Category Archives: agriculture

Growing plant roots and fungal hyphae in silica nanoparticles for 3D microvascular networks

This is fascinating,

A November 19, 2024 news item on phys.org describes the problem the researchers in Japan were solving,

Microfluidic technology has become increasingly important in many scientific fields, such as regenerative medicine, microelectronics, and environmental science. However, conventional microfabrication techniques face limitations in scale and in the construction of complex networks. These hurdles are compounded when it comes to building more intricate 3D microfluidic networks.

A November 19, 2024 Kyushu University press release (also on EurekAlert), which originated the news item, describes how the researchers propose to solve the problem building 3D microfluidic networks, Note: Links have been removed,

Now, researchers from Kyushu University have developed a new and convenient technique for building such complex 3D microfluidic networks. Their tool? Plants and fungi. The team developed a ‘soil’ medium using nanoparticles of glass (silica) and a cellulose based binding agent, then allowed plants and fungi to grow roots into it. After the plants were removed, the glass was left with a complex 3D microfluidic network of micrometer-sized hollow holes where the roots once were.

The new method can also be utilized for observing and preserving 3D biological structures that are typically difficult to study in soil, opening new opportunities for research in plant and fungal biology. Their findings were published in the journal Scientific Reports.

“The primary motivation for this research was to overcome the limitations of conventional microfabrication techniques in creating complex 3D microfluidic structures. The focus of our lab is biomimetics, where we try to solve engineering problems by looking to nature and artificially replicating such structures,” explains Professor Fujio Tsumori of Kyushu University’s Faculty of Engineering, who led the study. “And what better example of microfluidics in nature than plant roots and fungal hyphae? So, we set out to develop a method that could harness the natural growth patterns of these organisms and create optimized microfluidic networks.”

The researchers began by developing a ‘soil’ like mix for plants to grow in, but instead of dirt, they combined growth medium with glass nanoparticles smaller than 1 μm in diameter with hydroxypropyl methyl cellulose as a binding agent. They then seeded this ‘soil’ mixture and waited for the plants to take root. After confirming successful plant growth, the ‘soil’ was baked leaving only the glass with root cavities.

“The process is called sintering, which aggregates fine particles together into a more solid state. It is similar to powder metallurgy in the manufacturing of ceramics,” continues Tsumori. “In this case it is the plant that does the molding.”

Their method was able to replicate the intricate biological structures of a plant’s main roots which can be up to 150 μm in diameter, and all the way down to it root hairs which can be about 8 μm in diameter. Tests with other organisms showed that the method can even replicate the root structure of fungi, called hyphae.

“Hyphae are even thinner and can be as small as 1-2 μm in diameter. That’s thinner than a single strand of spider silk,” says Tsumori.

The team hopes that their new bio-inspired microfluidic fabrication technique could be used in various fields of science and engineering, potentially leading to more efficient microreactors, advanced heat exchangers, and innovative tissue engineering scaffolds.

“In the biological sciences, this technique provides a unique tool for studying the intricate 3D structures of plant roots and fungal networks, which can advance our understanding of soil ecosystems,” concludes Tsumori. “By bridging biological systems and engineering, our research has the potential to pave the way for new technologies and scientific discoveries.”

About Kyushu University 
Founded in 1911, Kyushu University is one of Japan’s leading research-oriented institutes of higher education, consistently ranking as one of the top ten Japanese universities in the Times Higher Education World University Rankings and the QS World Rankings. The university is one of the seven national universities in Japan, located in Fukuoka, on the island of Kyushu—the most southwestern of Japan’s four main islands with a population and land size slightly larger than Belgium. Kyushu U’s multiple campuses—home to around 19,000 students and 8000 faculty and staff—are located around Fukuoka City, a coastal metropolis that is frequently ranked among the world’s most livable cities and historically known as Japan’s gateway to Asia. Through its VISION 2030, Kyushu U will “drive social change with integrative knowledge.” By fusing the spectrum of knowledge, from the humanities and arts to engineering and medical sciences, Kyushu U will strengthen its research in the key areas of decarbonization, medicine and health, and environment and food, to tackle society’s most pressing issues.

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

Replicating biological 3D root and hyphal networks in transparent glass chips by Tetsuro Koga, Shota Nakashima & Fujio Tsumori. Scientific Reports volume 14, Article number: 21128 (2024) DOI: https://doi.org/10.1038/s41598-024-72333-y Published: 10 September 2024

This paper is open access.

Water, critical minerals, technology and US expansionist ambitions (Manifest Destiny)

I was taught in high school that the US was running out of its resources and that Canada still had much of its resources. That was decades ago. As well, throughout the years, usually during a vote in Québec about separating, I’ve heard rumblings about the US absorbing part or all of Canada as something they call ‘Manifest Destiny,’ which dates back to the 19th century.

Unlike the previous forays Into Manifest Destiny, this one has not been precipitated by any discussion of separation.

Manifest Destiny

It took a while for that phrase to emerge this time but when it finally did the Canadian Broadcasting Corporation (CBC) online news published a January 19, 2025 article by Ainsley Hawthorn providing some context for the term, Note: Links have been removed,

U.S. president-elect Donald Trump says he’s prepared to use economic force to turn Canada into America’s 51st state, and it’s making Canadians — two-thirds of whom believe he’s sincere — anxious. 

But the last time Canada faced the threat of American annexation, it united us more than ever before, leading to the foundation of our country as we know it today.

In the 1860s, several prominent U.S. politicians advocated for annexing the colonies of British North America. 

“I look on Rupert’s Land [modern-day Manitoba and parts of Alberta, Saskatchewan, Nunavut, Ontario, and Quebec] and Canada, and see how an ingenious people and a capable, enlightened government are occupied with bridging rivers and making railroads and telegraphs,” Secretary of State William Henry Seward told a crowd in St. Paul, Minn. while campaigning on behalf of presidential candidate Abraham Lincoln.

“I am able to say, it is very well; you are building excellent states to be hereafter admitted into the American Union.”

Seward believed in Manifest Destiny, the doctrine that the United States would inevitably expand across the entire North American continent. While he seems to have preferred to acquire territory through negotiation rather than aggression, Canadians weren’t wholly assured of America’s peaceful intentions. 

In the late 1850s and early 1860s, Canadian parliament had been so deadlocked it had practically come to a standstill. Within just a few years, American pressure created a sense of unity so great it led to Confederation.

The current conversation around annexation is likewise uniting Canada’s leaders to a degree we’ve rarely seen in recent years. 

Representatives across the political spectrum are sharing a common message, the same message as British North Americans in the late nineteenth century: despite our problems, Canadians value Canada.

Critical minerals and water

Prime Minister Justin Trudeau had a few comments to make about US President Donald Trump’s motivation for ‘absorbing’ Canada as the 51st state, from a February 7, 2025 CBC news online article by Peter Zimonjic, ·

Prime Minister Justin Trudeau told business leaders at the Canada-U.S. Economic Summit in Toronto that U.S. President Donald Trump’s threat to annex Canada “is a real thing” motivated by his desire to tap into the country’s critical minerals.

“Mr. Trump has it in mind that the easiest way to do it is absorbing our country and it is a real thing,” Trudeau said, before a microphone cut out at the start of the closed-door meeting. 

The prime minister made the remarks to more than 100 business leaders after delivering an opening address to the summit Friday morning [February 7, 2025], outlining the key issues facing the country when it comes to Canada’s trading relationship with the U.S.

After the opening address, media were ushered out of the room when a microphone that was left on picked up what was only meant to be heard by attendees [emphasis mine].

Automotive Parts Manufacturers’ Association president Flavio Volpe was in the room when Trudeau made the comments. He said the prime minister went on to say that Trump is driven because the U.S. could benefit from Canada’s critical mineral resources.

There was more, from a February 7, 2025 article by Nick Taylor-Vaisey for Politico., Note: A link has been removed,

In remarks caught on tape by The Toronto Star, Trudeau suggested the president is keenly aware of Canada’s vast mineral resources. “I suggest that not only does the Trump administration know how many critical minerals we have but that may be even why they keep talking about absorbing us and making us the 51st state,” Trudeau said.

All of this reminded me of US President Joe Biden’s visit to Canada and his interest in critical minerals which I mentioned briefly in my comments about the 2023 federal budget, from my April 17, 2023 posting (scroll down to the ‘Canadian economic theory (the staples theory), mining, nuclear energy, quantum science, and more’ subhead,

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 think there’s any question that the US knows how much, where, and how easily ‘extractable’ Canadian critical minerals might be.

