_____________________________________________________________________

LEAD Action News Volume 22 Number 4 December 2024 Page 11 of 131

Critical minerals: New Resources to help power the

Fall/Winter 2024

Cite as: Steinberg, N 2024. Critical

minerals: New resources to help power

the future. Strata magazine 7: 14-17.

Reprinted with kind permission of:

Nancy Steinberg

Director of Communications and

Marketing

some tiny pieces of the Earth that

probably came from deep

underground in various places

across the globe. Current— and

future — technologies, from iPhones to electric cars to wind turbines, require minerals

with unfamiliar names like wolframite, arsenopyrite and bastnaesite, which contain

tungsten, arsenic and rare earth elements, respectively. The lithium in lithium-ion

batteries comes from minerals like spodumene, lepidolite or hectorite. Circuitry requires

silicon and silver found in various types of ores. Electric vehicle batteries also require

lithium, as well as cobalt, manganese, nickel and a host of other elements, while

_____________________________________________________________________

LEAD Action News Volume 22 Number 4 December 2024 Page 12 of 131

be difficult to produce enough to keep pace with demand.3/9

The rise of green technologies offers the promise of a respite from, or even replacement

of, the use of fossil fuels, which we know drive not only our economies, but planet-

altering climate change. But, as the saying goes, there is no such thing as a free lunch:

Of course, resources are needed to build and operate green technologies, too. We

simply can’t construct electronics, batteries and other components without using

mineral resources of some kind. The trick will be to determine how to obtain them

responsibly, in a way that is minimally impactful to ecosystems and communities.

A new center at Oregon State University, the Center for Energy and Mineral Resources

for Resilient Societies, now under development and led by faculty in the College of

So which minerals are considered critical? It depends, explains Brian Tattitch, the

CEOAS Barrow Family Chair in Mineral Resource Geology and one of the driving forces

behind the new center. Some are critical now, and some are expected to become critical

as technologies evolve. While he largely agrees with the U.S. Department of Energy’s

criticality matrix (see Figure 1), which indicates which substances are considered critical

now and which ones are likely to become critical, he would tweak some of their

findings.4/9

_____________________________________________________________________

LEAD Action News Volume 22 Number 4 December 2024 Page 13 of 131

Figure 1: The U.S. Department of Energy’s criticality matrices for the short term (left)

some of the rare earths is growing as well, and the challenge is not that they are rare,

but that we are not mining them, while China has cornered control over supply and

processing. Keeping up with demand may become more difficult, as the mines that used

to produce them in small amounts are no longer operating, pushing more rare earths

into the “critical” category.

Beyond rare earths, a suite of other uncommon elements (like gallium) are equally

critical for modern technology, but the U.S. supply remains uncertain. What kinds of

domestic resources exist for these elements and how should we acquire them?

A good example is copper, which Tattitch thinks is more critical than the graphs in

Figure 1indicate. “Copper is not a headline-grabbing commodity, but it’s one of the few

things we don’t have a substitute for,” he explains. “Copper is not going to be easy to

_____________________________________________________________________

LEAD Action News Volume 22 Number 4 December 2024 Page 14 of 131

technologies is often problematic. Traditional mining rips apart the land surface,

rendering it useless for other activities like ranching or recreation. It can also leave

behind toxic tailings that contaminate soil and water. Research is underway to develop

methods that move away from open pit mining or other damaging techniques that

impact environmental, cultural and social resources, Tattitch explains.

For example, some of the minerals we need are found not in rocks, but dissolved in

geothermal fluids deep underground in geothermally active areas like central

Oregon.Tattitch describes techniques under development that would extract minerals by

sending fluids down into the rock via long pipes plumbed deep into the ground, and

sucking up the mineral-rich fluids from the other side of the mineral field. The footprint

Associate Professor Zhenxing Feng, employs electrically charged membranes to

separate desirable resources, including lithium, magnesium and green hydrogen, from

the brine waste that is usually sent back to the ocean. The only byproduct of their

process is clean water.

