in research and development by Canadian business [emphasis mine] is essential our long-term economic growth.

Budget 2023 proposes new measures to encourage business innovation in Canada, as well as new investments in college research and the forestry industry that will help to build a stronger and more innovative Canadian economy.

Attracting High-Tech Investment to Canada

In recent months, Canada has attracted several new digital and high-tech projects that will support our innovative economy, including:

  • Nokia: a $340 million project that will strengthen Canada’s position as a leader in 5G and digital innovation;
  • Xanadu Quantum Technologies: a $178 million project that will support Canada’s leadership in quantum computing;
  • Sanctuary Cognitive Systems Corporation: a $121 million project that will boost Canada’s leadership in the global Artificial Intelligence market; and,
  • EXFO: a $77 million project to create a 5G Centre of Excellence that aims to develop one of the world’s first Artificial Intelligence-based automated network solutions.

Review of the Scientific Research and Experimental Development Tax Incentive Program

The Scientific Research and Experimental Development (SR&ED) tax incentive program continues to be a cornerstone of Canada’s innovation strategy by supporting research and development with the goal of encouraging Canadian businesses of all sizes to invest in innovation that drives economic growth.

In Budget 2022, the federal government announced its intention to review the SR&ED program to ensure it is providing adequate support and improving the development, retention, and commercialization of intellectual property, including the consideration of adopting a patent box regime. [emphasis mine] The Department of Finance will continue to engage with stakeholders on the next steps in the coming months.

Modernizing Canada’s Research Ecosystem

Canada’s research community and world-class researchers solve some of the world’s toughest problems, and Canada’s spending on higher education research and development, as a share of GDP, has exceeded all other G7 countries. 

Since 2016, the federal government has committed more than $16 billion of additional funding to support research and science across Canada. This includes:

  • Nearly $4 billion in Budget 2018 for Canada’s research system, including $2.4 billion for the Canada Foundation for Innovation and the granting councils—the Natural Sciences and Engineering Research Council of Canada, the Social Sciences and Humanities Research Council of Canada and the Canadian Institutes of Health Research; [emphases mine]
  • More than $500 million in Budget 2019 in total additional support to third-party research and science organizations, in addition to the creation of the Strategic Science Fund, which will announce successful recipients later this year;
  • $1.2 billion in Budget 2021 for Pan-Canadian Genomics and Artificial Intelligence Strategies, and a National Quantum Strategy;
  • $1 billion in Budget 2021 to the granting councils and the Canada Foundation for Innovation for life sciences researchers and infrastructure; and,
  • The January 2023 announcement of Canada’s intention to become a full member in the Square Kilometre Array Observatory, which will provide Canadian astronomers with access to its ground-breaking data. The government is providing up to $269.3 million to support this collaboration.

In order to maintain Canada’s research strength—and the knowledge, innovations, and talent it fosters—our systems to support science and research must evolve. The government has been consulting with stakeholders, including through the independent Advisory Panel on the Federal Research Support System, to seek advice from research leaders on how to further strengthen Canada’s research support system.

The government is carefully considering the Advisory Panel’s advice, with more detail to follow in the coming months on further efforts to modernize the system.

Using College Research to Help Businesses Grow

Canada’s colleges, CEGEPs, and polytechnic institutes use their facilities, equipment, and expertise to solve applied research problems every day. Students at these institutions are developing the skills they need to start good careers when they leave school, and by partnering with these institutions, businesses can access the talent and the tools they need to innovate and grow.

  • To help more Canadian businesses access the expertise and research and development facilities they need, Budget 2023 proposes to provide $108.6 million over three years, starting in 2023-24, to expand the College and Community Innovation Program, administered by the Natural Sciences and Engineering Research Council.

Supporting Canadian Leadership in Space

For decades, Canada’s participation in the International Space Station has helped to fuel important scientific advances, and showcased Canada’s ability to create leading-edge space technologies, such as Canadarm2. Canadian space technologies have inspired advances in other fields, such as the NeuroArm, the world’s first robot capable of operating inside an MRI, making previously impossible surgeries possible.

  • Budget 2023 proposes to provide $1.1 billion [emphasis mine] over 14 years, starting in 2023-24, on a cash basis, to the Canadian Space Agency [emphasis mine] to continue Canada’s participation in the International Space Station until 2030.

Looking forward, humanity is returning to the moon [emphasis mine]. Canada intends to join these efforts by contributing a robotic lunar utility vehicle to perform key activities in support of human lunar exploration. Canadian participation in the NASA-led Lunar Gateway station—a space station that will orbit the moon—also presents new opportunities for innovative advances in science and technology. Canada is providing Canadarm3 to the Lunar Gateway, and a Canadian astronaut will join Artemis II, the first crewed mission to the moon since 1972. In Budget 2023, the government is providing further support to assist these missions.

  • Budget 2023 proposes to provide $1.2 billion [emphasis mine] over 13 years, starting in 2024-25, to the Canadian Space Agency to develop and contribute a lunar utility vehicle to assist astronauts on the moon.
  • Budget 2023 proposes to provide $150 million [emphasis mine[ over five years, starting in 2023-24, to the Canadian Space Agency for the next phase of the Lunar Exploration Accelerator Program to support the Canada’s world-class space industry and help accelerate the development of new technologies.
  • Budget 2023 also proposes to provide $76.5 million [emphasis mine] over eight years, starting in 2023-24, on a cash basis, to the Canadian Space Agency in support of Canadian science on the Lunar Gateway station.