Pressure builds

On the same day (Monday, February 3, 2025) the tariffs were postponed for a month,Trudeau had two telephone calls with US president Donald Trump. According to a February 9, 2025 article by Steve Chase and Stefanie Marotta for the Globe and Mail, Trump and his minions are exploring the possibility of acquiring Canada by means other than a trade war or economic domination,

“He [Trudeau] talked about two phone conversations he had with Mr. Trump on Monday [February 3, 2025] before the President agreed to delay to steep tariffs on Canadian goods for 30 days.n

During the calls, the Prime Minister recalled Mr. Trump referred to a four-page memo that included a list of grievances he had with Canadian trade and commercial rules, including the President’s false claim that US banks are unable to operate in Canada. …

In the second conversation with Mr. Trump on Monday, the Prime Minister told the summit, the President asked him whether he was familiar with the Treaty of 1908, a pact between the United States and Britain that defined the border between the United States and Canada. he told Mr. Trudeau, he should look it up.

Mr. Trudeau told the summit he thought the treaty had been superseded by other developments such as the repatriation the Canadian Constitution – in other words, that the border cannot be dissolved by repealing that treaty. He told the audience that international law would prevent the dissolution 1908 Treaty leading to the erasure of the border. For example, various international laws define sovereign borders, including the United Nationals Charter of which both countries are signatories and which has protection to territorial integrity.

A source familiar with the calls said Mr. Trump’s reference to the 1908 Treaty was taken as an implied threat. … [p. A3 in paper version]

I imagine Mr. Trump and/or his minions will keep trying to find one pretext or another for this attempt to absorb or annex or wage war (economically or otherwise) on Canada.

What makes Canadian (and Greenlandic) minerals and water so important?

You may have noticed the January 21, 2025 announcement by Mr. Trump about the ‘Stargate Project,’ a proposed US $500B AI infrastructure company (you can find more about the Stargate Project (Stargate LLC) in its Wikipedia entry).

Most likely not a coincidence, on February 10, 2025 President of France, Emmanuel Macron announced a 109B euros investment in French AI sector, from the February 9, 2025 Reuters preannouncement article,

France will announce private sector investments totalling some 109 billion euros ($112.5 billion [US]) in its artificial intelligence sector during the Paris AI summit which opens on Monday, President Emmanuel Macron said.

The financing includes plans by Canadian investment firm [emphasis mine] Brookfield to invest 20 billion euros in AI projects in France and financing from the United Arab Emirates which could hit 50 billion euros in the years ahead, Macron’s office said.

Big projects, non? It’s no surprise critical minerals will be necessary but the need for massive amounts of water may be. My October 16, 2023 posting focuses on water and AI development, specifically ChatGPT-4,

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 [in the excerpt] 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]

As for how much water was diverted in Iowa for a data centre project, from my October 16, 2023 posting

Jason Clayworth’s September 18, 2023 article for AXIOS describes the issue from the Iowan perspective, Note: Links [from the excerpt] 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.

The bottom line is that these technologies consume a lot of water and require critical minerals.

Greenland

Evan Dyer’s January 16, 2025 article for CBC news online describes both US military strategic interests and hunger for resources, Note 1: Article links have been removed; Note 2: I have added one link to a Wikipedia entry,

The person who first put a bug in Donald Trump’s ear about Greenland — if a 2022 biography is to be believed — was his friend Ronald Lauder, a New York billionaire and heir to the Estée Lauder cosmetics fortune.

But it would be wrong to believe that U.S. interest in Greenland originated with idle chatter at the country club, rather than real strategic considerations.

Trump’s talk of using force to annex Greenland — which would be an unprovoked act of war against a NATO ally — has been rebuked by Greenlandic, Danish and European leaders. A Fox News team that travelled to Greenland’s capital Nuuk reported back to the Trump-friendly show Fox & Friends that “most of the people we spoke with did not support Trump’s comments and found them offensive.”

Certainly, military considerations motivated the last U.S. attempt at buying Greenland in 1946.

The military value to the U.S. of acquiring Greenland is much less clear in 2025 than it was in 1946.

Russian nuclear submarines no longer need to traverse the GIUK [the GIUK gap; “{sometimes written G-I-UK} is an area in the northern Atlantic Ocean that forms a naval choke point. Its name is an acronym for Greenland, Iceland, and the United Kingdom, the gap being the two stretches of open ocean among these three landmasses.”]. They can launch their missiles from closer to home.

And in any case, the U.S. already has a military presence on Greenland, used for early warning, satellite tracking and marine surveillance. The Pentagon simply ignored Denmark’s 1957 ban on nuclear weapons on Greenlandic territory. Indeed, an American B-52 bomber carrying four hydrogen bombs crashed in Greenland in 1968.

“The U.S. already has almost unhindered access [emphasis mine], and just building on their relationship with Greenland is going to do far more good than talk of acquisition,” said Dwayne Menezes, director of the Polar Research and Policy Initiative in London.

The complication, he says, is Greenland’s own independence movement. All existing defence agreements involving the U.S. presence in Greenland are between Washington and the Kingdom of Denmark. [emphasis mine]

“They can’t control what’s happening between Denmark and Greenland,” Menezes said. “Over the long term, the only way to mitigate that risk altogether is by acquiring Greenland.”

Menezes also doesn’t believe U.S. interest in Greenland is purely military.

And Trump’s incoming national security adviser Michael Waltz [emphasis mine] appeared to confirm as much when asked by Fox News why the administration wanted Greenland.

This is about critical minerals, this is about natural resources [emphasis mine]. This is about, as the ice caps pull back, the Chinese are now cranking out icebreakers and are pushing up there.”

While the United States has an abundance of natural resources, it risks coming up short in two vital areas: rare-earth minerals and freshwater.

Greenland’s apparent barrenness belies its richness in those two key 21st-century resources.

The U.S. rise to superpower was driven partly by the good fortune of having abundant reserves of oil, which fuelled its industrial growth. The country is still a net exporter of petroleum.

China, Washington’s chief strategic rival, had no such luck. It has to import more than two-thirds of its oil, and is now importing more than six times as much as it did in 2000.

But the future may not favour the U.S. as much as the past.

I stand corrected, where oil is concerned. From Dyer’s January 16, 2025 article, Note: Links have been removed,

It’s China, and not the U.S., that nature blessed with rich deposits of rare-earth elements, a collection of 17 metals such as yttrium and scandium that are increasingly necessary for high-tech applications from cellphones and flat-screen TVs to electric cars.

The rare-earth element neodymium is an essential part of many computer hard drives and defence systems including electronic displays, guidance systems, lasers, radar and sonar.

Three decades ago, the U.S. produced a third of the world’s rare-earth elements, and China about 40 per cent. By 2011, China had 97 per cent of world production, and its government was increasingly limiting and controlling exports.

The U.S. has responded by opening new mines and spurring recovery and recycling to reduce dependence on China.

Such efforts have allowed the U.S. to claw back about 20 per cent of the world’s annual production of rare-earth elements. But that doesn’t change the fact that China has about 44 million tonnes of reserves, compared to fewer than two million in the U.S.

“There’s a huge dependency on China,” said Menezes. “It offers China the economic leverage, in the midst of a trade war in particular, to restrict supply to the West, thus crippling industries like defence, the green transition. This is where Greenland comes in.”

Greenland’s known reserves are almost equivalent to those of the entire U.S., and much more may lie beneath its icebound landscape. 

“Greenland is believed to be able to meet at least 25 per cent of global rare-earth demand well into the future,” he said.

An abundance of freshwater

The melting ice caps referenced by Trump’s nominee for national security adviser are another Greenlandic resource the world is increasingly interested in.

Seventy per cent of the world’s freshwater is locked up in the Antarctic ice cap. Of the remainder, two-thirds is in Greenland, in a massive ice cap that is turning to liquid at nearly twice the volume of melting in Antarctica.

“We know this because you can weigh the ice sheet from satellites,” said Christian Schoof, a professor of Earth, ocean and atmospheric sciences at the University of British Columbia who spent part of last year in Greenland studying ice cap melting.

“The ice sheet is heavy enough that it affects the orbit of satellites going over it. And you can record the change in that acceleration of satellites due to the ice sheet over time, and directly weigh the ice sheet.”

“There is a growing demand for freshwater on the world market, and the use of the vast water potential in Greenland may contribute to meeting this demand,” the Greenland government announces on its website.

The Geological Survey of Denmark and Greenland found 10 locations that were suitable for the commercial exploitation of Greenland’s ice and water, and has already issued a number of licenses.

