I'm confused. The article is about how various excited states of tin are generated. But tin is atomic number 50, platinum and gold are 78 and 79 respectively. Can someone draw a line between these?
It's about refining theoreticals models that are used to predict nucleosynthesis of heavier elements. The researchers used indium because we can obtain the required neutron-heavy isotopes for indium but not for heavier elements such as gold or platinum. But improving the model with data from indium, they say, makes it more accurate for gold as well?
Why then gold in the title? Probably just because it's shiny.
Platinum is also a peak of element abundance, together with its neighbor elements.
So any model of how the elements have been produced must explain why the probability of making platinum and its neighbor elements, osmium, iridium and gold was higher than the probability of making other elements.
The existence of other abundance peaks is easier to understand, e.g. the peaks at tin and at lead happened because these 2 metals have "magic" numbers of protons, i.e. 50 and 82, which correspond to complete nucleon layers.
The peak at platinum is higher to understand, so to explain it you need accurate models.
On Earth it is not obvious that the heavy platinum-group metals and gold are located on an abundance peak, because all these precious metals have gone deep inside the Earth, into its iron core, so the crust of the Earth is depleted in them, which has made them rare and precious.
There are asteroids where the iron cores are easily accessible and they contain great amounts of platinum and related metals. However, the idea that mining that would be easy is extremely naive.
On Earth, mining gold and platinum is easy, because they do not mix with silicate rocks so they can be found as native metals or sulfides/arsenides/tellurides that can be easily separated from silicate rocks and then the metals are easy to extract.
On the other hand, in asteroids platinum and the other precious metals are dissolved in iron uniformly, so they are extremely diluted, in proportions of less than 1 part per million. Therefore, even if the total amount of platinum and gold is huge, concentrating one gram of platinum from one ton of iron would be tremendously difficult, requiring a huge amount of energy.
Mining asteroids for the purpose of bringing something back to Earth will certainly not happen before solving much easier problems, e.g. growing back an amputated leg or any other part of the body. The fact that at least a startup exists that claims to work to achieve such mining is just a certain scam with no other goal than mine money from naive investors.
>concentrating one gram of platinum from one ton of iron would be tremendously difficult, requiring a huge amount of energy.
melting one ton of iron requires 500KWh, 12 gallons of gasoline, less than $100 on Earth. Or 5 Tesla car batteries fully charged by say 30x30 m solar array in 2.5 hours - cost nothing in space once you got the hardware there. This is why mining in space is going to be a pretty big thing once/if we get cheap launch capability.
Since you didn't show your math, I did a quick calculation. .45J/g/C specific heat of iron means .45MJ/tonne. 1811K to melt iron means 815MJ/tonne. 3.6kWh/MJ, so 226.4 kWh should melt 1t of iron.
Yes, but melting is just the beginning of the process. Even your computation is incomplete, because it is not enough to heat iron until the melting temperature, you must also provide the additional latent heat of melting. Similarly for boiling iron, after heating to the boiling temperature there is an additional latent heat of vaporization.
There is still no easy way to separate platinum-group metals from liquid iron, so you must vaporize the iron, to exploit the fact that platinum-group metals have higher boiling temperatures. It is true however that at the low pressures easily achievable in vacuum, vaporization is easier than on Earth.
Otherwise than by vaporization, you could dissolve iron with an acid, but on such asteroids you do not have with what to make an acid, so you would have to transport it from some other asteroid, or more likely from a satellite of Jupiter. You would also need a chemical plant to make the acid and also to recycle the iron salts into regenerated acid. This is so much more complicated, that vaporization of the iron might be simpler.
Finally, you must account for the fact that the energy required to vaporize one ton of iron produces less than a gram of platinum and of each other platinum-group metals. It is unlikely that you could build there a solar array big enough to provide energy for vaporizing a million of tons of iron, to make a ton of platinum, so you would need a nuclear reactor.