Investing in Canada’s Forest Economy

The forestry sector plays an important role in Canada’s natural resource economy [emphasis mine], and is a source of good careers in many rural communities across Canada, including Indigenous communities. As global demand for sustainable forest products grows, continued support for Canada’s forestry sector will help it innovate, grow, and support good middle class jobs for Canadians.

  • Budget 2023 proposes to provide $368.4 million over three years, starting in 2023-24, with $3.1 million in remaining amortization, to Natural Resources Canada to renew and update forest sector support, including for research and development, Indigenous and international leadership, and data. Of this amount, $30.1 million would be sourced from existing departmental resources.

Establishing the Dairy Innovation and Investment Fund

The dairy sector is facing a growing surplus of solids non-fat (SNF) [emphasis mine], a by-product of dairy processing. Limited processing capacity for SNF results in lost opportunities for dairy processors and farmers.

  • Budget 2023 proposes to provide $333 million over ten years, starting in 2023-24, for Agriculture and Agri-Food Canada to support investments in research and development of new products based on SNF, market development for these products, and processing capacity for SNF-based products more broadly.

Supporting Farmers for Diversifying Away from Russian Fertilizers

Russia’s illegal invasion of Ukraine has resulted in higher prices for nitrogen fertilizers, which has had a notable impact on Eastern Canadian farmers who rely heavily on imported fertilizer.

  • Budget 2023 proposes to provide $34.1 million over three years, starting in 2023-24, to Agriculture and Agri-Food Canada’s On-Farm Climate Action Fund to support adoption of nitrogen management practices by Eastern Canadian farmers, that will help optimize the use and reduce the need for fertilizer.

Providing Interest Relief for Agricultural Producers

Farm production costs have increased in Canada and around the world, including as a result Russia’s illegal invasion of Ukraine and global supply chain disruptions. It is important that Canada’s agricultural producers have access to the cash flow they need to cover these costs until they sell their products.

  • Budget 2023 proposes to provide $13 million in 2023-24 to Agriculture and Agri-Food Canada to increase the interest-free limit for loans under the Advance Payments Program from $250,000 to $350,000 for the 2023 program year.

Additionally, the government will consult with provincial and territorial counterparts to explore ways to extend help to small agricultural producers who demonstrate urgent financial need.

Maintaining Livestock Sector Exports with a Foot-and-Mouth Disease Vaccine Bank

Foot-and-Mouth Disease (FMD) is a highly transmissible illness that can affect cattle, pigs, and other cloven-hoofed animals. Recent outbreaks in Asia and Africa have increased the risk of global spread, and a FMD outbreak in Canada would cut off exports for all livestock sectors, with major economic implications. However, the impact of a potential outbreak would be significantly reduced with the early vaccination of livestock. 

  • Budget 2023 proposes to provide $57.5 million over five years, starting in 2023-24, with $5.6 million ongoing, to the Canadian Food Inspection Agency to establish a FMD vaccine bank for Canada, and to develop FMD response plans. The government will seek a cost-sharing arrangement with provinces and territories.

Canadian economic theory (the staples theory), mining, nuclear energy, quantum science, and more

Critical minerals are getting a lot of attention these days. (They were featured in the 2022 budget, see my April 19, 2022 posting, scroll down to the Mining subhead.) This year, US President Joe Biden, in his first visit to Canada as President, singled out critical minerals at the end of his 28 hour state visit (from a March 24, 2023 CBC news online article by Alexander Panetta; Note: Links have been removed),

There was a pot of gold at the end of President Joe Biden’s jaunt to Canada. It’s going to Canada’s mining sector.

The U.S. military will deliver funds this spring to critical minerals projects in both the U.S. and Canada. The goal is to accelerate the development of a critical minerals industry on this continent.

The context is the United States’ intensifying rivalry with China.

The U.S. is desperate to reduce its reliance on its adversary for materials needed to power electric vehicles, electronics and many other products, and has set aside hundreds of millions of dollars under a program called the Defence Production Act.

The Pentagon already has told Canadian companies they would be eligible to apply. It has said the cash would arrive as grants, not loans.

On Friday [March 24, 2023], before Biden left Ottawa, he promised they’ll get some.

The White House and the Prime Minister’s Office announced that companies from both countries will be eligible this spring for money from a $250 million US fund.

Which Canadian companies? The leaders didn’t say. Canadian officials have provided the U.S. with a list of at least 70 projects that could warrant U.S. funding.

“Our nations are blessed with incredible natural resources,” Biden told Canadian parliamentarians during his speech in the House of Commons.

Canada in particular has large quantities of critical minerals [emphasis mine] that are essential for our clean energy future, for the world’s clean energy future.

I don’t believe that Joe Biden has ever heard of the Canadian academic Harold Innis (neither have most Canadians) but Biden is echoing a rather well known theory, in some circles, about Canada’s economy (from the Harold Innis Wikipedia entry),

Harold Adams Innis FRSC (November 5, 1894 – November 9, 1952) was a Canadian professor of political economy at the University of Toronto and the author of seminal works on media, communication theory, and Canadian economic history. He helped develop the staples thesis, which holds that Canada’s culture, political history, and economy have been decisively influenced by the exploitation and export of a series of “staples” such as fur, fish, lumber, wheat, mined metals, and coal. The staple thesis dominated economic history in Canada from the 1930s to 1960s, and continues to be a fundamental part of the Canadian political economic tradition.[8] [all emphases mine]

The staples theory is referred to informally as “hewers of wood and drawers of water.”