Tattitch is also excited about efforts that could actually improve environmental

conditions at abandoned or legacy mines where piles of mine waste (tailings) remain,

often leaching toxins into the environment. While those piles of rock were considered

waste when mining for more traditional resources was undertaken long ago (gold,

silver), they may still contain critical minerals that we now want. If properly incentivized,

companies might be interested in removing those tailings and processing them to gain

things like lithium, gallium and rare-earth elements. Pushing forward these kinds of

operations could help erase our legacy of damaging mining practices, while helping

develop a new critical mineral supply chain.

_____________________________________________________________________

LEAD Action News Volume 22 Number 4 December 2024 Page 15 of 131

while the center is in the earliest stages of development, he expects it to ultimately help

Oregon State become a leader in this vital area. He explains, “A center like this will

allow for synergy among different researchers who are focused on a range of aspects of

the issue. It will allow for us to attract funding, and to go farther than we could if we

simply continued each individual research program on its own.”

geologists and problem solvers how to think holistically about critical minerals, their

extraction, and their cradle-to-grave impacts on ecosystems and communities.

The center represents a great opportunity for us to have a space for everybody’s

voice on these issues. We can do things differently. We can do them better.–

Alyssa Shiel

Tattitch, Tepley and others in the center will continue to focus on research that seeks to

characterize mineral resources using geological and geophysical techniques, answering

questions about how, where and how often these mineral deposits form and how we

can find them.

Tepley’s work is a good example of how asking first-order geology questions will help

characterize these resources. He studies volcanic systems, many of which harbor

various types of critical minerals in their petrological guts. “You do some mapping, you

This type of work can be combined with more experimental approaches that Tattitch

uses, in which he simulates geothermal conditions in the lab to determine how minerals

initially form in those environments. He is currently building an experimental system

that will recreate ancient underground conditions of pressure and temperature similar to

Yellowstone geothermal springs or bubbling Cascadia magma reservoirs, where some

of the minerals of interest form. “One of the ways to we can determine how these

minerals were formed is by creating those conditions in the lab and then evaluating

_____________________________________________________________________

LEAD Action News Volume 22 Number 4 December 2024 Page 16 of 131

assessment of critical mineral resources funded by the U.S. Department of Energy.

Pieces of Oregon are located in two of the massive project’s designated regions; Tattitch

is hoping that the new OSU center can “serve as a hub to strengthen and link the

geologic, innovation and public outreach programs” in both of those assessments. In

fact, OSU faculty and students, along with agency and industry partners, are already

working on a very large lithium deposit that spans the border between Nevada and

Oregon, known on the Oregon side as the McDermitt deposit. This region could become

the largest source of lithium in the United States, indeed one of the largest in the world.

As the center grows, CEOAS geologists will collaborate with faculty in Oregon State’s

which are found very deep underground (5 km or deeper) and are very hot (more than

400oC). These systems harbor the promise of nearly unlimited efficient geothermal

_____________________________________________________________________

LEAD Action News Volume 22 Number 4 December 2024 Page 17 of 131

critical mineral mining. Community and policy issues that come up in relation to critical

mineral mining include appropriate siting of facilities, potential for economic

development in areas near mines, social and cultural impacts of mining and its

environmental risks. Hilary Boudet, associate professor in Oregon State’s School of

Public Policy, will use her deep expertise in the sociological and policy aspects of

Boudet anticipates that there will be a variety of interesting and important challenges to

“There is also a rural-urban divide here, where a lot of the mines will be proposed for

rural areas, but the outcomes will serve the broader society, maybe urban areas in

particular. So how do people’s backgrounds or their views on urban or rural issues

impact their thoughts on mining projects?” she adds.8/9

Through the interdisciplinary power of the center, Boudet hopes to ask questions that

will lead to conducting public engagement and policy development differently.