While platinum-group metals might be obtained as a minuscule residue after vaporizing the iron, gold has about the same vapor pressure as the much more abundant iron, nickel, cobalt and germanium, so it would be impossible to extract it from iron by vaporization. It could be extracted only with a chemical method, e.g. with an acid or with oxygen, which need to be brought from elsewhere.
Taking all these into account, it seems that there is no chance of being able to mine precious metals at a cost less than on Earth any time soon, e.g. in the current century. Extraordinary reductions in the cost of interplanetary transport would be needed and in the cost of building a metallurgic plant on an asteroid.
Mining asteroids would make sense only if some people would decide to live in huge space stations with artificial gravity, instead of on Earth, and then some asteroids would be mined for making steel and other construction materials, to be used in the interplanetary space, not on Earth.
Your calculation assumes the heat must be considered wasted, but what prevents a counter-current heat exchange configuration from attaining ridiculously higher efficiencies? not to speak of just using saner approaches like chemical separation (gold and iron are very different chemically)
Heat exchangers for metal vapors at temperatures of a few thousand kelvin would be a significant technical challenge.
A heat exchanger needs fluids between which heat can be exchanged. Besides the fact that it would be very difficult to have pipes for fluids at such temperatures, it would not be so easy to efficiently heat the fluid more than it was heated by the recovered heat and then control somehow a fluid jet to transfer efficiently heat to the iron that must be vaporized.
Even if some heat would be recovered from the vapors, the losses due to imperfect heat transfer from fluid to iron might be greater than the recovered heat. Moreover, it is not clear what could be used as the working fluid, because those asteroids are depleted in volatile elements, so any fluid must be brought from elsewhere and any fluid losses would be irreplaceable.
Probably the easiest and most efficient way to heat iron until vaporization would be with an electron beam, but it would not be easy to ensure that the iron vapors do not destroy the installation and they condense in a safe place, from which the iron can be somehow evacuated.
working fluid? the same hot iron vapour is used to heat the incoming molten iron, no heat exchanger is perfect so the preheat would inevitably be a few percent short of the target temperature, the remainder is just the energy you supply to negate any heat lost through insulation (space is large, so one could use a ridiculously large insulation)
not that any of this matters, since chemical methods would be much more efficient
You cannot use a centrifuge to separate solid iron.
Using a centrifuge with liquid iron would create a gradient of concentration of the heavier elements dissolved in it, but that would not be enough to separate them.
All that could be done with a centrifuge with liquid iron would be to obtain an iron alloy enriched in heavy elements. However, I doubt that it would be possible to make a centrifuge for liquid iron that would have a lifetime sufficient to process quantities of the order of one million tons of iron. I do not think that until now anyone has ever tried to make a centrifuge that could work with a liquid metal at such a temperature. Most materials lose their strength at such temperatures, so the risk of breakage for the centrifuge would be extremely high, a risk that is increased by how heavy iron is.
It is also not clear if such an enrichment of the heavy elements would bring a sufficient simplification to further processing steps to make it worthwhile.
Iron and platinum have different melting points. If you melt the alloy, then spin it to concentrate the platinum, couldn't you coax the platinum to separate out as solid clumps by adjusting the temperature?
Alternatively, there are differences in magnetic properties that could be exploited...
This isn't my field, so I'm just spitballing. I bet if you can get the cost of launch and interplanetary transit to be low enough for people to really start tinkering with asteroid mining though, someone will crack the metallurgy issues...
>energy required to vaporize one ton of iron produces .... so you would need a nuclear reactor.
it is less than 2500KWh - under $250 of nuclear generated power on Earth. The best - fastest and efficient - way to travel outside planet's LEO that is available today is solar or nuclear powering ion thruster, with only nuclear really beyond Mars. So anyway you come into the asteroid belt with a reactor. A submarine or icebreaker like reactor - 70MW - would power vaporizing of almost 30 tons/hour of iron. Note, that nuclear reactor in space is tremendously cheaper than on Earth as all the regulation, safety, etc. costs either disappear completely or reduced a lot.