Schoof told CBC News that past projects that attempted to tow Greenlandic ice to irrigate farms in the Middle East “haven’t really taken off … but humans are resourceful and inventive, and we face some really significant issues in the future.”

For the U.S., those issues include the 22-year-long “megadrought” which has left the western U.S. [emphases mine] drier than at any time in the past 1,200 years, and which is already threatening the future of some American cities.

As important as they are, there’s more than critical minerals and water, according to Dyer’s January 16, 2025 article

Even the “rock flour” that lies under the ice cap could have great commercial and strategic importance.

Ground into nanoparticles by the crushing weight of the ice, research has revealed it to have almost miraculous properties, says Menezes.

“Scientists have found that Greenlandic glacial flour has a particular nutrient composition that enables it to be regenerative of soil conditions elsewhere,” he told CBC News. “It improves agricultural yields. It has direct implications for food security.”

Spreading Greenland rock flour on corn fields in Ghana produced a 30 to 50 per cent increase in crop yields. Similar yield gains occurred when it was spread on Danish fields that produce the barley for Carlsberg beer.

Canada

It’s getting a little tiring keeping up with Mr. Trump’s tariff tear (using ‘tear’ as a verbal noun; from the Cambridge dictionary, verb: TEAR definition: 1. to pull or be pulled apart, or to pull pieces off: 2. to move very quickly …).

The bottom line is that Mr. Trump wants something and certainly Canadian critical minerals and water constitute either his entire interest or, at least, his main interest for now, with more to be determined later.

Niall McGee’s February 9, 2025 article for the Globe and Mail provides an overview of the US’s dependence on Canada’s critical minerals,

The US relies on Canada for a huge swath of its critical mineral imports, including 40 per cent of its primary nickel for its defence industry, 30 per cent of its uranium, which is used in its nuclear-power fleet, and 79 per cent of its potash for growing crops.

The US produces only small amounts of all three, while Canada is the world’s biggest potash producer, the second biggest in uranium, and number six in nickel.

If the US wants to buy fewer critical minerals from Canada, in many cases it would be forced to source them from hostile countries such as Russia and China.

Vancouver-based Teck Resources Ltd. is one of the few North American suppliers of germanium. The critical mineral is used in fibre-optic networks, infrared vision systems, solar panels. The US relies on Canada for 23 per cent of its imports of germanium.

China in December [2024] banned exports of the critical mineral to the US citing national security concerns. The ban raised fears of possible shortages for the US.

“It’s obvious we have a lot of what Trump wants to support America’s ambitions, from both an economic and a geopolitical standpoint,” says Martin Turenne, CEO of Vancouver-based FPX Nickel Corp., which is developing a massive nickel project in British Columbia. [p. B5 paper version]

Akshay Kulkarni’s January 15, 2025 article for CBC news online provides more details about British Columbia and its critical minerals, Note: Links have been removed,

The premier had suggested Tuesday [January 14, 2025] that retaliatory tariffs and export bans could be part of the response, and cited a smelter operation located in Trail, B.C. [emphasis mine; keep reading], which exports minerals that Eby [Premier of British Columbia, David Eby] said are critical for the U.S.

The U.S. and Canada both maintain lists of critical minerals — ranging from aluminum and tin to more obscure elements like ytterbium and hafnium — that both countries say are important for defence, energy production and other key areas.

Michael Goehring, the president of the Mining Association of B.C., said B.C. has access to or produces 16 of the 50 minerals considered critical by the U.S.

Up-close picture of red and blue atoms.
Individual atoms of silicon and germanium are seen following an Atomic Probe Tomography (APT) measurement at Polytechnique Montreal. Both minerals are manufactured in B.C. (Christinne Muschi/The Canadian Press)

“We have 17 critical mineral projects on the horizon right now, along with a number of precious metal projects,” he told CBC News on Tuesday [January 14, 2025].

“The 17 critical mineral projects alone represent some $32 billion in potential investment for British Columbia,” he added.

John Steen, director of the Bradshaw Research Institute for Minerals and Mining at the University of B.C., pointed to germanium — which is manufactured at Teck’s facility in Trail [emphasis mine] — as one of the materials most important to U.S industry.

There are a number of mines and manufacturing facilities across B.C. and Canada for critical minerals.

The B.C. government says the province is Canada’s largest producer of copper, and only producer of molybdenum, which are both considered critical minerals.

There’s also graphite, not in BC but in Québec. This April 8, 2023 article by Christian Paas-Lang for CBC news online focuses largely on issues of how to access and exploit graphite and also, importantly, indigenous concerns, but this excerpt focuses on graphite as a critical mineral,

A mining project might not be what comes to mind when you think of the transition to a lower emissions economy. But embedded in electric vehicles, solar panels and hydrogen fuel storage are metals and minerals that come from mines like the one in Lac-des-Îles, Que.

The graphite mine, owned by the company Northern Graphite, is just one of many projects aimed at extracting what are now officially dubbed “critical minerals” — substances of significant strategic and economic importance to the future of national economies.

Lac-des-Îles is the only significant graphite mining project in North America, accounting for Canada’s contribution to an industry dominated by China.

There was another proposed graphite mine in Québec, which encountered significant push back from the local Indigenous community as noted in my November 26, 2024 posting, “Local resistance to Lomiko Metals’ Outaouais graphite mine.” The posting also provides a very brief update of graphite mining in Canada.

It seems to me that water does not get the attention that it should and that’s why I lead with water in my headline. Eric Reguly’s February 9, 2025 article in the Globe and Mail highlights some of the water issues facing the US, not just Iowa,

Water may be the real reason, or one of the top reasons, propelling his [Mr. Trump’s] desire to turn Canada into Minnesota North. Canadians represent 0.5 per cent of the globe’s population yet sit on 20% or more of its fresh water. Vast tracts of the United States routinely suffer from water shortages, which are drying up rivers – the once mighty Colorado River no longer reaches the Pacific Ocean – shrinking aquifers beneath farmland and preventing water-intensive industries from building factories. Warming average temperatures will intensify the shortages. [p. B2 in paper version]

Reguly is more interested in the impact water shortages have on industry. He also offers a brief history of US interest in acquiring Canadian water resources dating back to the first North America Free Trade Agreement (NAFTA) that came into effect on January 1, 1994.

A March 6, 2024 article by Elia Nilsen for CNN television news online details Colorado river geography and gives you a sense of just how serious the situation is, Note: Links have been removed,

Seven Western states are starting to plot a future for how much water they’ll draw from the dwindling Colorado River in a warmer, drier world.

The river is the lifeblood for the West – providing drinking water for tens of millions, irrigating crops, and powering homes and industry with hydroelectric dams.

This has bought states more time to figure out how to divvy up the river after 2026, when the current operating guidelines expire.

To that end, the four upper basin river states of Colorado, Utah, New Mexico and Wyoming submitted their proposal for how future cuts should be divvied up among the seven states to the federal government on Tuesday [March 5, 2024], and the three lower basin states of California, Arizona and Nevada submitted their plan on Wednesday [March 6, 2024].

One thing is clear from the competing plans: The two groups of states do not agree so far on who should bear the brunt of future cuts if water levels drop in the Colorado River basin.

As of a December 12, 2024 article by Shannon Mullane for watereducationcolorado.org, the states are still wrangling and they are not the only interested parties, Note: A link has been removed,

… officials from seven states are debating the terms of a new agreement for how to store, release and deliver Colorado River water for years to come, and they have until 2026 to finalize a plan. This month, the tone of the state negotiations soured as some state negotiators threw barbs and others called for an end to the political rhetoric and saber-rattling.

The state negotiators are not the only players at the table: Tribal leaders, federal officials, environmental organizations, agricultural groups, cities, industrial interests and others are weighing in on the process.

Water use from the Colorado river has international implications as this February 5, 2025 essay (Water is the other US-Mexico border crisis, and the supply crunch is getting worse) by Gabriel Eckstein, professor of law at Texas A&M University and Rosario Sanchez, senior research scientist at Texas Water Resources Institute and at Texas A&M University for The Conversation makes clear, Note: Links have been removed,

The Colorado River provides water to more than 44 million people, including seven U.S. and two Mexican states, 29 Indian tribes and 5.5 million acres of farmland. Only about 10% of its total flow reaches Mexico. The river once emptied into the Gulf of California, but now so much water is withdrawn along its course that since the 1960s it typically peters out in the desert.

At least 28 aquifers – underground rock formations that contain water – also traverse the border. With a few exceptions, very little information on these shared resources exists. One thing that is known is that many of them are severely overtapped and contaminated.

