Voyager 1 passed by Saturn in 1980 on my ninth birthday, and my dad had set up TV sets in the house with video he was getting off a satellite feed for my birthday party with a bunch of my friends. We were all very confused as to why he did it, as it wasn't very kid's party like. Only many years later did I get how cool it actually was, and how I will always remember that Voyager event. So... a much belated thanks, dad!
Humanity’s greatest journey so far has only reached the closest world to us: the Moon ... in a universe that stretches endlessly in every direction and is seemingly infinite.
It's kind of wild to think about: we might end up collapsing our own civilization before we ever make it beyond our solar system.
At this point, I suspect the next real explorers won't be us, but probes carrying intelligent machines..our robotic descendants venturing where we can’t.
Many see this as the answer to the Fermi paradox. Any society on the path to being advanced enough to potentially leave their system probably gains the ability to destroy themselves before getting to that point.
Early as in we may have developed before any other civilizations? That's interesting. We're speculating of course, but what would explain us being the first after so much time – 13.8 billion years?
Maybe we aren't the first living things to exist in the universe, but the first intelligent ones, and intelligent here meaning creatures with ability to ask these questions and make space probes to explore the universe.
Maybe intelligence isn't always a product of evolution. Even here on Earth, in the, what, 4 billion years history of the planet, humans are the only evolved creatures with intelligence as defined here. Maybe intelligence doesn't always occur.
A lengthy tangentially related post on my blog if you care -
We could be late too, it hasn't even been 200 years since we're technologically capable.
The universe is physically big, which means we'd have a hard time finding life even if it was going on at the same time as us, but add time to the equation and it's game over. There could have been a star trek tier civilisation next door that died 1m years ago and we would probably never know
If a civilisation spreads to stars then logically it will continue to spread (no technology or resource problems) and no event - not even super novas - could stop it (as events could only travel at the speed of expansion)
At that point you don’t have a single civilisation , you have thousands of functionally independent civilisations, with numbers increasing all the time. Sure something could wipe out a civ in one star system, but it couldn’t spread to others quickly enough to affect those others.
The most successful civilisations would continue to expand independently over time to take up all the resources in a galaxy.
Unless they found a way to travel faster than light, which means events could spread fast enough to collapse the civilisations.
Unsong is extremely amusing to me for some reason. Something about how Scott comes up with reasonably sounding similarities and manages to make those relate to an overall story.
It's already true because implied precision and comparing continuous measurements for equality and all that. It's both pedantic and meaningless to say it's true on (all of) Nov 13 2026 but not true today.
Elite Dangerous is a modern sci-fi space simulation game. It takes place in the 34th century. You can actually visit solar system (can't land on Earth yet), and catch up with two Voyagers. They are where they would be in 1200 years, approximately 25 light days away from the Sun.
A thousand years ago it was unthinkable we could circumnavigate the globe.
We don’t understand quantum mechanics and we don’t understand gravity. There’s no reason to assume that we won’t find ways to travel the universe, e.g. by manipulating space time. We just don’t know what we don’t know.
If you had to bet based on past achievements, humanity will find a way. Our job is to push the limits as much as we can and build a foundation for future generations.
That is it. When you become very aware of just how amazingly far away everything else is, fighting over a speak of dust and the only home we have seems absolutely ridiculous.
A great long form video on this is "Shouting at stars : A history of interstellar messages". It really highlights just how empty it all is.
https://www.youtube.com/watch?v=uFI5WpK2sgg
If mankind exists in 1000 years time and hasn’t regressed then we’ll be able to build fusion powered self sustaining asteroids. Those can be used as airships to colonise every system in the Milky Way in a few million years.
600M years is enough time for Earth to try two or three attempts at intelegence, with full blown fossil fuel replenishment cycles. It won’t be humans - whether we leave for the stars tomorrow or blow ourselves to bits we’ll have evolved to something unrecognisable by then, but there’s very few things which could end life on earth in the next 200 million years (mainly very large out of system asteroids/rogue planets)
My understanding is that ISS is not self-sustaining even in principle. It consistently needs to be resupplied with water and breathable air as the station continuously leaks it. These resupplies happen about once every month or two. This article goes into quite a few details about what would be needed for actual self-sustainable human space exploration and it looks like there's quite a few engineering challenges to work out.