Critical Minerals Infrastructure Fund

I cannot find an announcement for this fund (perhaps it’s a US government fund?) but there is a March 7, 2023 Natural Resources Canada news release, Note: A link has been removed,

Simply put, our future depends on critical minerals. The Government of Canada is committed to investing in this future, which is why the Canadian Critical Minerals Strategy — launched by the Honourable Jonathan Wilkinson, Minister of Natural Resources, in December 2022 — is backed by up to $3.8 billion in federal funding. [emphases mine] Today [March 7, 2023], Minister Wilkinson announced more details on the implementation of this Strategy. Over $344 million in funding is supporting the following five new programs and initiatives:

  • Critical Minerals Technology and Innovation Program – $144.4 million for the research, development, demonstration, commercialization and adoption of new technologies and processes that support sustainable growth in Canadian critical minerals value chains and associated innovation ecosystems. 
  • Critical Minerals Geoscience and Data Initiative – $79.2 million to enhance the quality and availability of data and digital technologies to support geoscience and mapping that will accelerate the efficient and effective development of Canadian critical minerals value chains, including by identifying critical minerals reserves and developing pathways for sustainable mineral development. 
  • Global Partnerships Program – $70 million to strengthen Canada’s global leadership role in enhancing critical minerals supply chain resiliency through international collaborations related to critical minerals. 
  • Northern Regulatory Initiative – $40 million to advance Canada’s northern and territorial critical minerals agenda by supporting regulatory dialogue, regional studies, land-use planning, impact assessments and Indigenous consultation.
  • Renewal of the Critical Minerals Centre of Excellence (CMCE) – $10.6 million so the CMCE can continue the ongoing development and implementation of the Canadian Critical Minerals Strategy.

Commentary from the mining community

Mariaan Webb wrote a March 29,2023 article about the budget and the response from the mining community for miningweekly.com, Note: Links have been removed,

The 2023 Budget, delivered by Finance Minister Chrystia Freeland on Tuesday, bolsters the ability of the Canadian mining sector to deliver for the country, recognising the industry’s central role in enabling the transition to a net-zero economy, says Mining Association of Canada (MAC) president and CEO Pierre Gratton.

“Without mining, there are no electric vehicles, no clean power from wind farms, solar panels or nuclear energy, [emphasis mine] and no transmission lines,” said Gratton.

What kind of nuclear energy?

There are two kinds of nuclear energy: fission and fusion. (Fission is the one where the atom is split and requires minerals. Fusion energy is how stars are formed. Much less polluting than fission energy, at this time it is not a commercially viable option nor is it close to being so.)

As far as I’m aware, fusion energy does not require any mined materials. So, Gratton appears to be referring to fission nuclear energy when he’s talking about the mining sector and critical minerals.

I have an October 28, 2022 posting, which provides an overview of fusion energy and the various projects designed to capitalize on it.

Smart Cities in Canada

I was happy to be updated on the Smart Cities Challenge. When I last wrote about it (a March 20, 2018 posting; scroll down to the “Smart Cities, the rest of the country, and Vancouver” subhead). I notice that the successful applicants are from Montreal, Quebec; Guelph, Ontario; communities of Nunavut; and Bridgewater, Nova Scotia. It’s about time northern communities got some attention. It’s hard not to notice that central Canada (i.e., Ontario and Quebec) again dominates.

I look forward to hearing more about the new, upcoming challenge.

The quantum crew

I first made note of what appears to be a fracture in the Canadian quantum community in a May 4, 2021 posting (scroll down to the National Quantum Strategy subhead) about the 2021 budget. I made note of it again in a July 26, 2022 posting (scroll down to the Canadian quantum scene subhead).

In my excerpts from the 3.5 Investing in Tomorrow’s Technology section of the 2023 budget, Xanadu Quantum Technologies, headquartered in Toronto, Ontario is singled out with three other companies (none of which are in the quantum computing field). Oddly, D-Wave Systems (located in British Columbia), which as far as I’m aware is the star of Canada’s quantum computing sector, has yet to be singled out in any budget I’ve seen yet. (I’m estimating I’ve reviewed about 10 budgets.)

Canadians in space

Shortly after the 2023 budget was presented, Canadian astronaut Jeremy Hansen was revealed as one of four astronauts to go on a mission to orbit the moon. From a Canadian Broadcasting (CBC) April 3, 2023 news online article by Nicole Mortillaro (Note: A link has been removed),

Jeremy Hansen is heading to the moon.

The 47-year old Canadian astronaut was announced today as one of four astronauts — along with Christina Koch, Victor Glover and Reid Wiseman — who will be part of NASA’s [US National Aeronautics and Space Administration] Artemis II mission.

Hansen was one of four active Canadian astronauts that included Jennifer Sidey-Gibbons, Joshua Kutryk and David Saint-Jacques vying for a seat on the Orion spacecraft set to orbit the moon.

Artemis II is the second step in NASA’s mission to return astronauts to the surface of the moon. 

The astronauts won’t be landing, but rather they will orbit for 10 days in the Orion spacecraft, testing key components to prepare for Artemis III that will place humans back on the moon some time in 2025 for the first time since 1972.

Canada gets a seat on Artemis II due to its contributions to Lunar Gateway, a space station that will orbit the moon. But Canada is also building a lunar rover provided by Canadensys Aerospace.

On Monday [April 3, 2023], Hansen noted there are two reasons a Canadian is going to the moon, adding that it “makes me smile when I say that.”

The first, he said, is American leadership, and the decision to curate an international team.

“The second reason is Canada’s can-do attitude,” he said proudly.