Nonetheless, reliance on aquifers is growing as surface water supplies dwindle. Some 80% of groundwater used in the border region goes to agriculture. The rest is used by farmers and industries, such as automotive and appliance manufacturers.

Over 10 million people in 30 cities and communities throughout the border region rely on groundwater for domestic use. Many communities, including Ciudad Juarez; the sister cities of Nogales in both Arizona and Sonora; and the sister cities of Columbus in New Mexico and Puerto Palomas in Chihuahua, get all or most of their fresh water from these aquifers.

A booming region

About 30 million people live within 100 miles (160 kilometers) of the border on both sides. Over the next 30 years, that figure is expected to double.

Municipal and industrial water use throughout the region is also expected to increase. In Texas’ lower Rio Grande Valley, municipal use alone could more than double by 2040.

At the same time, as climate change continues to worsen, scientists project that snowmelt will decrease and evaporation rates will increase. The Colorado River’s baseflow – the portion of its volume that comes from groundwater, rather than from rain and snow – may decline by nearly 30% in the next 30 years.

Precipitation patterns across the region are projected to be uncertain and erratic for the foreseeable future. This trend will fuel more extreme weather events, such as droughts and floods, which could cause widespread harm to crops, industrial activity, human health and the environment.

Further stress comes from growth and development. Both the Colorado River and Rio Grande are tainted by pollutants from agricultural, municipal and industrial sources. Cities on both sides of the border, especially on the Mexican side, have a long history of dumping untreated sewage into the Rio Grande. Of the 55 water treatment plants located along the border, 80% reported ongoing maintenance, capacity and operating problems as of 2019.

Drought across the border region is already stoking domestic and bilateral tensions. Competing water users are struggling to meet their needs, and the U.S. and Mexico are straining to comply with treaty obligations for sharing water [emphasis mine].

Getting back to Canada and water, Reguly’s February 9, 2025 article notes Mr. Trump’s attitude towards our water,

Mr. Trump’s transaction-oriented brain know that water availability translates into job availability. If Canada were forced to export water by bulk to the United States, Canada would in effect be exporting jobs and America absorbing them. In the fall [2024] when he was campaigning, he called British Columbia “essentially a very large faucet” [emphasis mine] that could be used to overcome California’s permanent water deficit.

In Canada’s favour, Canadians have been united in their opposition to bulk water exports. That sentiment is codified in the Transboundary Waters Protection Act, which bans large scale removal from waterways shared with the United States. … [p. B2 in paper version]

It’s reassuring to read that we have some rules regarding water removal but British Columbia also has a water treaty with the US, the Columbia River Treaty, and an update to it lingers in limbo as Kirk Lapointe notes in his February 6, 2025 article for vancouverisawesome.com. Lapointe mentions shortcomings on both sides of the negotiating table for the delay in ratifying the update while expressing concern over Mr. Trump’s possible machinations should this matter cross his radar.

What about Ukraine’s critical mineral?

A February 13, 2025 article by Geoff Nixon for CBC news online provides some of the latest news on the situation between the US and the Ukraine, Note: Links have been removed,

Ukraine has clearly grabbed the attention of U.S. President Donald Trump with its apparent willingness to share access to rare-earth resources with Washington, in exchange for its continued support and security guarantees.

Trump wants what he calls “equalization” for support the U.S. has provided to Ukraine in the wake of Russia’s full-scale invasion. And he wants this payment in the form of Ukraine’s rare earth minerals, metals “and other things,” as the U.S. leader put it last week.

U.S. Treasury Secretary Scott Bessent has travelled to Ukraine to discuss the proposition, which was first raised with Trump last fall [2024], telling reporters Wednesday [February 12, 2025] that he hoped a deal could be reached within days.

Bessent says such a deal could provide a “security shield” in post-war Ukraine. Ukrainian President Volodymyr Zelenskyy, meanwhile, said in his daily address that it would both strengthen Ukraine’s security and “give new momentum to our economic relations.”

But just how much trust can Kyiv put in a Trump-led White House to provide support to Ukraine, now and in the future? Ukraine may not be in a position to back away from the offer, with Trump’s interest piqued and U.S. support remaining critical for Kyiv after nearly three years of all-out war with Russia.

“I think the problem for Ukraine is that it doesn’t really have much choice,” said Oxana Shevel, an associate professor of political science at Boston’s Tufts University.

Then there’s the issue of the Ukrainian minerals, which have to remain in Kyiv’s hands in order for the U.S. to access them — a point Zelenskyy and other Ukraine officials have underlined.

There are more than a dozen elements considered to be rare earths, and Ukraine’s Institute of Geology says those that can be found in Ukraine include lanthanum, cerium, neodymium, erbium and yttrium. EU-funded research also indicates that Ukraine has scandium reserves. But the details of the data are classified.

Rare earths are used in manufacturing magnets that turn power into motion for electric vehicles, in cellphones and other electronics, as well as for scientific and industrial applications.

Trump has said he wants the equivalent of $500 billion US in rare earth minerals.

Yuriy Gorodnichenko, a professor of economics at the University of California, Berkeley, says any effort to develop and extract these resources won’t happen overnight and it’s unclear how plentiful they are.

“The fact is, nobody knows how much you have for sure there and what is the value of that,” he said in an interview.

“It will take years to do geological studies,” he said. “Years to build extraction facilities.” 

Just how desperate is the US?

Yes, the United States has oil but it doesn’t have much in the way of materials it needs for the new technologies and it’s running out of something very basic: water.

I don’t know how desperate the US is but Mr. Trump’s flailings suggest that the answer is very, very desperate.

*ETA February 18, 2025: For anyone interested in more information about water, Canada, and the US, Joel Dryden’s February 18, 2025 article, “Trump’s musings on ‘very large faucet’ in Canada part of looming water crisis, say researchers” for CBC news online, which offers more information about the situation.

FrogHeart’s 2024 comes to an end as 2025 comes into view

First, thank you to anyone who’s dropped by to read any of my posts. Second, I didn’t quite catch up on my backlog in what was then the new year (2024) despite my promises. (sigh) I will try to publish my drafts in a more timely fashion but I start this coming year as I did 2024 with a backlog of two to three months. This may be my new normal.

As for now, here’s an overview of FrogHeart’s 2024. The posts that follow are loosely organized under a heading but many of them could fit under other headings as well. After my informal review, there’s some material on foretelling the future as depicted in an exhibition, “Oracles, Omens and Answers,” at the Bodleian Libraries, University of Oxford.

Human enhancement: prosthetics, robotics, and more

Within a year or two of starting this blog I created a tag ‘machine/flesh’ to organize information about a number of converging technologies such as robotics, brain implants, and prosthetics that could alter our concepts of what it means to be human. The larger category of human enhancement functions in much the same way also allowing a greater range of topics to be covered.

Here are some of the 2024 human enhancement and/or machine/flesh stories on this blog,

Other species are also being rendered ‘machine/flesh’,

The year of the hydrogel?

It was the year of the hydrogel for me (btw, hydrogels are squishy materials; I have more of a description after this list),

As for anyone who’s curious about hydrogels, there’s this from an October 20, 2016 article by D.C.Demetre for ScienceBeta, Note: A link has been removed,

Hydrogels, materials that can absorb and retain large quantities of water, could revolutionise medicine. Our bodies contain up to 60% water, but hydrogels can hold up to 90%.

It is this similarity to human tissue that has led researchers to examine if these materials could be used to improve the treatment of a range of medical conditions including heart disease and cancer.

These days hydrogels can be found in many everyday products, from disposable nappies and soft contact lenses to plant-water crystals. But the history of hydrogels for medical applications started in the 1960s.

Scientists developed artificial materials with the ambitious goal of using them in permanent contact applications , ones that are implanted in the body permanently.

For anyone who wants a more technical explanation, there’s the Hydrogel entry on Wikipedia.

Science education and citizen science

Where science education is concerned I’m seeing some innovative approaches to teaching science, which can include citizen science. As for citizen science (also known as, participatory science) I’ve been noticing heightened interest at all age levels.

Artificial intelligence

It’s been another year where artificial intelligence (AI) has absorbed a lot of energy from nearly everyone. I’m highlighting the more unusual AI stories I’ve stumbled across,

As you can see, I’ve tucked in two tangentially related stories, one which references a neuromorphic computing story ((see my Neuromorphic engineering category or search for ‘memristors’ in the blog search engine for more on brain-like computing topics) and the other is intellectual property. There are many, many more stories on these topics

Art/science (or art/sci or sciart)

It’s a bit of a surprise to see how many art/sci stories were published here this year, although some might be better described as art/tech stories.