I once watched one of those videos that was a speeded up example of light leaving the sun and showing the time it takes to get to the various planets. It was boring as hell after just a couple of minutes and that's with light way speeded up. My conclusion is that "light is too damn slow."
There are lots of hypotheses, but this is one of my gut feelings for why there are no aliens in view. It's hard to escape your local solar system.
When will we need more resources than exist here? We'll be mining the sun to run future simulations. Do we need more compute? Seems like we'll just stay inside.
Most life is probably similarly bound up to their origin. That and life is hard by many, many, many hard steps. Earth life is nearly 30% the age of the universe and it took us this long to get here.
It'd be near impossible for aquatic life to have an industrial revolution without aqueous chemistry control. Can't do that when you're stuck inside water. It's also hard to evolve reasoning when you can't see far ahead. Little evolutionary pressure on reasoning over time and distance.
And it's hard to leave water. You need to evolve new eyes and lungs to live on land. And then you need an energy source like O2, which tends not to stick around.
So many reasons.
The distances of space are certainly one holding us back now.
One thing I keep wondering, though, is whether “life” is tied more to the particular chemistry and environment it uses or to its patterns (the abstract information structure that can, in principle, be re-instantiated on different substrates).
If it’s the patterns that matter, do you think it’s actually impossible for those patterns to be transmitted across interstellar distances? Just like a cup of ocean water is packed with DNA, it’s at least conceivable that what we call “cosmic background noise” could, in principle, hide extremely compressed life-patterns that only an advanced civilization could recognize and reconstruct back into something we’d meaningfully call “alive.” And of course, the more efficiently you code that information, the more it statistically has to look like random noise.
Not saying this is likely -- just that if the essence of life is informational rather than chemical, "traveling" could look very different for any life that is suitably advanced.
Probably from deconstructing the solar system's asteroids and planets. I imagine a Dyson sphere would be less structurally sound and harder to get right – due to gravitational forces on the material – than a Dyson swarm or matryoshka brain. The latter made of independent satellites orbiting the sun and collecting light from concentric orbits at various distances.
> Of course we are, but my question is why is that notable?
> You also breathe a nitrogen-oxygen-hydrogen mixture, and have a body that is built to walk around at 1g on a planet between 0-100 degrees F.
> That doesn’t seem to bother people.
Humans like to explore. We've populated the globe from our starting position in East Africa.
When we look to the skies, beyond our own galaxy, and into the early history of the universe, we are seeing a world that will never get to explore first-hand. Humans like to explore.
I mean we have a way today to get to a fraction of light speed with the nuclear bombs for propulsion method. Technically it’s even survivable for a person.
It was more like assimilating everything it encountered in minute detail, but the living beings were no longer "living" as such once assimilated. It was creepy.
I remember as a kid seeing the first photos of Uranus and Neptune from the Voyager probes. What's sad to me is they remain to this day the only time we've ever visited these ice giants. There have been a number of proposals over the years but none have been selected and it seems like 2045-2050 is the soonest we could get to Uranus (more for Neptune) but that pretty much requires a launch by 2034 and we've pretty much run out of time for a mission to be selected to that window given that it would be a complex and expensive flagship mission. I guess it depends on whether it's a flyby (like New Horizons) or an intercept mission, which would take substantially longer.
Obital mechanics are a funny thing however. You see this with the complicated BepiColombo trajectory to Mercury [1] that requires multiple passes on Venus. Mercury orbits at ~48km/s (compared to Earth's 30km/s). Fun fact: the escape velocity of the Sun is 42km/s so it's easier to leave the Solar System than intercept Mercury.
One difficulty is there aren't large gas giants to slingshot or brake around.
Uranus's orbital velocity is ~6.8km/s so it's both really far and requires a ton of delta-V to slow down to intercept.
