a16z Podcast - Mining the Data for Cobalt
Episode Date: June 29, 2022In this episode from July 2019, Kurt House, CEO and co-founder of Kobold Metals, John Thompson, professor of earth and geosciences at Cornell; and Connie Chan, a16z general partner for consumer, talk ...with editorial partner Hanne Winarsky about the way technology is transforming how we find cobalt, and the mining industry as a whole, as well as the science behind why cobalt is so critical for batteries, the data and knowledge behind mining today vs the past, and more.
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While many of us increasingly live in digital worlds, and even as software eats the world,
we still rely on a myriad of devices that depend on resources from the physical world.
One of the most important resources on the planet is cobalt, which is used in batteries, among other things.
In this episode from July 2019, Kurt House, CEO and co-founder of cobald metals,
John Thompson, professor of Earth and Geosciences at Cornell, and Connie Chan, a 16Z general partner
for consumer, talk with editorial partner Hannah Wernarski about the way technology is transforming
how we find cobalt and the mining industry as a whole, as well as the science behind why
cobalt is so critical for batteries, the data and knowledge behind mining today versus the past,
and more.
Hi and welcome to the A16Z podcast. I'm Hannah, and this episode is all about the exploration
for and mining of minerals, specifically cobalt. In this conversation, I'm joined by Kurt
House, CEO and co-founder of cobalt metals, Professor John Thompson of Earth and Geosciences at Cornell,
and A16Z general partner on the consumer team, Connie Chan.
We explain why it is that cobalt is suddenly one of the most important and in-demand metals on the planet
and how technology is transforming how we find it and the mining industry as a whole.
Along the way, we touch on a little bit of battery tech history and science,
and how entire chapters of human civilization are driven by the search for and mining of metals
from ancient civilization's first finding copper
to the major ground shift in the 1950s
with geophysics and knowledge of plate tectonics.
And finally, what kinds of new data sources,
technologies, and techniques we can use
to find more cobalt today,
everything from geophysical and geochemical data
to agricultural information,
to old boxes collected over centuries
in the basements and attics of mining companies.
All of this to satisfy the incredible new demand
as we enter a new age of battery metals.
why are we even sitting around this table talking about cobalt today? What is it that's suddenly so
interesting about cobalt? I think of it as a color as a price, right? Well, that's actually you're
right. And that was the very, very first use of cobalt. The very, very first use was in dyes.
And to get a particular type of blue, that was the principal way to do it. And when was it
discovered? The actual metal was first isolated as a metal. I'm pretty sure it's 1739.
So if you go back 15 years or so, its principal uses were.
were in high, sort of high strength steels and things like that. So cobalt demand sort of grew
gradually, but everybody listening to this podcast and presumably listening to this podcast on their
device has, has 10 grams of cobalt in, in that device about. Some might be listening from
their cars. That's true. Good point. In which case, if they happen to be driving an electric
vehicle, it could be closer to 10 or 20 kilograms of cobalt. It's the battery that uses the
it makes it makes the best batteries everyone knows they have a lithium you know sort of a lithium on
battery in their in their phone or uh but that's a it's a chemical reaction between lithium and
cobalt oxide and uh and so it's the two parts of the chemical reaction are essential and the
greatest energy density greatest uh greatest uh rate capability how fast you can charge and discharge
the battery uh greatest cycle life that kind of thing that has some or all cobalt in it why is
that can we get into the science of why that's the best battery the reason cobalt makes a great
battery is that the battery in your iPhone is what we call a lithium intercalation cathode.
That's a fancy name, but what it means is lithium is the mobile ion. So a battery is a battery has
an anode and a cathode and an ion that moves from the anode to the cathode to react
chemically and form a new molecule that's more stable. The cathode looks like kind of like a layered
sandwich. It has cobald oxide, then lithium, then lithium, then lithium, the cobald oxide.
It's like a layer cake.
A layer cake in a fully discharged sense.
You can imagine very intuitively why that's good
because the lithium has to get access to the cobalt.
So when you fully charge it,
when you push the lithium out of the cathode,
the lithium can intercalate into those spaces very easily.
And put simply, cobalt forms the most stable layered structures.
So as you pull lithium out, it doesn't sort of disorder or change.
And other similar metals tend to change.