There may be more 2024 art/sci stories but the list was getting long. In addition to searching for art/sci on the blog search engine, you may want to try data sonification too.

Moving off planet to outer space

This is not a big interest of mine but there were a few stories,

A writer/blogger’s self-indulgences

Apparently books can be dangerous and not in a ‘ban [fill in the blank] from the library’ kind of way,

Then, there are these,

New uses for electricity,

Given the name for this blog, it has to be included,

  • Frog saunas published September 15, 2024, this includes what seems to be a mild scientific kerfuffle

I’ve been following Lomiko Metals (graphite mining) for a while,

Who would have guessed?

Another bacteria story,

New crimes,

Origins of life,

Dirt

While no one year features a large number of ‘dirt’ stories, it has been a recurring theme here throughout the years,

Regenerative medicine

In addition to or instead of using the ‘regenerative medicine’ tag, I might use ’tissue engineering’ or ’tissue scaffolding’,

To sum it up

It was an eclectic year.

Peering forward into 2025 and futurecasting

I expect to be delighted, horrified, thrilled, and left shaking my head by science stories in 2025. Year after year the world of science reveals a world of wonder.

More mundanely, I can state with some confidence that my commentary (mentioned in the future-oriented subsection of my 2023 review and 2024 look forward) on Quantum Potential, a 2023 report from the Council of Canadian Academies, will be published early in this new year as I’ve almost finished writing it.

As for more about the future, I’ve got this, from a December 3, 2024 essay (Five ways to predict the future from around the world – from spider divination to bibliomancy) about an exhibition by Michelle Aroney (Research Fellow in Early Modern History, University of Oxford) and David Zeitlyn (Professor of Social Anthropology, University of Oxford) in The Conversation (h/t December 3, 2024 news item on phys.org), Note: Links have been removed

Some questions are hard to answer and always have been. Does my beloved love me back? Should my country go to war? Who stole my goats?

Questions like these have been asked of diviners around the world throughout history – and still are today. From astrology and tarot to reading entrails, divination comes in a wide variety of forms.

Yet they all address the same human needs. They promise to tame uncertainty, help us make decisions or simply satisfy our desire to understand.

Anthropologists and historians like us study divination because it sheds light on the fears and anxieties of particular cultures, many of which are universal. Our new exhibition at Oxford’s Bodleian Library, Oracles, Omens & Answers, explores these issues by showcasing divination techniques from around the world.

1. Spider divination

In Cameroon, Mambila spider divination (ŋgam dù) addresses difficult questions to spiders or land crabs that live in holes in the ground.

Asking the spiders a question involves covering their hole with a broken pot and placing a stick, a stone and cards made from leaves around it. The diviner then asks a question in a yes or no format while tapping the enclosure to encourage the spider or crab to emerge. The stick and stone represent yes or no, while the leaf cards, which are specially incised with certain meanings, offer further clarification.

2. Palmistry

Reading people’s palms (palmistry) is well known as a fairground amusement, but serious forms of this divination technique exist in many cultures. The practice of reading the hands to gather insights into a person’s character and future was used in many ancient cultures across Asia and Europe.

In some traditions, the shape and depth of the lines on the palm are richest in meaning. In others, the size of the hands and fingers are also considered. In some Indian traditions, special marks and symbols appearing on the palm also provide insights.

Palmistry experienced a huge resurgence in 19th-century England and America, just as the science of fingerprints was being developed. If you could identify someone from their fingerprints, it seemed plausible to read their personality from their hands.

3. Bibliomancy

If you want a quick answer to a difficult question, you could try bibliomancy. Historically, this DIY [do-it-yourself] divining technique was performed with whatever important books were on hand.

Throughout Europe, the works of Homer or Virgil were used. In Iran, it was often the Divan of Hafiz, a collection of Persian poetry. In Christian, Muslim and Jewish traditions, holy texts have often been used, though not without controversy.

4. Astrology

Astrology exists in almost every culture around the world. As far back as ancient Babylon, astrologers have interpreted the heavens to discover hidden truths and predict the future.

5. Calendrical divination

Calendars have long been used to divine the future and establish the best times to perform certain activities. In many countries, almanacs still advise auspicious and inauspicious days for tasks ranging from getting a haircut to starting a new business deal.

In Indonesia, Hindu almanacs called pawukon [calendar] explain how different weeks are ruled by different local deities. The characteristics of the deities mean that some weeks are better than others for activities like marriage ceremonies.

You’ll find logistics for the exhibition in this September 23, 2024 Bodleian Libraries University of Oxford press release about the exhibit, Note: Links have been removed,

Oracles, Omens and Answers

6 December 2024 – 27 April 2025
ST Lee Gallery, Weston Library

The Bodleian Libraries’ new exhibition, Oracles, Omens and Answers, will explore the many ways in which people have sought answers in the face of the unknown across time and cultures. From astrology and palm reading to weather and public health forecasting, the exhibition demonstrates the ubiquity of divination practices, and humanity’s universal desire to tame uncertainty, diagnose present problems, and predict future outcomes.

Through plagues, wars and political turmoil, divination, or the practice of seeking knowledge of the future or the unknown, has remained an integral part of society. Historically, royals and politicians would consult with diviners to guide decision-making and incite action. People have continued to seek comfort and guidance through divination in uncertain times — the COVID-19 pandemic saw a rise in apps enabling users to generate astrological charts or read the Yijing [I Ching], alongside a growth in horoscope and tarot communities on social media such as ‘WitchTok’. Many aspects of our lives are now dictated by algorithmic predictions, from e-health platforms to digital advertising. Scientific forecasters as well as doctors, detectives, and therapists have taken over many of the societal roles once held by diviners. Yet the predictions of today’s experts are not immune to criticism, nor can they answer all our questions.

Curated by Dr Michelle Aroney, whose research focuses on early modern science and religion, and Professor David Zeitlyn, an expert in the anthropology of divination, the exhibition will take a historical-anthropological approach to methods of prophecy, prediction and forecasting, covering a broad range of divination methods, including astrology, tarot, necromancy, and spider divination.

Dating back as far as ancient Mesopotamia, the exhibition will show us that the same kinds of questions have been asked of specialist practitioners from around the world throughout history. What is the best treatment for this illness? Does my loved one love me back? When will this pandemic end? Through materials from the archives of the Bodleian Libraries alongside other collections in Oxford, the exhibition demonstrates just how universally human it is to seek answers to difficult questions.

Highlights of the exhibition include: oracle bones from Shang Dynasty China (ca. 1250-1050 BCE); an Egyptian celestial globe dating to around 1318; a 16th-century armillary sphere from Flanders, once used by astrologers to place the planets in the sky in relation to the Zodiac; a nineteenth-century illuminated Javanese almanac; and the autobiography of astrologer Joan Quigley, who worked with Nancy and Ronald Reagan in the White House for seven years. The casebooks of astrologer-physicians in 16th- and 17th-century England also offer rare insights into the questions asked by clients across the social spectrum, about their health, personal lives, and business ventures, and in some cases the actions taken by them in response.

The exhibition also explores divination which involves the interpretation of patterns or clues in natural things, with the idea that natural bodies contain hidden clues that can be decrypted. Some diviners inspect the entrails of sacrificed animals (known as ‘extispicy’), as evidenced by an ancient Mesopotamian cuneiform tablet describing the observation of patterns in the guts of birds. Others use human bodies, with palm readers interpreting characters and fortunes etched in their clients’ hands. A sketch of Oscar Wilde’s palms – which his palm reader believed indicated “a great love of detail…extraordinary brain power and profound scholarship” – shows the revival of palmistry’s popularity in 19th century Britain.

The exhibition will also feature a case study of spider divination practised by the Mambila people of Cameroon and Nigeria, which is the research specialism of curator Professor David Zeitlyn, himself a Ŋgam dù diviner. This process uses burrowing spiders or land crabs to arrange marked leaf cards into a pattern, which is read by the diviner. The display will demonstrate the methods involved in this process and the way in which its results are interpreted by the card readers. African basket divination has also been observed through anthropological research, where diviners receive answers to their questions in the form of the configurations of thirty plus items after they have been tossed in the basket.

Dr Michelle Aroney and Professor David Zeitlyn, co-curators of the exhibition, say:

Every day we confront the limits of our own knowledge when it comes to the enigmas of the past and present and the uncertainties of the future. Across history and around the world, humans have used various techniques that promise to unveil the concealed, disclosing insights that offer answers to private or shared dilemmas and help to make decisions. Whether a diviner uses spiders or tarot cards, what matters is whether the answers they offer are meaningful and helpful to their clients. What is fun or entertainment for one person is deadly serious for another.