Anyway, I digress.
So Voyager 1's speed seems to be ~17km/s, I guess relative to the Sun. People talk about the time required for interplanetary (let alone interstellar) travel but we can do much better than this with relatively near-future technology.
We need a whole bunch more Earth-orbit space infrastructure and industry to do anything, really. Lower launch costs in particular. I think this future is orbital rings [2]. This would revolutionize getting stuff into orbit but also launching vehicles to other planets. Basically you accelerate on the inside of the ring at ~2G with magnetic levitation to counter the linear momentum. You can reasonably get ~15km/s with this, adding to the EArth's 30km/s ideally so even without fuel you can get to ~45km/s.
I see China is proposing a fair few missions to the outer system with Jutiper in a few years with Uranus and Neptune to follow. But they are just proposals still, but it is good to see they are at least considering it.
It's expected never to encounter any other object in all eternity. Unless of course someone deliberately aims for it. I heard once it will eventually lose it's form entirely and just drift through space as a melted lump of metal. For some reason that reminds me of Red Dwarf.
We are going to lose it before long i wonder if it will be possible to find it on a future date in theory.
Sure, but we're talking insane amounts of time unless it hits something head one. Even the electronics are still alive and in 2024 after a long break we managed to get signals back. It is anybody's guess at this point how long the craft will remain functional but it will take a long, long time (long after humanity will either have destroyed itself or has figured out how to overtake it) before it is 'a melted lump of metal'.
Look at the metal that we routinely dig up in the hostile environment known as 'Earth' and which wasn't particularly designed to be long lasting. Voyager is just that: designed to last for a really long time. At a minimum several millennia, though of course by that time the electronics will no longer function, and not because they no longer have power but simply because they have degraded due to their rather more sensitive nature than the rest of the craft.
I doubt that’s true. At minimum it’s going to hit an enormous quantity of micrometer sized objects.
It’s gravitationally bound to the Milky way so it’s going to keep wandering into and out of star systems for a very long time. We’re talking a large multiple of the age of the universe meanwhile plenty of space rocks show encounters with other space rocks on a vastly smaller timescale. If nothing else it’s got decent odds of being part of the star formation process. Stars are ~10% of the milky way’s mass and star formation is going to continue for a while.
Supposing that it does become part of a new star, and some "nearby" civilization had sufficiently precise instruments...would that be a detectable anomaly? Like some atoms of Plutonium still haven't decayed, and isn't that weird that Plutonium's spectral signature is present in this new star? Or is that just something that happens because some plutonium is created in a supernova and might just have been floating around anyway.
Based on the interstellar density it will take a billion years to ablate just a millimetre off its outer layer.
The chance of impacting anything larger than that is internal, same as an encounter with another star. In 40,000 years it will get to within 1.6 light years from a star, that’s such an unimaginable distance it’s irrelevant.
In 100 million to 1 billion years you may not be able to recover audio from the golden record, but until that point they will be lasting remnants of a civilisation long gone, and never be encountered.
Voyagers will only impact a few thousand kilograms of material before all stars die out in 10^14 years, it will still be an object after the final stars fade.
The biggest risk to voyager now is if proton decay is a thing, or if a civilisation deliberately seeks it out, which seems very unlikely given how many natural lumps of iron int he 1 ton range flying through interstellar space.
“In 40,000 years it will get to within 1.6 light years from a star, that’s such an unimaginable distance it’s irrelevant.”
On most human timescales that’s a long time, but here it’s only 0.004% of a billion years and in general stars are ~5 light years between closest stars in our neighborhood. If you assume zero significant impacts means it’s around in 100+ billion years there will be many vastly closer passes than 1.6 lightyears. It’s the kind of thing you really need to simulate because gravity plays a larger role the closer voyager gets to another star.
> I heard once it will eventually lose it's form entirely
It will be sitting at something like -450F. Could it really lose form!? Is the idea that all the phonons could converge to one point, shifting an atom of metal (which will happen infinitely with infinite time)? Maybe with random photons/hydrogen/whatever "continuously" adding energy?