And when they change, then you lose capacity.
your battery fades over time.
Basically, because it forms that really robust crystal structure,
it forms the longest lasting batteries.
And then it also has the sort of the greatest energy per molecule for lithium oxide battery.
And this is by orders of magnitude.
So, like, right next to lithium on the periodic table is nickel.
And if you made a nickel oxide, lithium nickel oxide battery, it would work okay.
But on your first cycle, it would have maybe 10% less energy density.
Over 100 cycles, then it would have maybe 50% less energy density.
energy density. So it really adds up. In the same age when you're shopping for your iPhone
battery life is one of the key things you think about. And especially with your electric
vehicle. And with your electric vehicle, right. It determines how long you can drive with a car.
The whole battery technology world is really interesting because it's such an important part
of our life now. So if you go back 50, 100 years, the lead acid battery, which is the first car
battery, which is still the dominant battery for starting lights and ignition, the SLA battery.
you know, once you've got an established battery that works that people trust, it's quite
hard to displace it.
So you've got to be convinced people with any new battery technology that it's going to deliver
the right amount of charge many, many times.
If you bought your phone and tomorrow had to go back to get a new battery, you wouldn't
be very happy.
Right.
This is where COBEL is a key piece of that puzzle because it offers a level of reliability that
it's going to be hard to, you know, to substitute.
To sum it up simply, it's the things you really care about are,
rate at which you can charge and discharge it, how much energy there is per unit mass and per unit
volume, and how long the battery, how long it lasted a single charge, and then how much that
charge fades over many cycles. And for all those, all those elements, Cobalt is Cobalt superior.
So we went from using it to make a pretty color, to suddenly needing it all around us.
You can almost define human history by the types of metals that we were pulling out of the
ground during that time. And in fact, if you look at the 8,000 years from the beginning of the
metal ages to about 1970, we produced a certain amount of metals. We pulled out the ground,
call that X. In the last 50 years, we pulled out the same amount again. So throughout all human history,
now we've pulled out two X. We reproduced it in last 50 years. In the next 30, we're going to
pull out another 2X just on current trends. Okay, that's the mass of material is coming out of the
ground. But here's the thing. The types of metals that we're pulling out of the ground are changing.
And they're changing for both society trends and society's needs, right? So in the next less than 100 years,
we have to rebuild the entire energy infrastructure of the world, some of that requires the types of metals that we've been pulling on the ground for a long time, but some of it requires totally new metals. And we need lots of new materials. We need lots of lithium. We need lots of manganese. We need lots of cobalt. If we're going to convert the entire automobile fleet to an electric fleet, we need vastly more cobalt than we've pulled out to date. And in order to that, we need to find new sources of cobalt, and that's what we do.
So how do you do that? The metal that we need is changing, and now we need cobalt. How is the way we
mine the way we source it changing too. And actually, let's go back and start earlier. What
does the history of mining cobalt look like? The act of exploration and discovery is a, is fundamentally
an information problem, right? And so the mineral exploration business is an incredibly old
industry. And it's essentially driven and been driven by the evolution of civilization.
Right. It's as old as humanity. It started pretty much with copper. And that's because people
have actually found copper, the metal sticking out of the ground. So they used it. They could
make it into different things and make it into ornaments and so on.
So this was the very beginnings of metallurgy as a science as a discipline.
It's very cool because they somehow, very creatively,
worked out how to extract metals from rocks that looked green
because they have copper in them but didn't obviously show the copper
until they were smelted effectively in a very hot fire.
And a fire that was a lot hotter than a campfire.
So somehow these people had figured out how to get the temperature of the fire
up to a level where it could reduce the copper-bary material and extract the metal from that.
And that's amazing.
So that's, you know, six, seven thousand years ago.
And that process of exploration back then just looked like kind of studying the land,
understanding and reading the earth around us.
I read an article recently about the Vikings and the Age of Iron and how the Vikings they think
were able to identify where the iron, the bog iron was through a kind of microbial sheen apparently.
It's all based on observation and then sort of correlation of different factors that were purely observation and experiential.
Effectively, that's the sort of original prospector, the person who could go into the ground and recognize that this had potential.
And that really was the way all expiration was done until about 1950.
They went to places where they could still observe the metals or the minerals then that they knew had the metals in,
even if they didn't understand exactly why or how or what the concentration was.