Richard Ovenden, Bodley’s [a nickname? Bodleian Libraries were founded by Sir Thomas Bodley] Librarian, said:

People have tried to find ways of predicting the future for as long as we have had recorded history. This exhibition examines and illustrates how across time and culture, people manage the uncertainty of everyday life in their own way. We hope that through the extraordinary exhibits, and the scholarship that brings them together, visitors to the show will appreciate the long history of people seeking answers to life’s biggest questions, and how people have approached it in their own unique way.

The exhibition will be accompanied by the book Divinations, Oracles & Omens, edited by Michelle Aroney and David Zeitlyn, which will be published by Bodleian Library Publishing on 5 December 2024.

Courtesy: Bodleian Libraries, University of Oxford

I’m not sure why the preceding image is used to illustrate the exhibition webpage but I find it quite interesting. Should you be in Oxford, UK and lucky enough to visit the exhibition, there are a few more details on the Oracles, Omens and Answers event webpage, Note: There are 26 Bodleian Libraries at Oxford and the exhibition is being held in the Weston Library,

EXHIBITION

Oracles, Omens and Answers

6 December 2024 – 27 April 2025

ST Lee Gallery, Weston Library

Free admission, no ticket required

Note: This exhibition includes a large continuous projection of spider divination practice, including images of the spiders in action.

Exhibition tours

Oracles, Omens and Answers exhibition tours are available on selected Wednesdays and Saturdays from 1–1.45pm and are open to all.

These free gallery tours are led by our dedicated volunteer team and places are limited. Check available dates and book your tickets.

You do not need to book a tour to visit the exhibition. Please meet by the entrance doors to the exhibition at the rear of Blackwell Hall.

Happy 2025! And, once again, thank you.

Effects of soil contamination could be blunted with nanonutrients

An October 15, 2024 news item on phys.org highlights research into soil remediation, Note: A link has been removed,

One of the pressing problems that the world faces in the era of climate change is how to grow enough healthy food to meet the increasing global population, even as soil contamination rises. Research recently published in Nature Food by an international team of scientists led by the University of Massachusetts Amherst, Guangdong University of Technology, and Central South University of Forestry and Technology, has shown that nutrients on the nanometer scale can not only blunt some of the worst effects of heavy metal and metalloid contamination, but increase crop yields and nutrient content.

Caption: Nanomaterials can enter plants through above-ground tissues and root tissues. Soil rhizosphere microorganisms, soil particles, organic matter and rhizosphere deposits can also influence NM uptake in plants. Credit: 10.1038/s43016-024-01063-1 Courtesy of University of Massachusetts Amherst

An October 15, 2024 University of Massachusetts Amherst news release (also on EurekAlert), which originated the news item, describes the problem and the proposed solution, Note: Links have been removed,

“Much of the world’s arable soil is contaminated by heavy metals, like cadmium, lead and mercury, as well as metalloids, like arsenic and selenium,” says Baoshan Xing, University Distinguished Professor and director of the Stockbridge School of Agriculture at UMass Amherst. Xing, who is also the paper’s senior author, notes that such contamination puts severe stress on the ability to grow staple crops, which also affects the nutritional value of the crops that manage to survive. “We need to come up with solutions to reduce the heavy metals that wind up in our food,” says Xing, and one approach that has shown promise is the use of nutrients at nanoscale, or what he calls a “nano-enabled” agriculture.


The bulk fertilizers that you may be more familiar with are made up of large particles, which aren’t as readily absorbed by the crop. This means that farmers need to apply more, which then increases the levels of fertilizer runoff into streams, lakes and the ocean. However, crop nutrients at the nanometer scale can be specifically designed and mixed for particular crops, growing conditions and application methods, and engineered so that the target plant can most efficiently absorb the nutrients into its system, cutting down on the amount of fertilizer needed, keeping costs down and limiting runoff.

Though nanomaterials are already available on the agricultural market and have plenty of peer-reviewed science looking at their effect on the soil and crop growth, Xing and his colleagues’ research is the first comprehensive account of the effectiveness of nanomaterials as a class, with results that offer practical insights to help steer sustainable agriculture and global food safety.

“We collected data from 170 previous publications on the effectiveness of nanoparticles in reducing heavy metal and metalloid uptake,” says Chuanxin Ma, the paper’s co-lead author who completed his doctoral training at UMass Amherst’s Stockbridge School of Agriculture and is now a professor at China’s Guangdong University of Technology. “From those 170 papers, we collected 8,585 experimental observations of how plants respond to nanomaterials.”

The team then conducted a meta-analysis on this enormous trove of data, running it through a series of machine-learning models to quantify the effect of nanomaterials on crop growth and metal and metalloid uptake, before finally testing a flexible quantitative approach, known as the “IVIF-TOPSIS-EW method,” that can illuminate how to choose different types of nanomaterials according to a range of realistic agricultural scenarios.

The results show that nanomaterials are more effective than conventional fertilizers at mitigating the harmful effects of polluted soil (by 38.3%), can enhance crop yields (by 22.8%) and the nutritional value of those crops (by 30%), as well as combat plant stress (by 21.6%) due to metal and metalloid pollution. Nanomaterials also help increase soil enzymes and organic carbon, both of which help drive soil fertility.

“Of course, nanomaterials are not a silver bullet,” explains Xing. “They need to be applied in distinct ways based on the individual crop and soil.” Which is where the team’s IVIF-TOPSIS-EW method comes into play. “Our method can help policy makers choose the best course of action for their particular situation,” says Ma.

Yini Cao from Central South University of Forestry and Technology also contributed greatly to collecting and analyzing the data in this work.

This research was supported by the National Natural Science Foundation of China and the United States National Institute of Food and Agriculture (USDA).

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

Engineered nanomaterials reduce metal(loid) accumulation and enhance staple food production for sustainable agriculture by Yini Cao, Chuanxin Ma, Jason C. White, Yuchi Cao, Fan Zhang, Ran Tong, Hao Yu, Yi Hao, Wende Yan, Melanie Kah & Baoshan Xing. Nature Food volume 5, pages 951–962 (2024) DOI: https://doi.org/10.1038/s43016-024-01063-1 Published: 11 October 2024 Issue Date: November 2024

This paper is behind a paywall.

Enhancing plant tolerance for high salt levels in soil

Soil with high concentrations of salt is not considered good for growing plants and that may become more of a problem as researchers seek to create greater global food security in the coming decades. From an August 7, 2024 news item on phys.org,

Soil salt concentrations above the optimal threshold for plant growth can threaten global food security by compromising agricultural productivity and crop quality. An analysis published in Physiologia Plantarum has examined the potential of nanomaterials—which have emerged over the past decade as a promising tool to mitigate such “salinity stress”—to address this challenge.

An August 7, 2024 Wiley (publisher) news release (also on EurekAlert) provides a few more details about an assessment (meta-analysis) of how nanomaterials could be helpful,

Nanomaterials, which are tiny natural or synthetic materials, can modulate a plant’s response to salinity stress through various mechanisms, for example by affecting the expression of genes related to salt tolerance or by enhancing physiological processes such as antioxidant activities.

When investigators assessed 495 experiments from 70 publications related to how different nanomaterials interact with plants under salinity stress, they found that nanomaterials enhance plant performance and mitigate salinity stress when applied at lower dosages. At higher doses, however, nanomaterials are toxic to plants and may even worsen salinity stress.

Also, plant responses to nanomaterials vary across plant species, plant families, and nanomaterial types.

“Our analysis revealed that plants respond more positively to nanomaterials under salt stress compared with non-stressed conditions, indicating the ameliorative role of nanomaterials,” said corresponding author Damiano R. Kwaslema, MSc, of Sokoine University of Agriculture, in Tanzania. “These findings pave the way for considering nanomaterials as a future option for managing salinity stress.”

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

Meta-analysis of nanomaterials and plants interaction under salinity stress by Damiano R. Kwaslema, Paulo Sulle Michael. Physiologia Plantarium Volume176, Issue4 July/August 2024 e14445 DOI: https://doi.org/10.1111/ppl.14445 First published: 07 August 2024

This paper is behind a paywall.

More dirt from Saskatoon’s synchrotron (Canadian Light Source)

Apparently, dirt is not welcome at most synchrotrons (also known as light sources) as was noted in my November 13, 2022 posting about Saskatoon’s synchrotron being used to analyze some soil from Hawaii. This time, according to a September 4, 2024 Canadian Light Source (CLS) news release by Rowan Hollinger (also received via email), the soil is from Kansas and there appears to be a second synchroton involved in this research,

With carbon dioxide levels in the atmosphere increasing in recent decades, there is a growing urgency to find strategies for capturing and holding carbon.