From what I recall, one of the hazards of long term space travel is that nearly any material will start sublimating atoms in the hard vacuum of space, with things like cosmic rays adding to the woes. Some over time it will start deteriorating.
Not sure about “melting” into an amorphous mass, I guess in theory the probes gravity could do that, but I would imagine even the tiniest force would disturb that and dissipate it.
One issue is that over long enough timeframes, even atoms that we consider stable will decay - particularly ones that are heavier than iron, which will decay towards iron or nickel. That decay will eventually compromise the structure of the probes.
> It's expected never to encounter any other object in all eternity.
This is read as "near zero" rather than "no chance". "Expected" is a word of uncertainty.
I think the rough napkin math would be: take the volume that the probe will sweep through and multiply it by the volume of matter in the universe/volume of the universe.
Voyager 1 passed by Saturn in 1980 on my ninth birthday, and my dad had set up TV sets in the house with video he was getting off a satellite feed for my birthday party with a bunch of my friends. We were all very confused as to why he did it, as it wasn't very kid's party like. Only many years later did I get how cool it actually was, and how I will always remember that Voyager event. So... a much belated thanks, dad!
Humanity’s greatest journey so far has only reached the closest world to us: the Moon ... in a universe that stretches endlessly in every direction and is seemingly infinite.
It's kind of wild to think about: we might end up collapsing our own civilization before we ever make it beyond our solar system.
At this point, I suspect the next real explorers won't be us, but probes carrying intelligent machines..our robotic descendants venturing where we can’t.
Many see this as the answer to the Fermi paradox. Any society on the path to being advanced enough to potentially leave their system probably gains the ability to destroy themselves before getting to that point.
Short terms issues preventing long term gains.
That is one answer. Another possibility (the one I prefer, since this is mere speculation anyway) is that we are early.
Early as in we may have developed before any other civilizations? That's interesting. We're speculating of course, but what would explain us being the first after so much time – 13.8 billion years?
Maybe we aren't the first living things to exist in the universe, but the first intelligent ones, and intelligent here meaning creatures with ability to ask these questions and make space probes to explore the universe.
Maybe intelligence isn't always a product of evolution. Even here on Earth, in the, what, 4 billion years history of the planet, humans are the only evolved creatures with intelligence as defined here. Maybe intelligence doesn't always occur.
A lengthy tangentially related post on my blog if you care -
https://www.rxjourney.net/extraterrestrial-intelligence-and-...
I think that’s the question, is 13.8 billion years a lot of time, of not a lot of time?
We could be late too, it hasn't even been 200 years since we're technologically capable.
The universe is physically big, which means we'd have a hard time finding life even if it was going on at the same time as us, but add time to the equation and it's game over. There could have been a star trek tier civilisation next door that died 1m years ago and we would probably never know
If a civilisation spreads to stars then logically it will continue to spread (no technology or resource problems) and no event - not even super novas - could stop it (as events could only travel at the speed of expansion)
At that point you don’t have a single civilisation , you have thousands of functionally independent civilisations, with numbers increasing all the time. Sure something could wipe out a civ in one star system, but it couldn’t spread to others quickly enough to affect those others.
The most successful civilisations would continue to expand independently over time to take up all the resources in a galaxy.
Unless they found a way to travel faster than light, which means events could spread fast enough to collapse the civilisations.
"we might end up collapsing our own civilization before we ever make it beyond our solar system."
Given what I see in the past 15 years, I don't particularly see that as a problem, honestly.
"Some say it has already happened..."
Lol
Yep. Ghost in the shell. The robots are just the next stage in the evolution of life..
Both Voyager space probes are way farther away than the moon. Is this a reference I'm not understanding?
Parent poster is considering only crewed journeys, surely.
That's when it collides with the skybox, like the sailboat at the end of The Truman Show.
David Brin thinks so:
https://en.wikipedia.org/wiki/The_Crystal_Spheres
Or like Apollo 8 in the incredibly funny book Unsong.
Unsong is extremely amusing to me for some reason. Something about how Scott comes up with reasonably sounding similarities and manages to make those relate to an overall story.