In addition to our ‘can-do attitude,” we’re also spending some big money, i.e., the Canadian government has proposed in its 2023 budget some $2.5B to various space and lunar efforts over the next several years.

Chapter 3 odds and sods

First seen in the 2022 budget, the patent box regime makes a second appearance in the 2023 budget where apparently ‘stakeholders will be engaged’ later this year. At least, they’re not rushing into this. (For the original announcement and an explanation of a patent box regime, see my April 19, 2022 budget review; scroll down to the Review of Tax Support to R&D and Intellectual Property subhead.)

I’m happy to see the Dairy Innovation and Investment Fund. I’m particularly happy to see a focus on finding uses for solids non-fat (SNF) by providing “$333 million over ten years, starting in 2023-24, … research and development of new products based on SNF [emphasis mine], market development for these products, and processing capacity for SNF-based products more broadly.”

This investment contrasts with the approach to cellulose nanocrystals (CNC) derived from wood (i.e., the forest economy), where the Canadian government invested heavily in research and even opened a production facility under the auspices of a company, CelluForce. It was a little problematic.

By 2013, the facility had a stockpile of CNC and nowhere to sell it. That’s right, no market for CNC as there had been no product development. (See my May 8, 2012 posting where that lack is mentioned, specifically there’s a quote from Tim Harper in an excerpted Globe and Mail article. My August 17, 2016 posting notes that the stockpile was diminishing. The CelluForce website makes no mention of it now in 2023.)

It’s good to see the government emphasis on research into developing products for SNFs especially after the CelluForce stockpile and in light of US President Joe Biden’s recent enthusiasm over our critical minerals.

Chapter 4: Advancing Reconciliation and Building a Canada That Works for Everyone

Chapter 4: Advancing Reconciliation and Building a Canada That Works for Everyone offers this, from https://www.budget.canada.ca/2023/report-rapport/toc-tdm-en.html,

4.3 Clean Air and Clean Water

Progress on Biodiversity

Montreal recently hosted the Fifteenth Conference of the Parties (COP15) to the United Nations Convention on Biological Diversity, which led to a new Post-2020 Global Biodiversity Framework. During COP15, Canada announced new funding for biodiversity and conservation measures at home and abroad that will support the implementation of the Global Biodiversity Framework, including $800 million to support Indigenous-led conservation within Canada through the innovative Project Finance for Permanence model.

Protecting Our Freshwater

Canada is home to 20 per cent of the world’s freshwater supply. Healthy lakes and rivers are essential to Canadians, communities, and businesses across the country. Recognizing the threat to freshwater caused by climate change and pollution, the federal government is moving forward to establish a new Canada Water Agency and make major investments in a strengthened Freshwater Action Plan.

  • Budget 2023 proposes to provide $650 million over ten years, starting in 2023-24, to support monitoring, assessment, and restoration work in the Great Lakes, Lake Winnipeg, Lake of the Woods, St. Lawrence River, Fraser River, Saint John River, Mackenzie River, and Lake Simcoe. Budget 2023 also proposes to provide $22.6 million over three years, starting in 2023-24, to support better coordination of efforts to protect freshwater across Canada.
  • Budget 2023 also proposes to provide $85.1 million over five years, starting in 2023-24, with $0.4 million in remaining amortization and $21 million ongoing thereafter to support the creation of the Canada Water Agency [emphasis mine], which will be headquartered in Winnipeg. By the end of 2023, the government will introduce legislation that will fully establish the Canada Water Agency as a standalone entity.

Cleaner and Healthier Ports

Canada’s ports are at the heart of our supply chains, delivering goods to Canadians and allowing our businesses to reach global markets. As rising shipping levels enable and create economic growth and good jobs, the federal government is taking action to protect Canada’s coastal ecosystems and communities.

  • Budget 2023 proposes to provide $165.4 million over seven years, starting in 2023-24, to Transport Canada to establish a Green Shipping Corridor Program to reduce the impact of marine shipping on surrounding communities and ecosystems. The program will help spur the launch of the next generation of clean ships, invest in shore power technology, and prioritize low-emission and low-noise vessels at ports.

Water, water everywhere

I wasn’t expecting to find mention of establishing a Canada Water Agency and details are sketchy other than, It will be in Winnipeg, Manitoba and there will be government funding. Fingers crossed that this agency will do some good work (whatever that might be). Personally, I’d like to see some action with regard to droughts.

In British Columbia (BC) where I live and which most of us think of as ‘water rich’, is suffering under conditions such that our rivers and lakes are at very low levels according to an April 6, 2023 article by Glenda Luymes for the Vancouver Sun (print version, p. A4),

On the North American WaterWatch map, which codes river flows using a series of coloured dots, high flows are represented in various shades of blue while low flows are represented in red hues. On Wednesday [April 5, 2023], most of BC was speckled red, brown and orange, with the majority of the province’s rivers flowing “much below normal.”

“It does not bode well for the fish populations,” said Marvin Rosenau, a fisheries and ecosystems instructor at BCIT [British Columbia Institute of Technology]. …

Rosenau said low water last fall [2022], when much of BC was in the grip of drought, decreased salmon habitat during spawning season. …

BC has already seen small early season wildfires, including one near Merritt last weekend [April 1/2, 2023]. …

Getting back to the Canada Water Agency, there’s this March 29, 2023 CBC news online article by Bartley Kives,

The 2023 federal budget calls for a new national water agency to be based in Winnipeg, provided Justin Trudeau’s Liberal government remains in power long enough to see it established [emphasis mine] in the Manitoba capital.

The budget announced on Tuesday [March 28, 2023] calls for the creation of the Canada Water Agency, a new federal entity with a headquarters in Winnipeg.