Researchers from Kansas State University (K-State) are exploring how different farming practices can affect the amount of carbon that gets stored in soil. Using the Canadian Light Source (CLS) at the University of Saskatchewan (USask) and the Advanced Light Source in Berkeley, California, they analyzed soil from a cornfield in Kansas that had been farmed with no tilling for the past 22 years. During that time, the farm used a variety of different soil nitrogen management practices, including no fertilizer, chemical fertilizer, and manure/compost fertilizer.

“We were trying to understand what the mechanisms are behind increasing soil carbon storage using certain management practices,” says Dr. Ganga Hettiarachchi, professor of soil and environmental chemistry at Kansas State University. “We were looking at not just soil carbon, but other soil minerals that are going to help store carbon.”

As has been shown in other studies, the K-state researchers found that the soil enhanced (treated) with manure or compost fertilizer stores more carbon than soil that received either chemical fertilizer or no fertilizer. More exciting though, says Hettiarachchi, the ultrabright synchrotron light enabled them to see how the carbon gets stored: they found that it was preserved in pores and some carbon had attached itself to minerals in the soil.

The team also found that the soil treated with manure or compost contained more microbial carbon, an indication that these enhancements support more microorganisms and their activities in the soil. In addition, they identified special minerals in the soil, evidence Hettiarachchi says, that the treatments contribute to active chemical and biological processes.

“To my knowledge, this is the first direct evidence of mechanisms through which organic enhancements improve soil health, microbial diversity, and carbon sequestration.”

Because synchrotron imaging is non-destructive, the K-state researchers were able to observe what was going on in soil aggregate (clumps) without having to break up the soil; essentially, they were looking at the carbon chemistry in its natural state.

“Collectively, studies like this are going to help us to move forward to more sustainable, more regenerative agriculture practices that will protect our soils and environment as well as help feed growing populations, says Hettiarachchi. “As well, understanding the role of the different minerals, chemicals, and microbes involved will help improve models for predicting how different farming practices affect soil carbon storage.”

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

Direct evidence on the impact of organic amendments on carbon stabilization in soil microaggregates by Pavithra S. Pitumpe Arachchige, Ganga M. Hettiarachchi, Charles W. Rice, James J. Dynes, Leila Maurmann, A. L. David Kilcoyne, Chammi P. Attanayake. Soil Science Society of America Journal (2024) DOI: https://doi.org/10.1002/saj2.20701 First published: 21 June 2024

This paper is behind a paywall.

Nano-enabled precision delivery methods for agriculture

A July 23, 2024 news item on Nanowerk provides an introduction to nanoparticles and their potential use in agriculture, Note: Links have been removed,

Nanoparticles could potentially help address agricultural and environmental sustainability issues on a global scale.

Those issues include rising food demand, increasing greenhouse gas emissions generated by agricultural activities, climbing costs of agrochemicals, reducing crop yields induced by climate change, and degrading soil quality. A class of nanoscale particles called “nanocarriers” could make crop agriculture more sustainable and resilient to climate change, according to a group of specialists that includes Kurt Ristroph, assistant professor of agricultural and biological engineering at Purdue University.

“Saying ‘nanoparticle’ means different things to different people,” Ristroph said. In nanodrug delivery, a nanoparticle usually ranges in size from 60 to 100 nanometers and is made of lipids or polymers. “In the environmental world, a nanoparticle usually means a 3- to 5-nanometer metal oxide colloid. Those are not the same thing, but people use ‘nanoparticle’ for both.”

Ristroph helped organize a 2022 interdisciplinary workshop on nanomethods for drug delivery in plants. Funded by the National Science Foundation and the U.S. Department of Agriculture, the workshop was attended by 30 participants from academia, industry and government laboratories.

Many of the workshop participants, including Ristroph, have now published their conclusions in Nature Nanotechnology (“Towards realizing nano-enabled precision delivery in plants”). Their article reviews the possibility nanocarriers could make crop agriculture more sustainable and resilient to climate change.

A July 23, 2024 Purdue University news release (also on EurekAlert but published July 19, 2024) by Steve Koppes, which originated the news item, delves further into the topic of how agriculture could be made more sustainable with nanotechnology-enabled delivery methods, Note: Links have been removed,

“Nano-enabled precision delivery of active agents in plants will transform agriculture, but there are critical technical challenges that we must first overcome to realize the full range of its benefits,” said the article’s co-lead author Greg Lowry, the Walter J. Blenko, Sr. Professor of Civil and Environmental Engineering at Carnegie Mellon University. “I’m optimistic about the future of plant nanobiotechnology approaches and the beneficial impacts it will have on our ability to sustainably produce food.”

Plant cells and human cells have major physiological differences. Plant cells have a cell wall while human cells don’t, for example. But certain tools can be transferred from nanomedicine to plant applications.

“People have developed tools for studying the bio-corona formation around nanoparticles in an animal. We could think about bringing some of those tools to bear on nanoparticles in plants,” Ristroph said. 

When nanoparticles are injected into the bloodstream, many components of the blood stick onto the surface of the nanoparticles. The various proteins sticking to a nanoparticle’s surface make it look different.

The task then becomes figuring out what proteins or other molecules will stick to the surface and where the particle will go as a result. A nanoparticle designed to move toward a certain organ may have its destination altered by white blood cells that detect the particle’s surface proteins and send it to a different organ.

“Broadly speaking, that’s the idea of bio-corona formation and trafficking,” Ristroph said. “People in drug delivery nanomedicine have been thinking about and developing tools for studying that kind of thing. Some of those thoughts and some of those tools could be applied to plants.” 

Researchers already have developed many different architectures and chemistries for making nanoscale delivery vehicles for nanomedicine. “Some of the particle types are transferable,” he said. “You can take a nanoparticle that was optimized for movement in humans and put it in a plant, and you’ll probably find that it needs to be redesigned at least somewhat.”

Ristroph focuses on organic (carbon-based) nanocarriers that have a core-shell structure. The core contains a payload, while the shell forms a protective outer layer. Researchers have used many different types of nanomaterial in plants. The most popular materials are metallic nanoparticles because they are somewhat easier to make, handle and track where they go in a plant than organic nanoparticles.

“One of the first questions that you want to figure out is where these nanoparticles go in a plant,” Ristroph said. “It’s a lot easier to detect a metal inside of a plant that’s made of carbon than it is to detect a carbon-based nanoparticle in a plant that’s made of carbon.”

Last March, Ristroph and Purdue PhD student Luiza Stolte Bezerra Lisboa Oliveira published a critical review of the research literature on the Uptake and Translocation of Organic Nanodelivery Vehicles in Plants in Environmental Science and Technology.

“Not a lot is understood about transformations after these things go into a plant, how they’re getting metabolized,” Ristroph said. His team is interested in studying that, along with ways to help ensure that the nanoparticles are delivered to their proper destinations, and in corona formation. Coronas are biomolecular coatings that affect nanoparticle functions. 

The manufacturability of nanocarriers is another interest area that could be transferred to agriculture from nanomedicine.

“I care a lot about manufacturability and making sure that whatever techniques we’re using to make the nanoparticles are scalable and economically feasible,” Ristroph said.

The manufacturability of nanocarriers is another interest area that could be transferred to agriculture from nanomedicine.

“I care a lot about manufacturability and making sure that whatever techniques we’re using to make the nanoparticles are scalable and economically feasible,” Ristroph said.

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

Towards realizing nano-enabled precision delivery in plants by Gregory V. Lowry, Juan Pablo Giraldo, Nicole F. Steinmetz, Astrid Avellan, Gozde S. Demirer, Kurt D. Ristroph, Gerald J. Wang, Christine O. Hendren, Christopher A. Alabi, Adam Caparco, Washington da Silva, Ivonne González-Gamboa, Khara D. Grieger, Su-Ji Jeon, Mariya V. Khodakovskaya, Hagay Kohay, Vivek Kumar, Raja Muthuramalingam, Hanna Poffenbarger, Swadeshmukul Santra, Robert D. Tilton & Jason C. White. Nature Nanotechnology (2024) DOI: https://doi.org/10.1038/s41565-024-01667-5 Published: 06 June 2024

This paper is behind a paywall.