If you produce a few grams of a precious metal, that cannot justify the trip until there.
To produce something of the order of one ton, which still seems too low to cover the expenses, you need to process something of the order of one million tons of iron.
With your estimation that could take several years.
In reality the energy consumption would be much greater, because one must cut chunks of iron and transport them to the vaporization installation, then also transport elsewhere the condensed iron.
So you would need a decent number of submarine like reactors in order to achieve an acceptable productivity.
There is no doubt that it would be feasible, but the problem is that at the current prices there would be no way to recover the expenses.
How much less? I believe most gold produced in the US is from ore with under a half ppm gold (E.g open pit mines in Nevada).
Maybe the point there is that we already have practically endless supplies of quarter ppm ore ready for the taking on the surface of the earth. Gold is rare only in so far that the current price reflects the breakeven point of these most abundant sources. Adding more supply with similar or worst production costs wouldn't change anything.
All the other precious metals are less than 1 ppm compared to iron, but platinum is more abundant, and by weight it is about 6 ppm in iron.
The advantage of an asteroid is that its entire metal core has 6 ppm of platinum and a fraction of a ppm of gold, while on Earth the quantities of ore containing such amounts of precious metals like a half ppm or a quarter ppm of gold are much smaller.
There certainly exists no "endless supply" of gold ore with a quarter ppm gold, because the average concentration of gold in the crust of the Earth is a few parts per billion, so the few places where the concentration is as high as a fraction of a ppm are compensated by vast areas where the gold concentration is much less than one part per billion.
While an asteroid may have a lot of iron containing 6 ppm of platinum and a little less than 1 ppm of gold, that is not comparable at all with a terrestrial ore with 1 ppm or a few ppm of precious metals.
The precious metals are the easiest to separate from rocks, which is why one can exploit on Earth ores with a so low content of metal. On the other hand, precious metals are very hard to separate from iron, which is the very reason why in any planet or asteroid these metals end up being dissolved in the iron core.
So the extraction of platinum or gold in so small quantities from iron would be extremely expensive on Earth and much more so on an asteroid, where it is impossible to produce most of the chemicals used on Earth, like acids or cyanides.
True, but even with that, the amount of siderophile elements like platinum and gold in the crust is much less than in the core of the Earth ("siderophile" means that at the contact between molten iron and molten silicate rock such elements go into the molten iron).
Without that impact, it is assumed that almost no platinum-group metals and gold would have remained in the crust.
> Without that impact, it is assumed that almost no platinum-group metals and gold would have remained in the crust.
Wow, its wild to think of a counterfactual world without gold. Would those metals have emerged to the crust from volcanism or is that material not sourced deeply enough?
Volcanism at most brings material from the upper mantle, but usually such material becomes mixed with material from the crust, while ascending.
The mantle has slightly bigger concentrations of precious metals than the crust, but the concentrations remain many times smaller than in the core.
The reason is that both the mantle and the crust are made mostly of silicate rocks. The mantle is made of heavy silicate rocks and the crust is made of light silicate rocks, which float on the denser mantle.
The metals that are resistant to oxidation do not mix well with silicates, so they tend to segregate from them, and then, being heavier than rocks, they tend to descend towards the core. If they reach the core, then they dissolve into the melted iron.
When lava is expelled by volcanism, the precious metals contained in it usually separate from the silicates together with metal sulfides and arsenides, which makes them easier to find than if they were dispersed uniformly in the rocks. Other elements that ere much more abundant, for instance germanium and gallium, are harder to mine than the precious metals because they are not concentrated in distinct minerals but they are uniformly distributed in many rocks.