While the federal government is still determining precisely what the new agency will do, one Winnipeg-based environmental organization expects it to become a one-stop shop for water science, water quality assessment and water management [emphasis mine].

“This is something that we don’t actually have in this country at the moment,” said Matt McCandless, a vice-president for the non-profit International Institute for Sustainable Development.

Right now, municipalities, provinces and Indigenous authorities take different approaches to managing water quality, water science, flooding and droughts, said McCandless, adding a national water agency could provide more co-ordination.

For now, it’s unknown how many employees will be based at the Canada Water Agency’s Winnipeg headquarters. According to the budget, legislation to create the agency won’t be introduced until later this year [emphasis mine].

That means the Winnipeg headquarters likely won’t materialize before 2024, one year before the Trudeau minority government faces re-election, assuming it doesn’t lose the confidence of the House of Commons beforehand [emphasis mine].

Nonetheless, several Canadian cities and provinces were vying for the Canada Water Agency’s headquarters, including Manitoba.

The budget also calls for $65 million worth of annual spending on lake science and restoration, with an unstated fraction of that cash devoted to Lake Winnipeg.

McCandless calls the spending on water science an improvement over previous budgets.

Kives seems a tad jaundiced but you get that way (confession: I have too) when covering government spending promises.

Part 2 (military spending and general comments) will be posted sometime during the week of April 24-28, 2023.

Water-based ionic computing (neural computing networks)

An ionic circuit comprising hundreds of ionic transistors
Caption: An ionic circuit comprising hundreds of ionic transistors. Credit: Woo-Bin Jung/Harvard SEAS

I love that image and it pertains to this September 29, 2022 news item on ScienceDaily,

Microprocessors in smartphones, computers, and data centers process information by manipulating electrons through solid semiconductors but our brains have a different system. They rely on the manipulation of ions in liquid to process information.

Inspired by the brain, researchers have long been seeking to develop ‘ionics’ in an aqueous solution. While ions in water move slower than electrons in semiconductors, scientists think the diversity of ionic species with different physical and chemical properties could be harnessed for richer and more diverse information processing.

Ionic computing, however, is still in its early days. To date, labs have only developed individual ionic devices such as ionic diodes and transistors, but no one has put many such devices together into a more complex circuit for computing — until now.

A team of researchers at the Harvard John A. Paulson School of Engineering and Applied Sciences (SEAS), in collaboration with DNA Script, a biotech startup, have developed an ionic circuit comprising hundreds of ionic transistors and performed a core process of neural net computing.

A September 28, 2022 Harvard John A. Paulson School of Engineering and Applied Sciences news release (also on EurekAlert but published on Sept. 29, 2022), which originated the news item, provides details (Note: A link has been removed),

The researchers began by building a new type of ionic transistor from a  technique they recently pioneered. The transistor consists of an aqueous solution of quinone molecules, interfaced with two concentric ring electrodes with a center disk electrode, like a bullseye. The two ring electrodes electrochemically lower and tune the local pH around the center disk by producing and trapping hydrogen ions. A voltage applied to the center disk causes an electrochemical reaction to generate an ionic current from the disk into the water. The reaction rate can be sped up or down –– increasing or decreasing the ionic current — by tuning the local pH.  In other words, the pH controls, or gates, the disk’s ionic current in the aqueous solution, creating an ionic counterpart of the electronic transistor.

They then engineered the pH-gated ionic transistor in such a way that the disk current is an arithmetic multiplication of the disk voltage and a “weight” parameter representing the local pH gating the transistor. They organized these transistors into a 16 × 16 array to expand the analog arithmetic multiplication of individual transistors into an analog matrix multiplication, with the array of local pH values serving as a weight matrix encountered in neural networks.

“Matrix multiplication is the most prevalent calculation in neural networks for artificial intelligence,” said Woo-Bin Jung, a postdoctoral fellow at SEAS and the first author of the paper. “Our ionic circuit performs the matrix multiplication in water in an analog manner that is based fully on electrochemical machinery.”

“Microprocessors manipulate electrons in a digital fashion to perform matrix multiplication,” said Donhee Ham, the Gordon McKay Professor of Electrical Engineering and Applied Physics at SEAS and the senior author of the paper. “While our ionic circuit cannot be as fast or accurate as the digital microprocessors, the electrochemical matrix multiplication in water is charming in its own right, and has a potential to be energy efficient.”

Now, the team looks to enrich the chemical complexity of the system.

“So far, we have used only 3 to 4 ionic species, such as hydrogen and quinone ions, to enable the gating and ionic transport in the aqueous ionic transistor,” said Jung. “It will be very interesting to employ more diverse ionic species and to see how we can exploit them to make rich the contents of information to be processed.”

The research was co-authored by Han Sae Jung, Jun Wang, Henry Hinton, Maxime Fournier, Adrian Horgan, Xavier Godron, and Robert Nicol. It was supported in part by the Office of the Director of National Intelligence (ODNI), Intelligence Advanced Research Projects Activity (IARPA), under grant 2019-19081900002.

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

An Aqueous Analog MAC Machine by Woo-Bin Jung, Han Sae Jung, Jun Wang, Henry Hinton, Maxime Fournier, Adrian Horgan, Xavier Godron, Robert Nicol, Donhee Ham. Advanced Materials DOI: https://doi.org/10.1002/adma.202205096 First published online: 23 August 2022

This paper is behind a paywall.

As for the biotech startup mentioned as a collaborative partner in the research, DNA Script can be found here.