Wearable air curtain (an invisible mask) kills viruses and blocks 99.8% of aerosols

If you are vegetarian or vegan or have some objections to animal processing plants, this video is most likely not for you,

A July 8, 2024 University of Michigan news release (also on EurekAlert) describe a technology primarily designed for use by agricultural and industrial workers,

An air curtain shooting down from the brim of a hard hat can prevent 99.8% of aerosols from reaching a worker’s face. The technology, created by University of Michigan startup Taza Aya, potentially offers a new protection option for workers in industries where respiratory disease transmission is a concern.

Independent, third-party testing of Taza Aya’s device showed the effectiveness of the air curtain, curved to encircle the face, coming from nozzles at the hat’s brim. But for the air curtain to effectively protect against pathogens in the room, it must first be cleansed of pathogens itself. Previous research by the group of Taza Aya co-founder Herek Clack, U-M associate professor of civil and environmental engineering, showed that their method can remove and kill 99% of airborne viruses in farm and laboratory settings. 

“Our air curtain technology is precisely designed to protect wearers from airborne infectious pathogens, using treated air as a barrier in which any pathogens present have been inactivated so that they are no longer able to infect you if you breathe them in,” Clack said. “It’s virtually unheard of—our level of protection against airborne germs, especially when combined with the improved ergonomics it also provides.”

Fire has been used throughout history for sterilization, and while we might not usually think of it this way, it’s what’s known as a thermal plasma. Nonthermal, or cold, plasmas are made of highly energetic, electrically charged molecules and molecular fragments that achieve a similar effect without the heat. Those ions and molecules stabilize quickly, becoming ordinary air before reaching the curtain nozzles.

Taza Aya’s prototype features a backpack, weighing roughly 10 pounds, that houses the nonthermal plasma module, air handler, electronics and the unit’s battery pack. The handler draws air into the module, where it’s treated before flowing to the air curtain’s nozzle array.

Taza Aya’s progress comes in the wake of the COVID-19 pandemic and in the midst of a summer when the U.S. Centers for Disease Control and Prevention have reported four cases of humans testing positive for bird flu. During the pandemic, agriculture suffered disruptions in meat production due to shortages in labor, which had a direct impact on prices, the availability of some products and the extended supply chain.

In recent months, Taza Aya has conducted user experience testing with workers at Michigan Turkey Producers in Wyoming, Michigan, a processing plant that practices the humane handling of birds. The plant is home to hundreds of workers, many of them coming into direct contact with turkeys during their work day.

To date, paper masks have been the main strategy for protecting employees in such large-scale agriculture productions. But on a noisy production line, where many workers speak English as a second language, masks further reduce the ability of workers to communicate by muffling voices and hiding facial clues.

“During COVID, it was a problem for many plants—the masks were needed, but they prevented good communication with our associates,” said Tina Conklin, Michigan Turkey’s vice president of technical services.  

In addition, the effectiveness of masks is reliant on a tight seal over the mouth and noise to ensure proper filtration, which can change minute to minute during a workday. Masks can also fog up safety goggles, and they have to be removed for workers to eat. Taza Aya’s technology avoids all of those problems.

As a researcher at U-M, Clack spent years exploring the use of nonthermal plasma to protect livestock. With the arrival of COVID-19 in early 2020, he quickly pivoted to how the technology might be used for personal protection from airborne pathogens.

In October of that year, Taza Aya was named an awardee in the Invisible Shield QuickFire Challenge—a competition created by Johnson & Johnson Innovation in cooperation with the U.S. Department of Health and Human Services. The program sought to encourage the development of technologies that could protect people from airborne viruses while having a minimal impact on daily life.

“We are pleased with the study results as we embark on this journey,” said Alberto Elli, Taza Aya’s CEO. “This real-world product and user testing experience will help us successfully launch the Worker Wearable [Protection] in 2025.”

There’s a bit more information about the 3rd party testing mentioned at the start of the news release in a June 26, 2024 posting by Herek Clack on the Taza Aya company blog. You find out more about Worker and Individual Wearable Protection on Taza Aya’s The Solution webpage, scroll down abut 55% of the way.

Back to school: Stanford University (California) brings nanoscience to teachers and Ingenium brings STEAM to school

I have two stories that fit into the ‘back to school’ theme, one from Stanford University and one from Ingenium (Canada’s Museums of Science and Innovation).

Stanford, nanoscience, and middle school teachers

h/t to Google Alert of August 27, 2024 (received via email) for information about a Stanford University programme for middle school teachers. From an August 27, 2024 article in the Stanford Report, Note: Links have been removed,

Crafting holographic chocolate, printing with the power of the sun, and seeing behind the scenes of cutting-edge research at the scale of one-billionth of a meter, educators participating in the Nanoscience Summer Institute for Middle School Teachers (NanoSIMST) got to play the role of students, for a change.

Teachers hailed from the Bay Area and Southern California – one had even come all the way from Arkansas – for the professional development program. NanoSIMST, run by nano@stanford, is designed to connect middle school teachers with activities, skills, and knowledge about science at the scale of molecules and atoms so they can incorporate it into their curriculum. NanoSIMST also prioritizes teachers from Title I schools, which are low-income schools with low-income student populations that receive federal funding to improve academic achievement.

Debbie Senesky, the site investigator and principal researcher on the nano@stanford project, highlighted the importance of nanoscience at the university. “It’s not just about focusing on research – we also have bigger impacts on entrepreneurs, start-ups, community colleges, and other educators who can use these facilities,” said Senesky, who is also an associate professor of aeronautics and astronautics and of electrical engineering. “We’re helping to train the next generation of people who can be a workforce in the nanotechnology and semiconductor industry.”

The program also supports education and outreach, including through NanoSIMST, which uniquely reaches out to middle school teachers due to the STEM education outcomes that occur at that age. According to a 2009 report by the Lemelson-MIT InvenTeam Initiative, even among teens who were interested in and felt academically prepared in their STEM studies, “nearly two-thirds of teens indicated that they may be discouraged from pursuing a career in science, technology, engineering or mathematics because they do not know anyone who works in these fields (31%) or understand what people in these fields do (28%).”

A teacher from the Oakland Unified School District, Thuon Chen, connected several other teachers from OUSD to attend NanoSIMST as a first-time group. He emphasized that young kids, especially in middle school, have a unique way of approaching new technologies. “Kids have this sense where they’re always pushing things and coming up with completely new uses, so introducing them to a new technology can give them a lot to work with.”

Over the course of four days in the summer, NanoSIMST provides teachers with an understanding of extremely small science and technology: they go through tours of the nano facilities, speak with scientists, perform experiments that can be conducted in the classroom, and learn about careers in nanotechnology and the semiconductor industry.

Tara Hodge, the teacher who flew all the way from Arkansas, was thrilled about bringing what she learned back with her. “I’m not a good virtual learner, honestly. That’s why I came here. And I’m really excited to learn about different hands-on activities. Anything I can get excited about, I know I can get my students excited about.”

They have provided a video,

One comment regarding the host, Daniella Duran, the director of education and outreach for nano@stanford, she comments about nano being everywhere and, then, says “… everything has a microchip in it.” I wish she’d been a little more careful with the wording. Granted those microchips likely have nanoscale structures.

Ingenium’s STEAM (science, technology, engineering, arts, and mathematics) programmes for teachers across Canada

An August 27, 2024 Ingenium newsletter (received via email) lists STEAM resources being made available for teachers across the country.

There appears to be a temporary copy of the August 27, 2024 Ingenium newsletter here,

STEAM lessons made simple!

Another school year is about to begin, and whether you’re an experienced teacher or leading your first class, Ingenium has what you need to make your STEAM (science, technology, engineering, arts and math) lessons fun! With three museums of science and innovation – the Canada Agriculture and Food Museum, the Canada Aviation and Space Museum and the Canada Science and Technology Museum – under one umbrella, we are uniquely positioned to help your STEAM lessons come to life.

Embark on an exciting adventure with our bilingual virtual field trips and meet the animals in our barns, explore aviation technology, and conduct amazing science experiments.

Or take advantage of our FREE lesson plans, activities and resources to simplify and animate your classroom, all available in English and French. With Ingenium, innovation is at your fingertips!

Bring the museum to your classroom with a virtual field trip!

Can’t visit in person? Don’t worry, Ingenium will bring the museum to you! All of our virtual field trips are led by engaging guides who will animate each subject with an entertaining and educational approach. Choose from an array of bilingual programs designed for all learners that cover the spectrum of STEAM subjects, including the importance of healthy soil, the genetic considerations of a dairy farm operation, the science of flight, simple machines, climate change and the various states of matter. There is so much to discover with Ingenium. Book your virtual field trip today!

Here’s a video introduction to Ingenium’s offerings,

To get a look at all the resources, check out this temporary copy of the August 27, 2024 Ingenium newsletter here.