But oftentimes the minerals aren't sitting above the earth's...
No, not now.
They'd find it on the surface, and they'd keep mining down,
and originally they would mine down until they hit the water table,
and then they couldn't deal with it.
The Romans then started using wheels to actually de-water,
so they could then go deeper.
And the breakthrough in the Industrial Revolution was the steam engine,
which then allow them to make pumps
that then could take the water from much, much deeper level.
So at that point, then they could chase it further and farther.
But they didn't know where it was going.
They just followed it.
So the 1950s was when we started to develop technologies, remote technologies, geophysical
technologies that predict where things were going and predict where things might be.
Really recent, actually.
And what were those sort of different sources of information in the 1950s that changed,
that we started becoming aware of these new processes, Earth's processes?
So two, really.
One was what was called the plate tectonic revolution of the 1960s to 70s,
when people realized that the planet is dynamic and that, you know, the planet.
planet is descending off the west coast here of North America. The ocean plate is going beneath us
and that's giving us all earthquakes and volcanoes and so on. And simultaneously was the development
of geophysics. So the ability to detect the signature of the earth beneath the surface in terms
of its physical properties. So how magnetic it is, how dense it is, how conductive it is,
we started to be able to measure those things. Those measurements, the data comes from that
correlates in some cases with the presence of metals.
How much does it correlate?
How predictive was it really?
Poorly is the answer.
There were many false positives.
So we generated maps of magnetic signatures.
People would say there's all these fancy-looking anomalous bumps in the data,
and they'd drill them.
They put holes in the ground,
and it turned out the one in 100 would actually be interesting.
Incredible amount of investment and effort and tools.
Interesting.
And that hasn't changed.
We've got more and more tools now, but statistically, when we look at the chance of discovery,
our odds are still very low.
We're in thousands, one in thousand, one in five thousand.
Well, let's go back to Cobalt and talk about what that process has looked like for Cobalt,
because it hasn't, we haven't, there hasn't been a reason to invest a lot of discovery in
cobalt, right, up until this point, besides pretty pictures.
Right, that's right.
So one of the interesting things about cobalt in particular as a metal is that you have big copper mines
that are principally there because of copper.
And they also have a lot of copper
and a little bit of cobalt.
And that just happens to be
because cobalt and copper
tend to be...
Hang out together.
Yeah.
Not always, but in certain circumstances,
they do.
And so it was,
effectively, the marginal cost
to produce cobalt out of these mines
is very low.
A nice little extra perk.
It's an extra perk, right?
You would develop a mine anyway
if there was no cobalt there.
Right.
So you have this,
you have this sort of kind of gift
to the world.
We're going to invest in copper production
and we get a little more,
a little cobalt.
And same thing with nickel.
You get a lot of cobalt associated with nickel.
So that byproduct production of cobalt alongside copper and nickel was more than sufficient to supply the world up until now.
When you say more than sufficient, does that mean sometimes people didn't?
Absolutely.
So there's just piles of cobalt sitting around?
Even just in the last 15 years where copper mines were developed, the cobalt was well known, its presence was well known, and investment decisions were made not to extract the cobalt from the ore.
to extract the copper and to throw the cobalt into the tailings pile.
Why?
Because at the time, if you did make that investment and supplied that cobalt, it would have tanked the market.
Too much.
Because the demand was not there from the smartphones and the laptops and the electric cars yet.
Nobody needs it, quite literally.
Exactly.
Yeah.
Right.
Exactly.
And so now the whole situation has flipped.
Right.
So now all of those mine tailings that are full of cobalt and that are known are being
reprocessed or our investments are being made to go to go. So everyone that was sitting on a
garbage pile of cobalt is suddenly feeling good about it. Oh, absolutely. Yeah. In fact,
the largest, the two largest projects to come online in the next 18 to 24 months are exactly
that, our waste pile reprocessing projects. But in order to, you know, in order to convert the
entire global vehicle fleet to electric vehicles, we need vastly more than is available.