Using nanomagnets to remove plastic from water

it seems Australian researchers are working hard to find ways of removing microplastics from water. I have two items, first, a November 29, 2022 news item on Nanowerk announces some of the latest work,

Researchers at RMIT University have found an innovative way to rapidly remove hazardous microplastics from water using magnets.

Lead researcher Professor Nicky Eshtiaghi said existing methods could take days to remove microplastics from water, while their cheap and sustainable invention achieves better results in just one hour.

The team says they have developed adsorbents, in the form of a powder, that remove microplastics 1,000 times smaller than those currently detectable by existing wastewater treatment plants. 

The researchers have successfully tested the adsorbents in the lab, and they plan to engage with industry to further develop the innovation to remove microplastics from waterways.

A November 30, 2022 RMIT University press release, which originated the news item, provides more technical detail about the work,

“The nano-pillar structure we’ve engineered to remove this pollution, which is impossible to see but very harmful to the environment, is recycled from waste and can be used multiple times,” said Eshtiaghi from RMIT’s School of Environmental and Chemical Engineering.

“This is a big win for the environment and the circular economy.”

How does this innovation work?

The researchers have developed an adsorbent using nanomaterials that they can mix into water to attract microplastics and dissolved pollutants.

Muhammad Haris, the first author and PhD candidate from RMIT’s School of Environmental and Chemical Engineering, said the nanomaterials contained iron, which enabled the team to use magnets to easily separate the microplastics and pollutants from the water.

“This whole process takes one hour, compared to other inventions taking days,” he said.

Co-lead researcher Dr Nasir Mahmood said the nano-pillar structured material was designed to attract microplastics without creating any secondary pollutants or carbon footprints.

“The adsorbent is prepared with special surface properties so that it can effectively and simultaneously remove both microplastics and dissolved pollutants from water,” said Mahmood from Applied Chemistry and Environmental Science at RMIT.

“Microplastics smaller than 5 millimetres, which can take up to 450 years to degrade, are not detectable and removable through conventional treatment systems, resulting in millions of tonnes being released into the sea every year. This is not only harmful for aquatic life, but also has significant negative impacts on human health.”

The team received scientific and technical support from the Microscopy and Microanalysis Facility and the Micro Nano Research Facility, part of RMIT’s newly expanded Advanced Manufacturing Precinct, to complete their research. 

What are the next steps?

Developing a cost-effective way to overcome these signficant challenges posed by microplastics was critical, Eshtiaghi said.

“Our powder additive can remove microplastics that are 1,000 times smaller than those that are currently detectable by existing wastewater treatment plants,” she said.

“We are looking for industrial collaborators to take our invention to the next steps, where we will be looking at its application in wastewater treatment plants.”

Eshtiaghi and her colleagues have worked with various water utilities across Australia, including with Melbourne Water and Water Corporation in Perth on a recent Australian Research Council Linkage project to optimise sludge pumping systems.

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

Self-assembly of C@FeO nanopillars on 2D-MOF for simultaneous removal of microplastic and dissolved contaminants from water by Muhammad Haris, Muhammad Waqas Khan, Ali Zavabeti, Nasir Mahmood and Nicky Eshtiaghi. Chemical Engineering Journal Available online 23 November 2022, 140390 DOI: https://doi.org/10.1016/j.cej.2022.140390

This paper is behind a paywall.

Back in 2019

Caption: This visual abstract depicts the findings of Kang et al.. Novel and robust nanocarbon springs were synthesized via solid pyrolysis with a controlled morphology, and simultaneously engineered nitrogen dopants and encapsulated magnetic nanoparticles. The carbocatalysts can effectively catalyze peroxymonosulfate to generate highly reactive radicals under hydrothermal conditions for decomposing microplastics into harmless substances in water. Credit: Kang et al/Matter

This July 31, 2019 Cell Press news release on EurekAlert announces a different approach, from an Australian team, to removing plastics from water,

Plastic waste that finds its way into oceans and rivers poses a global environmental threat with damaging health consequences for animals, humans, and ecosystems. Now, using tiny coil-shaped carbon-based magnets, researchers in Australia have developed a new approach to purging water sources of the microplastics that pollute them without harming nearby microorganisms. Their work appears July 31 in the journal Matter.

“Microplastics adsorb organic and metal contaminants as they travel through water and release these hazardous substances into aquatic organisms when eaten, causing them to accumulate all the way up the food chain” says senior author Shaobin Wang, a professor of chemical engineering at the University of Adelaide (Australia). “Carbon nanosprings are strong and stable enough to break these microplastics down into compounds that do not pose such a threat to the marine ecosystem.”

Although often invisible to the naked eye, microplastics are ubiquitous pollutants. Some, such as the exfoliating beads found in popular cosmetics, are simply too small to be filtered out during industrial water treatment. Others are produced indirectly, when larger debris like soda bottles or tires weather amid sun and sand.

To decompose the microplastics, the researchers had to generate short-lived chemicals called reactive oxygen species, which trigger chain reactions that chop the various long molecules that make up microplastics into tiny and harmless segments that dissolve in water. However, reactive oxygen species are often produced using heavy metals such as iron or cobalt, which are dangerous pollutants in their own right and thus unsuitable in an environmental context.

To get around this challenge, the researchers found a greener solution in the form of carbon nanotubes laced with nitrogen to help boost generation of reactive oxygen species. Shaped like springs, the carbon nanotube catalysts removed a significant fraction of microplastics in just eight hours while remaining stable themselves in the harsh oxidative conditions needed for microplastics breakdown. The coiled shape increases stability and maximises reactive surface area. As a bonus, by including a small amount of manganese, buried far from the surface of the nanotubes to prevent it from leaching into water, the minute springs became magnetic.