Tangentially related from something I'm currently reading¹:
> This is the reality of twenty-first-century resource exploitation: reducing vast quantities of rock into granules and chemically processing what remains. It is both awe inspiring and disturbing. One risk is that the cyanide and mercury used in the method could escape into the surrounding ecosystem. After all, while miners like Barrick insist they follow all the rules laid down by the US Environmental Protection Agency (EPA), campaigners warn that pollution often finds its way out of the mine. Indeed, a few years earlier the EPA had fined Barrick and another nearby miner $618,000 for failing to report the release of toxic chemicals including cyanide, lead and mercury. But the main thing I was struck by as I observed each stage in this process was just how far we will go these days to secure a tiny shred of shiny metal.
> The scale, for one thing, was mind-boggling. As I looked down into the pit I could just about make out some trucks on the bottom, but only when they emerged at the top did I realise that they were bigger than three-storey buildings; the tyres alone were the size of a double-decker bus. How much earth do you have to remove to produce a gold bar? I asked my minders. They didn’t know, but they did know that in a single working day those trucks would shift rocks equivalent to the weight of the Empire State Building.
¹ Material World: A Substantial Story of Our Past and Future by Ed Conway
does anyone else experience an “eyes glazing over” effect when you read things like “Heavy elements such as gold and platinum are forged under extraordinary conditions, including when stars collapse, explode, or collide”?
It seems totally beyond possible in scope and scale to validate something like this, even if you managed to get up close to one of these events it would still be too big and powerful to follow what is happening.
It is quite difficult to validate if you only consider the most direct of means like smashing two stars together and then physically going out and picking up the pieces.
There are other means to validate that type of thing though. Trying to come up with those means is a lot of fun. Can you think of any?
This is a goldmine. No, wait, it isn't but it appears these valuable rocks are more understood now...Maybe I can use this info to dissuade my wife from needing gold in her life. We could go to a steakhouse instead or something, haha.
I'm confused. The article is about how various excited states of tin are generated. But tin is atomic number 50, platinum and gold are 78 and 79 respectively. Can someone draw a line between these?
It's about refining theoreticals models that are used to predict nucleosynthesis of heavier elements. The researchers used indium because we can obtain the required neutron-heavy isotopes for indium but not for heavier elements such as gold or platinum. But improving the model with data from indium, they say, makes it more accurate for gold as well?
Why then gold in the title? Probably just because it's shiny.
Platinum is also a peak of element abundance, together with its neighbor elements.
So any model of how the elements have been produced must explain why the probability of making platinum and its neighbor elements, osmium, iridium and gold was higher than the probability of making other elements.
The existence of other abundance peaks is easier to understand, e.g. the peaks at tin and at lead happened because these 2 metals have "magic" numbers of protons, i.e. 50 and 82, which correspond to complete nucleon layers.
The peak at platinum is higher to understand, so to explain it you need accurate models.
On Earth it is not obvious that the heavy platinum-group metals and gold are located on an abundance peak, because all these precious metals have gone deep inside the Earth, into its iron core, so the crust of the Earth is depleted in them, which has made them rare and precious.
There are asteroids where the iron cores are easily accessible and they contain great amounts of platinum and related metals. However, the idea that mining that would be easy is extremely naive.
On Earth, mining gold and platinum is easy, because they do not mix with silicate rocks so they can be found as native metals or sulfides/arsenides/tellurides that can be easily separated from silicate rocks and then the metals are easy to extract.
On the other hand, in asteroids platinum and the other precious metals are dissolved in iron uniformly, so they are extremely diluted, in proportions of less than 1 part per million. Therefore, even if the total amount of platinum and gold is huge, concentrating one gram of platinum from one ton of iron would be tremendously difficult, requiring a huge amount of energy.
Mining asteroids for the purpose of bringing something back to Earth will certainly not happen before solving much easier problems, e.g. growing back an amputated leg or any other part of the body. The fact that at least a startup exists that claims to work to achieve such mining is just a certain scam with no other goal than mine money from naive investors.
>concentrating one gram of platinum from one ton of iron would be tremendously difficult, requiring a huge amount of energy.
melting one ton of iron requires 500KWh, 12 gallons of gasoline, less than $100 on Earth. Or 5 Tesla car batteries fully charged by say 30x30 m solar array in 2.5 hours - cost nothing in space once you got the hardware there. This is why mining in space is going to be a pretty big thing once/if we get cheap launch capability.