Even just current predictions, if you include global demand, especially from
Asia of electric vehicles. We're likely going to run out of cobalt from known supply in less
than 10 years. Wow. We have this sudden increased demand. What are the sourcing efforts starting
to look like? How is it changing how we actually find and source cobalt? If you look into the
scientific literature and you look at gold or deposit formation, you'll find a very rich scientific
literature on how gold deposits form. You'll find a very rich scientific literature on how copper deposits
form. You will not find a rich scientific literature on how cobalt deposits form because people haven't
looked for it. Right. There was not the same incentive at all. It just wasn't important. So John, what does
that science look like for how to find cobalt? How much do we know? Not very much is the simple answer.
I mean, we're kind of starting pretty at a basic level. If we wanted cobalt, we'd have gone looking
for copper and we know how to do that quite well. And we'd go looking for nickel. So kind of like
piggyback on other knowledge. And we'd hope that we found some copper and oh, this is terrific. We've got a bit of
extra cobalt. But there's no science basis for that. So what actually makes cobalt tick? So understanding
what kind of liquid will transport cobalt? So what, if we have a fluid that moves through
the earth, it's water dominated, maybe salty water, it moves through the earth, and it interacts
with a rock, will it actually extract cobalt? We know kind of how much copper it might extract,
but we don't know with cobalt. So if it did, and then it keeps moving, then that liquid kind of
comes up on the surface or comes into a different environment, would it precipitate cobalt?
We don't know the answer to that either.
And yet we know it did that because we can find occurrences around the world which are rich
in cobald.
And we can see the evidence that that came from the passage of a liquid through the rock
and it left the cobalt behind in cobalt minerals.
So that's one clue.
So that's one clue.
And if we understand how that work, then can we extrapolate to other areas and predict where
it might work again or where it might even work even better and give us a greater concentration
of cobalt. So that's the science
kind of basis. And what are some of the
other clues that we're starting to gather
and where you want to dive deeper into why
is this happening with cobalt?
Well, it's key to understand it's not that rare.
When you look at the distribution of cobalt,
it occurs in environments that
formed from liquid rocks, a very high
temperature, plus 1,000 degrees. But also
it's precipitating on the ocean floor,
deep, deep on the ocean floor below
4,000 meters beneath the surface.
We have the nodules, these little concentrations
of metal that are
precipitating out of seawater.
And so at seawater temperature, that's two degrees in the deep ocean.
And how do we know those are there?
They were found in late 1800s on an expedition that was just dredging stuff off the bottom
for the heck of dredging stuff up for the bottom.
Oh my gosh.
These little round balls called manganese nodules because the major constituent actually is manganese.
But they contain significant cobal.
And how interesting that that's what exploration was back then.
Like, let's just drag.
Yeah, let's just pick stuff up on the ocean and see what's there.
The result is we know cobalt can form at really high temperatures,
and we know it can form at really cold temperatures.
That's a huge range of conditions, range of pressures.
Now we want to get a little bit smarter and clever and understand
which of those range of conditions will give us more cobalt relative to copper or nickel or manganese
or other things that may come along right.
And I think that's where the data play makes so much sense, right?
Exactly.
That takes us into now the data world.
Because rather than comparing various exploration efforts,
they're looking at places that are fundamentally so different.
Yeah. Now you can track every known source of cobalt and what aspects or what qualities around that land made it particular. And then pattern match.
There's pattern matching that process. And then there's just looking at the patterns of data and get them to tell us a story.
It almost reminds me of like the initial way of looking at the landscape with very little information and trying to pattern match the green rocks or the, you know, the iron sheen or what have you.
But this is like at a much higher resolution and much greater than any.
one human could ever do, right?
What the data world can do for us now, AI, machine learning,
it is the 21st century prospector because it's not biased
and prospectors weren't biased.
They were just observers.
So the digital world can observe and integrate and interrogate the data
in ways that we, humans, geologists with all our biases, will never do.
And we can go back and look at all the other historical known traces of cobalt
and all the reports that are written that are like in PDF form right now, actually.
over the last several decades or not or in paper form. So where are you pulling these different
information sources from? What are they? What are the mainstreams of different kinds of information?
There's a huge amount of information out there. The challenge is that it's not well structured
or even digitized in some sense. You have geophysical data, which is that we're talking about
things like gravitational anomalies, magnetic anomalies, electromagnetic responses, things like
that, a whole class of data. Geochemical data.
is compositional data in basically a point in space and a list of concentrations at that location.
Then you have mineralogical data, which is like geochemical data, but it's more complex
because it gets into not just a list of elements, but actually what molecules the elements were in.