“Having magnetic nanotubes is particularly exciting because this makes it easy to collect them from real wastewater streams for repeated use in environmental remediation,” says Xiaoguang Duan, a chemical engineering research fellow at Adelaide who also co-led the project.

As no two microplastics are chemically quite the same, the researchers’ next steps will center on ensuring that the nanosprings work on microplastics of different compositions, shapes and origins. They also intend to continue to rigorously confirm the non-toxicity of any chemical compounds occurring as intermediates or by-products during microplastics decomposition.

The researchers also say that those intermediates and byproducts could be harnessed as an energy source for microorganisms that the polluting plastics currently plague. “If plastic contaminants can be repurposed as food for algae growth, it will be a triumph for using biotechnology to solve environmental problems in ways that are both green and cost efficient,” Wang says.

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

Degradation of Cosmetic Microplastics via Functionalized Carbon Nanosprings by Jian Kang, Li Zhou, Xiaoguang Duan, Hongqi Sun, Zhimin Ao, Shaobin Wang. Matter Volume 1, Issue 3, 4 September 2019, Pages 745-758 DOI: https://doi.org/10.1016/j.matt.2019.06.004

This paper is open access.

Comments

I’m glad to see this work and as for which approach might be preferable, I don’t know if there’s a clear winner. The 2022 work removes both microplastics and pollutants in one hour! An impressive feat, which leaves us with microplastics and pollutants to deal with. By contrast , the 2019 work transforms the microplastics into materials that don’t pose harm to the aquatic environment. Great although it takes eight hours. I wish the best for all the researchers working on this microplastics problem.

Pulling water from the air

Adele Peters’ May 27, 2022 article for Fast Company describes some research into harvesting water from the air (Note: Links have been removed),

In Ethiopia, where an ongoing drought is the worst in 40 years, getting drinking water for the day can involve walking for eight hours. Some wells are drying up. As climate change progresses, water scarcity keeps getting worse. But new technology in development at the University of Texas at Austin could help: Using simple, low-cost materials, it harvests water from the air, even in the driest climates.

“The advantage of taking water moisture from the air is that it’s not limited geographically,” says Youhong “Nancy” Guo, lead author of a new study in Nature Communications that describes the technology.

It’s a little surprising that Peters doesn’t mention the megadrought in the US Southwest, which has made quite a splash in the news, from a February 15, 2022 article by Denise Chow for NBC [{US} National Broadcasting Corporation] news online, Note: Links have been removed,

The megadrought that has gripped the southwestern United States for the past 22 years is the worst since at least 800 A.D., according to a new study that examined shifts in water availability and soil moisture over the past 12 centuries.

The research, which suggests that the past two decades in the American Southwest have been the driest period in 1,200 years, pointed to human-caused climate change as a major reason for the current drought’s severity. The findings were published Monday in the journal Nature Climate Change.

Jason Smerdon, one of the study’s authors and a climate scientist at Columbia University’s Lamont-Doherty Earth Observatory, said global warming has made the megadrought more extreme because it creates a “thirstier” atmosphere that is better able to pull moisture out of forests, vegetation and soil.

Over the past two decades, temperatures in the Southwest were around 1.64 degrees Fahrenheit higher than the average from 1950 to 1999, according to the researchers. Globally, the world has warmed by about 2 degrees Fahrenheit since the late 1800s.

It’s getting drier even here in the Pacific Northwest. Maybe it’s time to start looking at drought and water shortages as a global issue rather than as a regional issue.

Caption: An example of a different shape the water-capturing film can take. Credit: The University of Texas at Austin / Cockrell School of Engineering

Getting back to the topic, a May 23, 2022 University of Texas at Austin news release (also on EurkeAlert), which originated the Peters’ article, announces the work,

More than a third of the world’s population lives in drylands, areas that experience significant water shortages. Scientists and engineers at The University of Texas at Austin have developed a solution that could help people in these areas access clean drinking water.

The team developed a low-cost gel film made of abundant materials that can pull water from the air in even the driest climates. The materials that facilitate this reaction cost a mere $2 per kilogram, and a single kilogram can produce more than 6 liters of water per day in areas with less than 15% relative humidity and 13 liters in areas with up to 30% relative humidity.

The research builds on previous breakthroughs from the team, including the ability to pull water out of the atmosphere and the application of that technology to create self-watering soil. However, these technologies were designed for relatively high-humidity environments.

“This new work is about practical solutions that people can use to get water in the hottest, driest places on Earth,” said Guihua Yu, professor of materials science and mechanical engineering in the Cockrell School of Engineering’s Walker Department of Mechanical Engineering. “This could allow millions of people without consistent access to drinking water to have simple, water generating devices at home that they can easily operate.”

The researchers used renewable cellulose and a common kitchen ingredient, konjac gum, as a main hydrophilic (attracted to water) skeleton. The open-pore structure of gum speeds the moisture-capturing process. Another designed component, thermo-responsive cellulose with hydrophobic (resistant to water) interaction when heated, helps release the collected water immediately so that overall energy input to produce water is minimized.

Other attempts at pulling water from desert air are typically energy-intensive and do not produce much. And although 6 liters does not sound like much, the researchers say that creating thicker films or absorbent beds or arrays with optimization could drastically increase the amount of water they yield.

The reaction itself is a simple one, the researchers said, which reduces the challenges of scaling it up and achieving mass usage.