Since you didn't show your math, I did a quick calculation. .45J/g/C specific heat of iron means .45MJ/tonne. 1811K to melt iron means 815MJ/tonne. 3.6kWh/MJ, so 226.4 kWh should melt 1t of iron.
Yes, but melting is just the beginning of the process. Even your computation is incomplete, because it is not enough to heat iron until the melting temperature, you must also provide the additional latent heat of melting. Similarly for boiling iron, after heating to the boiling temperature there is an additional latent heat of vaporization.
There is still no easy way to separate platinum-group metals from liquid iron, so you must vaporize the iron, to exploit the fact that platinum-group metals have higher boiling temperatures. It is true however that at the low pressures easily achievable in vacuum, vaporization is easier than on Earth.
Otherwise than by vaporization, you could dissolve iron with an acid, but on such asteroids you do not have with what to make an acid, so you would have to transport it from some other asteroid, or more likely from a satellite of Jupiter. You would also need a chemical plant to make the acid and also to recycle the iron salts into regenerated acid. This is so much more complicated, that vaporization of the iron might be simpler.
Finally, you must account for the fact that the energy required to vaporize one ton of iron produces less than a gram of platinum and of each other platinum-group metals. It is unlikely that you could build there a solar array big enough to provide energy for vaporizing a million of tons of iron, to make a ton of platinum, so you would need a nuclear reactor.
While platinum-group metals might be obtained as a minuscule residue after vaporizing the iron, gold has about the same vapor pressure as the much more abundant iron, nickel, cobalt and germanium, so it would be impossible to extract it from iron by vaporization. It could be extracted only with a chemical method, e.g. with an acid or with oxygen, which need to be brought from elsewhere.
Taking all these into account, it seems that there is no chance of being able to mine precious metals at a cost less than on Earth any time soon, e.g. in the current century. Extraordinary reductions in the cost of interplanetary transport would be needed and in the cost of building a metallurgic plant on an asteroid.
Mining asteroids would make sense only if some people would decide to live in huge space stations with artificial gravity, instead of on Earth, and then some asteroids would be mined for making steel and other construction materials, to be used in the interplanetary space, not on Earth.
Your calculation assumes the heat must be considered wasted, but what prevents a counter-current heat exchange configuration from attaining ridiculously higher efficiencies? not to speak of just using saner approaches like chemical separation (gold and iron are very different chemically)
Heat exchangers for metal vapors at temperatures of a few thousand kelvin would be a significant technical challenge.
A heat exchanger needs fluids between which heat can be exchanged. Besides the fact that it would be very difficult to have pipes for fluids at such temperatures, it would not be so easy to efficiently heat the fluid more than it was heated by the recovered heat and then control somehow a fluid jet to transfer efficiently heat to the iron that must be vaporized.
Even if some heat would be recovered from the vapors, the losses due to imperfect heat transfer from fluid to iron might be greater than the recovered heat. Moreover, it is not clear what could be used as the working fluid, because those asteroids are depleted in volatile elements, so any fluid must be brought from elsewhere and any fluid losses would be irreplaceable.
Probably the easiest and most efficient way to heat iron until vaporization would be with an electron beam, but it would not be easy to ensure that the iron vapors do not destroy the installation and they condense in a safe place, from which the iron can be somehow evacuated.
working fluid? the same hot iron vapour is used to heat the incoming molten iron, no heat exchanger is perfect so the preheat would inevitably be a few percent short of the target temperature, the remainder is just the energy you supply to negate any heat lost through insulation (space is large, so one could use a ridiculously large insulation)
not that any of this matters, since chemical methods would be much more efficient
Could you use a centrifuge to separate the elements instead of vaporizing it?
You cannot use a centrifuge to separate solid iron.