And then you have things like agricultural information, right, which are sort of indirect or topological information.
Meaning, like, what is the soil like here?
And this is used for inference, right? It's not necessarily direct, you know, direct observation.
But that's really important.
And then hyperspectral data, which is, you know, just the wide band of, you know,
electromagnetic emissions and reflection from the surface of the earth.
Is weather a part of that as well?
Groundwater is a great source of information.
So you have these, you have very, very wide sets of data.
That data has been collected over centuries, really.
Right.
It sounds like basically every piece of knowledge we have about the Earth and the way the Earth works.
That's exactly right.
Every piece of, you know, to first order, every piece of knowledge about how the Earth works
and what about the Earth is relevant.
It's just a matter of how relevant, you know, the sort of relative weightings of importance.
And so in certain jurisdictions, that data has been sort of aggregated in certain ways.
And there's a lot of it is public.
In certain places, it's, it has not even been digitized.
Over what kind of timescale are you looking at is this all like fresh new data?
Is this data from 200 years ago when people were panning for gold?
Both.
New and old.
So something like...
The good thing is the rock doesn't move that quickly.
That's the one constantly.
So 200 years ago is not really that.
It's still fine.
Unlike a lot of, it's actually interesting, unlike a lot of data analytics and data science plays, right?
We are looking at effectively a static system.
I mean, of course the Earth is dynamic, but on the timescale we're looking at it, it's effectively static.
That's a very different, it's a very different data science problem, but we're dealing with sparse data and then we're dealing with highly, highly disparate data.
So we have a program of trying to aggregate all these different data sources and then do two different things on it.
From one side, we have our basic science.
approach, which is sort of how these ore bodies formed, cobalt, or any other material we might be
looking for, and then looking for those sorts of indicators. And then you have the really
exciting thing, which is the data, rather than us asking the data questions, the data tells
us stuff, right? So this is where your machine learning or statistical association modeling
becomes important, right? Because the data itself can make predictions based on the patterns
that it sees. And that's where you eliminate the human bias and the non-systematic approach
of historic exploration.
Yeah, and just, like, to tie that back to, again,
like the demand for cobalt is so new.
So there's lots of reports out there
where they'll say there's known cobalt in these places,
they just didn't go mind them.
If you even get all those reports
and digitize them and look on a map,
oh, you know, all those reports are clustered in these areas.
That already surfaces some interesting sites.
And fun enough, if you go back 30, 40 years,
a lot of the people out exploring
were very good at identifying minerals.
and better than we probably are now
because we rely on a lot of extra tools to do it for us now
and they recorded that presence of that mineral
so now you're not looking through all these old texts
for the word cobald because they didn't write cobalt down
they wrote down the name of a scuderudorite
which is a very, you know, it's a particular cold arsenic
so yes they would have found that interesting
but not from a commercial perspective
they just thought it was cool they found another mineral
because they were just like being a bird washer
they were mineral watches so they recorded that
so now you've got to go through the data and find those
references to that kind of thing.
I just want to drill one to level down just for like fun color.
Where do those reports live now?
Where are these types of data coming from?
I mean, the modern data must be easier to access, but the old data.
Boxes and boxes and boxes and boxes of paper.
Where in libraries?
Dusty basements.
Basements.
How do you even get access to all these?
It's hard.
I mean, some of the mining companies are 100-year-old companies and they have 100-year-old data.
And so they have boxes and boxes sitting there.
Some would be well-archived.
and catalogued, and some is completely unknown.
And inside those boxes could be anything.
It could be actual good information, a mention of a mineral,
or it could be some mention of a conversation between two people
and the conversation they made mention that,
oh, when I was in the hills last, you know, I found this rock,
and it has this mineral in it, and that happens to be a cobalt mineral.
20 years ago, if you went to a new city and you wanted to find a business in a new city,
you had to get the yellow pages for that city,
and you had to get a paper map for that city,
and you had to look up the address in the book,
and then you had to look on the map for that location.
And a lot of what mineral exploration does now
is exactly that.
It's very site-specific.
You kind of collect all the data for a new project
in a new area at a new time.
It's relatively easy to image the surface of the earth
and the infrastructure of the earth
and the way Google Maps did
and to catalog all the businesses.