“This is not something you need an advanced degree to use,” said Youhong “Nancy” Guo, the lead author on the paper and a former doctoral student in Yu’s lab, now a postdoctoral researcher at the Massachusetts Institute of Technology. “It’s straightforward enough that anyone can make it at home if they have the materials.”

The film is flexible and can be molded into a variety of shapes and sizes, depending on the need of the user. Making the film requires only the gel precursor, which includes all the relevant ingredients poured into a mold.

“The gel takes 2 minutes to set simply. Then, it just needs to be freeze-dried, and it can be peeled off the mold and used immediately after that,” said Weixin Guan, a doctoral student on Yu’s team and a lead researcher of the work.

The research was funded by the U.S. Department of Defense’s Defense Advanced Research Projects Agency (DARPA), and drinking water for soldiers in arid climates is a big part of the project. However, the researchers also envision this as something that people could someday buy at a hardware store and use in their homes because of the simplicity.

Yu directed the project. Guo and Guan co-led experimental efforts on synthesis, characterization of the samples and device demonstration. Other team members are Chuxin Lei, Hengyi Lu and Wen Shi.

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

Scalable super hygroscopic polymer films for sustainable moisture harvesting in arid environments by Youhong Guo, Weixin Guan, Chuxin Lei, Hengyi Lu, Wen Shi & Guihua Yu. Nature Communications volume 13, Article number: 2761 (2022) DOI: https://doi.org/10.1038/s41467-022-30505-2 Published: 19 May 2022

This paper is open access.

Fluorine-based nanostructures for desalination

A May 16, 2022 article by Qamariya Nasrullah for cosmosmagazine.com describes research from Japan on desalination (Note: A link has been removed),

Water supply is a growing global issue, especially with climate change bringing on more droughts. Seawater desalination is used worldwide to filter up to 97.4 million cubic metres per day. Two methods – thermal and reverse osmosis – predominate; both have huge energy costs.

In a pioneering study published in Science, researchers have used a fluorine-based nanostructure to successfully filter salt from water faster and more efficiently than other current technologies. But how does it work?

A May 12, 2022 University of Tokyo press release (also on EurekAlert), which originated the news item, provides the answer to Nasrullah’s question,

If you’ve ever cooked with a nonstick Teflon-coated frying pan, then you’ve probably seen the way that wet ingredients slide around it easily. This happens because the key component of Teflon is fluorine, a lightweight element that is naturally water repelling, or hydrophobic. Teflon can also be used to line pipes to improve the flow of water. Such behavior caught the attention of Associate Professor Yoshimitsu Itoh from the Department of Chemistry and Biotechnology at the University of Tokyo and his team. It inspired them to explore how pipes or channels made from fluorine might operate on a very different scale, the nanoscale.

“We were curious to see how effective a fluorous nanochannel might be at selectively filtering different compounds, in particular, water and salt. And, after running some complex computer simulations, we decided it was worth the time and effort to create a working sample,” said Itoh. “There are two main ways to desalinate water currently: thermally, using heat to evaporate seawater so it condenses as pure water, or by reverse osmosis, which uses pressure to force water through a membrane that blocks salt. Both methods require a lot of energy, but our tests suggest fluorous nanochannels require little energy, and have other benefits too.”

The team created test filtration membranes by chemically synthesizing nanoscopic fluorine rings, which were stacked and embedded in an otherwise impermeable lipid layer, similar to the organic molecules that make up cell walls. They created several test samples with nanorings between about 1 and 2 nanometers. For reference, a human hair is almost 100,000 nanometers wide. To test the effectiveness of their membranes, Itoh and the team measured the presence of chlorine ions, one of the major components of salt — the other being sodium — on either side of the test membrane.

“It was very exciting to see the results firsthand. The smaller of our test channels perfectly rejected incoming salt molecules, and the larger channels too were still an improvement over other desalination techniques and even cutting-edge carbon nanotube filters,” said Itoh. “The real surprise to me was how fast the process occurred. Our sample worked around several thousand times faster than typical industrial devices, and around 2,400 times faster than experimental carbon nanotube-based desalination devices.”

As fluorine is electrically negative, it repels negative ions such as the chlorine found in salt. But an added bonus of this negativity is that it also breaks down what are known as water clusters, essentially loosely bound groups of water molecules, so that they pass through the channels quicker. The team’s fluorine-based water desalination membranes are more effective, faster, require less energy to operate and are made to be very simple to use as well, so what’s the catch?

“At present, the way we synthesize our materials is relatively energy-intensive itself; however, this is something we hope to improve upon in upcoming research. And, given the longevity of the membranes and their low operational costs, the overall energy costs will be much lower than with current methods,” said Itoh. “Other steps we wish to take are of course scaling this up. Our test samples were single nanochannels, but with the help of other specialists, we hope to create a membrane around 1 meter across in several years. In parallel with these manufacturing concerns, we’re also exploring whether similar membranes could be used to reduce carbon dioxide or other undesirable waste products released by industry.”

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

Ultrafast water permeation through nanochannels with a densely fluorous interior surface by Yoshimitsu Itoh, Shuo Chen, Jyota Hirahara, Takeshi Konda, Tsubasa Aoki, Takumi Ueda, Ichio Shimada, James J. Cannon, Cheng Shao, Junichiro Shiomi, Kazuhito V. Tabata, Hiroyuki Noji, Kohei Sato, and Takuzo Aida. Science • 12 May 2022 • Vol 376, Issue 6594 • pp. 738-743 • DOI: 10.1126/science.abd0966

This paper is behind a paywall.