Using a centrifuge with liquid iron would create a gradient of concentration of the heavier elements dissolved in it, but that would not be enough to separate them.
All that could be done with a centrifuge with liquid iron would be to obtain an iron alloy enriched in heavy elements. However, I doubt that it would be possible to make a centrifuge for liquid iron that would have a lifetime sufficient to process quantities of the order of one million tons of iron. I do not think that until now anyone has ever tried to make a centrifuge that could work with a liquid metal at such a temperature. Most materials lose their strength at such temperatures, so the risk of breakage for the centrifuge would be extremely high, a risk that is increased by how heavy iron is.
It is also not clear if such an enrichment of the heavy elements would bring a sufficient simplification to further processing steps to make it worthwhile.
Iron and platinum have different melting points. If you melt the alloy, then spin it to concentrate the platinum, couldn't you coax the platinum to separate out as solid clumps by adjusting the temperature?
Alternatively, there are differences in magnetic properties that could be exploited...
This isn't my field, so I'm just spitballing. I bet if you can get the cost of launch and interplanetary transit to be low enough for people to really start tinkering with asteroid mining though, someone will crack the metallurgy issues...
>energy required to vaporize one ton of iron produces .... so you would need a nuclear reactor.
it is less than 2500KWh - under $250 of nuclear generated power on Earth. The best - fastest and efficient - way to travel outside planet's LEO that is available today is solar or nuclear powering ion thruster, with only nuclear really beyond Mars. So anyway you come into the asteroid belt with a reactor. A submarine or icebreaker like reactor - 70MW - would power vaporizing of almost 30 tons/hour of iron. Note, that nuclear reactor in space is tremendously cheaper than on Earth as all the regulation, safety, etc. costs either disappear completely or reduced a lot.
You have forgotten many zeros.
If you produce a few grams of a precious metal, that cannot justify the trip until there.
To produce something of the order of one ton, which still seems too low to cover the expenses, you need to process something of the order of one million tons of iron.
With your estimation that could take several years.
In reality the energy consumption would be much greater, because one must cut chunks of iron and transport them to the vaporization installation, then also transport elsewhere the condensed iron.
So you would need a decent number of submarine like reactors in order to achieve an acceptable productivity.
There is no doubt that it would be feasible, but the problem is that at the current prices there would be no way to recover the expenses.
> melting one ton of iron requires 500KWh, 12 gallons of gasoline, less than $100 on Earth
The spot price for platinum today is $68, so you'd be losing money doing it.
> in proportions of less than 1 part per million.
How much less? I believe most gold produced in the US is from ore with under a half ppm gold (E.g open pit mines in Nevada).
Maybe the point there is that we already have practically endless supplies of quarter ppm ore ready for the taking on the surface of the earth. Gold is rare only in so far that the current price reflects the breakeven point of these most abundant sources. Adding more supply with similar or worst production costs wouldn't change anything.
All the other precious metals are less than 1 ppm compared to iron, but platinum is more abundant, and by weight it is about 6 ppm in iron.
The advantage of an asteroid is that its entire metal core has 6 ppm of platinum and a fraction of a ppm of gold, while on Earth the quantities of ore containing such amounts of precious metals like a half ppm or a quarter ppm of gold are much smaller.
There certainly exists no "endless supply" of gold ore with a quarter ppm gold, because the average concentration of gold in the crust of the Earth is a few parts per billion, so the few places where the concentration is as high as a fraction of a ppm are compensated by vast areas where the gold concentration is much less than one part per billion.
While an asteroid may have a lot of iron containing 6 ppm of platinum and a little less than 1 ppm of gold, that is not comparable at all with a terrestrial ore with 1 ppm or a few ppm of precious metals.
The precious metals are the easiest to separate from rocks, which is why one can exploit on Earth ores with a so low content of metal. On the other hand, precious metals are very hard to separate from iron, which is the very reason why in any planet or asteroid these metals end up being dissolved in the iron core.