The problem we deal with is data sparsity.
So in some locations,
we have tremendous amounts of surface
data density and meaningful amounts of subsurface data density. And in other locations, it's very
data poor. And so then we have to use really sophisticated statistics, really, to try to figure out
and predict what is in those materials where there is no data. How do you actually deal with that
incredible variety in huge amounts of data in some areas and very little, very old data in other areas?
It's about making predictions, right? So it's about using places where there is a high density of data
and you can train and make predictions and then make those predictions in areas where there isn't
high densities of data and then go out and validate it, you know, by collecting new data.
It's interesting because in some ways it feels incredibly modern and new, but in other ways
it also feels like a kind of old-fashioned way of exploring again.
Actually, a lot of this reminds me of like their original idea of venture capital, which is
when kings and queens would fund these exploration efforts to look for natural resources or
look for new land or whatever they were looking for.
The whole idea of exploring the earth to encourage people to look for the materials that we need such that society can improve and do new things.
That's an old concept.
That's what developed California ultimately was the influx of people looking for gold.
And governments also fairly early, 150 years ago, started mapping the rocks on the surface because they knew if they mapped rocks that somebody would recognize associations and realize that that might have potential and therefore they'd go exploring, therefore they'd find things.
that would then open up and create economic activity and so on.
It's a very old cycle we're repeating, but more efficient and more effective.
Because now one of those explorers is a computer.
It's also going to help us actually mine more efficiently and more effectively and more
cleanly.
And that's really important because to me there's no point in us going electric and having electric
cars using cobalt for batteries and so on to do that if we create a big mess in terms
of providing those materials.
So we've not only got to find it better, we've also got to then exploit it and develop
in a way that's more efficient and cleaner
and doesn't have the kind of problems
that we've seen all over the world.
Well, I think it's fantastic to think about
the way that this searches and exploration
for these metals have driven
sort of entire chapters of human civilization.
And if we think about that, you know,
the age of copper, the age of iron,
if we think now we're entering the age of cobalt,
what are some of the ripple effects
that we're going to see, you know,
as we begin to more smartly mine and access
this new incredibly important mineral?
Trying to solve like,
climate change and other major issues that requires very specific use of commodities
that we're not so familiar with like cobalt and so that changes the way we need to think about
them and the way we therefore also need to exploit them and the exploitation part is to be more
selective we've been you know we've bolt mined everything so we make big big holes in the ground
in order to get iron ore or copper out of the ground and if we want to be really clever we've got
to define higher concentrations because higher concentrations are more efficient but we also now
need to try and be very selective about how we mine them.
Have much higher certainty.
Yeah.
And it's great if we go back and reprocess the tailings,
which as we're doing for Cobort.
And actually, the Romans were the first people
who started reprocessing waste rocks.
They did a couple of cycles of this kind of stuff.
So that's not a new idea either.
But it would be much better to be really efficient at the outset
and extract as much metal as we can
from the less and less volumes of rock
instead of moving more and more rock to get the metal.
And from a consumer perspective,
this can result in much better batteries.
Yeah.
Because right now, even the amount of cobalt in the battery
is kind of a financial decision, right?
Oh, really?
And a sourcing decision.
A financial and sourcing decision, right?
Like, if these companies could put more cobalt
than they put in today in their batteries,
it would still be a better battery.
So if we want batteries or iPhones that last one, two weeks without a charge...
Yeah, we need more cobalt.
Yeah.
You know, there must be a cobalt craze, right?
Like, everyone in their mom suddenly wants to go,
mining cobalt. That's the other cobalt issue, is that a lot of it comes from the DRC.
Over two-thirds of the world supply. And again, remember, cobalt's not a rare metal. And so the fact
that two-thirds of our supply comes from the DRC, the Congo right now, is largely a function of
where those copper and nickel mines historically were. And it's mined at a scale of, you know,
local people who don't aren't regulated, don't necessarily do it in an appropriate manner,
and use child labor and may have links to, you know, all sorts of other,
Central Provence. It's basically done by local people and DRC and other parts of the world.
They're doing it because they are impoverished and they feel they can probably make a better living
by scraping up the material than plowing their little piece of land.
Well, this highly valuable material.
It's highly valuable material.
So it's these small teams that are taking the gamble and using shovels and very basic tools to go look for this.
Correct.
So that's actually how it's happening right now still.
is just small groups of people with eyeballs and shovels in the dirt.
Consumers care about where their products came from now.
They care about the ingredients.
They care about how they were made.
They care about if this came from a local farmer.
So they will eventually start also caring about where their batteries came from.
In the DRC where this is done,
they are mining material, which was originally a copper-cobalt deposit,
that then suffered thousands of years of weathering.
So rain came down and dripped through the rocks,
and it actually separated the copper from the cobalt.
So the cobalt stayed near the surface,
and deeper down, it gets more copper-rich.
And the mineral that they mine now is it's got this great name called heterogeneite,
which, as you might guess, is something to be being heterogeneous.
It looks all over the place.
It's really messy stuff,
and they can just literally dig that up and put it in bags.
But unfortunately, that also concentrated quite a bit of thorium,
which is radioactive.
So now we have artisanal miners, local people and kids who are mining bags for all this
stuff, which is slightly radioactive.
It's not super radioactive, but it's radioactive enough to cause concern.
They don't know that.
They're just interested in getting bags full and getting paid for the bag of dirt that they scrape up.
Some people estimate as many as 100 million people on the planet involved in some kind
of activity like this at this scale.
Not just cobalt, not just cobalt, gold, diamonds, other coal tan, other minerals.
Okay, so let's talk about what this new kind of endeavor of exploration and mining and knowledge aggregation.
What does that mean on the company building side?
Who do you need?
What kind of people do you need to sort of represent all those different elements?
It's a fantastic question.
And basically it's two very different classes of people.
And they're both essential.
Our company is effectively half made up of economic geologists, geochemists, geochemists,
mineral explorationists, people who have spent their careers looking in sort of the conventional
manner for mineral deposits of all kinds. And then the other half is data scientists, right?
And so one of my co-founders has got his PhD in quantum computing. And the other one was the chief
reservoir engineer for Conoco Phillips for, you know, for many years.
Oil and gas has been incredibly sophisticated in how they use technology because there's a very
clear financial reason to go find oil and gas. Right, right.
But that same sophistication has not run brought over to mineral and metal exploration.
We relatively well understand the environment in which we find oil and gas,
and we have very good sophisticated tools to then help us do that.
So the mining business is playing catch-up on discovery,
and it's playing catch-up on exploitation as well.
So just in the last 10 years, everything now in mining is being sensors all over,
data is being gathered in the mining process.
Autonomous vehicles are coming into mining, so on.
And that's why the team makeup, I think.
think is so interesting because you have data scientists, you have people who are truly experts
in cobalt and they already know and have this gut feeling of where to look. And then you have
people from oil and gas who can take that sophistication and kind of bring them up to date.
Okay, so we're entering a new era not just about sort of about the importance of cobalt, but also
about new ways of mining as a whole, transforming a whole industry and a whole model of how we
find and explore in the earth. So what changes as a result of that entire model shifting so
dramatically? That's a fantastic question. I think when you think about, when you think about like
the metallurgic epochs, right, the sort of copper age, the bronze age, the iron age,
the steel age, giving rise to the industrial revolution and then petroleum. We're basically at,
we're still in the petroleum age. From a material standpoint, I would say we're entering the battery
materials age. And so battery materials will be the sort of the backbone of energy infrastructure
in the next hundred years. And that requires a staggering amount of new material and different
materials than we needed in the past. Cobalt being a, being a salient one, but not the only one.
I think that the tools that we're developing specifically to look for cobalt actually have a lot
of generality to them. And ultimately, I think we'll probably be looking for a lot of things other
than cobalt, to feed the need of the battery materials age broadly.
So a new kind of exploration for a new age of new materials.
Exactly.
When you create the Google Maps, you don't just know where that stores.
You know where everything else is too.
And funnily enough, it's different, but it's the same.
It's still source to material, to technology, to people's desire to change the world.
And that's the way it's been when it was the sword 5,000 years ago to an electric vehicle now.
It's that same process, but what we're doing is going to speed it up, make it more efficient, use the data more effectively.
So we're bringing all our tools that we have now to do the same things as we've done 5,000 years ago.
That's wonderful. Thank you so much for joining us on the A16D podcast.
You're welcome. Thank you.
Thank you.