So the extraction of platinum or gold in so small quantities from iron would be extremely expensive on Earth and much more so on an asteroid, where it is impossible to produce most of the chemicals used on Earth, like acids or cyanides.
I assume those abundances in asteroids are actually the abundances in iron meteorites, right?
I thought the impact of Thea made heavier elements spread much more evenly towards the surface.
True, but even with that, the amount of siderophile elements like platinum and gold in the crust is much less than in the core of the Earth ("siderophile" means that at the contact between molten iron and molten silicate rock such elements go into the molten iron).
Without that impact, it is assumed that almost no platinum-group metals and gold would have remained in the crust.
> Without that impact, it is assumed that almost no platinum-group metals and gold would have remained in the crust.
Wow, its wild to think of a counterfactual world without gold. Would those metals have emerged to the crust from volcanism or is that material not sourced deeply enough?
Volcanism at most brings material from the upper mantle, but usually such material becomes mixed with material from the crust, while ascending.
The mantle has slightly bigger concentrations of precious metals than the crust, but the concentrations remain many times smaller than in the core.
The reason is that both the mantle and the crust are made mostly of silicate rocks. The mantle is made of heavy silicate rocks and the crust is made of light silicate rocks, which float on the denser mantle.
The metals that are resistant to oxidation do not mix well with silicates, so they tend to segregate from them, and then, being heavier than rocks, they tend to descend towards the core. If they reach the core, then they dissolve into the melted iron.
When lava is expelled by volcanism, the precious metals contained in it usually separate from the silicates together with metal sulfides and arsenides, which makes them easier to find than if they were dispersed uniformly in the rocks. Other elements that ere much more abundant, for instance germanium and gallium, are harder to mine than the precious metals because they are not concentrated in distinct minerals but they are uniformly distributed in many rocks.
I am surprised that the s-process plays no role in the formation of gold.
Tangentially related from something I'm currently reading¹:
> This is the reality of twenty-first-century resource exploitation: reducing vast quantities of rock into granules and chemically processing what remains. It is both awe inspiring and disturbing. One risk is that the cyanide and mercury used in the method could escape into the surrounding ecosystem. After all, while miners like Barrick insist they follow all the rules laid down by the US Environmental Protection Agency (EPA), campaigners warn that pollution often finds its way out of the mine. Indeed, a few years earlier the EPA had fined Barrick and another nearby miner $618,000 for failing to report the release of toxic chemicals including cyanide, lead and mercury. But the main thing I was struck by as I observed each stage in this process was just how far we will go these days to secure a tiny shred of shiny metal.
> The scale, for one thing, was mind-boggling. As I looked down into the pit I could just about make out some trucks on the bottom, but only when they emerged at the top did I realise that they were bigger than three-storey buildings; the tyres alone were the size of a double-decker bus. How much earth do you have to remove to produce a gold bar? I asked my minders. They didn’t know, but they did know that in a single working day those trucks would shift rocks equivalent to the weight of the Empire State Building.
¹ Material World: A Substantial Story of Our Past and Future by Ed Conway
> in a single working day those trucks would shift rocks equivalent to the weight of the Empire State Building.
Oh. My. God.
does anyone else experience an “eyes glazing over” effect when you read things like “Heavy elements such as gold and platinum are forged under extraordinary conditions, including when stars collapse, explode, or collide”?
It seems totally beyond possible in scope and scale to validate something like this, even if you managed to get up close to one of these events it would still be too big and powerful to follow what is happening.
It is quite difficult to validate if you only consider the most direct of means like smashing two stars together and then physically going out and picking up the pieces.
There are other means to validate that type of thing though. Trying to come up with those means is a lot of fun. Can you think of any?
And they said turning Lead into Gold was just heresy.
This is a goldmine. No, wait, it isn't but it appears these valuable rocks are more understood now...Maybe I can use this info to dissuade my wife from needing gold in her life. We could go to a steakhouse instead or something, haha.
This isn't Reddit