Supplied headline will be true in 1 year. Actual headline:
thanks, title is updated.
It's already true because implied precision and comparing continuous measurements for equality and all that. It's both pedantic and meaningless to say it's true on (all of) Nov 13 2026 but not true today.
Elite Dangerous is a modern sci-fi space simulation game. It takes place in the 34th century. You can actually visit solar system (can't land on Earth yet), and catch up with two Voyagers. They are where they would be in 1200 years, approximately 25 light days away from the Sun.
We are trapped in the solar system.
A thousand years ago it was unthinkable we could circumnavigate the globe.
We don’t understand quantum mechanics and we don’t understand gravity. There’s no reason to assume that we won’t find ways to travel the universe, e.g. by manipulating space time. We just don’t know what we don’t know.
If you had to bet based on past achievements, humanity will find a way. Our job is to push the limits as much as we can and build a foundation for future generations.
> Our job is to push the limits as much as we can
What if that's exactly what will cause our extinction, you don't know what you don't know am I right ?
For the next 300-500 years, yes. But there is plenty of things to do, stuff to build and room to expand within a light-day from Sun.
No other place is habitable within a light day of the sun.
A good argument for making sure our planet stays habitable. Caring about the environment isn't just for hippies anymore!
That is it. When you become very aware of just how amazingly far away everything else is, fighting over a speak of dust and the only home we have seems absolutely ridiculous.
A great long form video on this is "Shouting at stars : A history of interstellar messages". It really highlights just how empty it all is. https://www.youtube.com/watch?v=uFI5WpK2sgg
Works up until the earth becomes uninhabitable in 600M years, before then humans are going to need to find and colonize a different planet.
If mankind exists in 1000 years time and hasn’t regressed then we’ll be able to build fusion powered self sustaining asteroids. Those can be used as airships to colonise every system in the Milky Way in a few million years.
600M years is enough time for Earth to try two or three attempts at intelegence, with full blown fossil fuel replenishment cycles. It won’t be humans - whether we leave for the stars tomorrow or blow ourselves to bits we’ll have evolved to something unrecognisable by then, but there’s very few things which could end life on earth in the next 200 million years (mainly very large out of system asteroids/rogue planets)
No rush then, modern humans aren't even 1m years old...
ISS is one such place.
My understanding is that ISS is not self-sustaining even in principle. It consistently needs to be resupplied with water and breathable air as the station continuously leaks it. These resupplies happen about once every month or two. This article goes into quite a few details about what would be needed for actual self-sustainable human space exploration and it looks like there's quite a few engineering challenges to work out.
https://www.frontiersin.org/journals/space-technologies/arti...
Not only that but they have to routinely boost its orbital velocity as there is still a little atmospheric drag at the height.
Yeah, pretty much:
> It will take about 300 years for Voyager 1 to reach the inner edge of the Oort Cloud and possibly about 30,000 years to fly beyond it.
I once watched one of those videos that was a speeded up example of light leaving the sun and showing the time it takes to get to the various planets. It was boring as hell after just a couple of minutes and that's with light way speeded up. My conclusion is that "light is too damn slow."
The sky is big!
until next "General Relativity" is discovered, and maybe we can get both voyagers back.
There are lots of hypotheses, but this is one of my gut feelings for why there are no aliens in view. It's hard to escape your local solar system.
When will we need more resources than exist here? We'll be mining the sun to run future simulations. Do we need more compute? Seems like we'll just stay inside.
Most life is probably similarly bound up to their origin. That and life is hard by many, many, many hard steps. Earth life is nearly 30% the age of the universe and it took us this long to get here.
It'd be near impossible for aquatic life to have an industrial revolution without aqueous chemistry control. Can't do that when you're stuck inside water. It's also hard to evolve reasoning when you can't see far ahead. Little evolutionary pressure on reasoning over time and distance.
And it's hard to leave water. You need to evolve new eyes and lungs to live on land. And then you need an energy source like O2, which tends not to stick around.
So many reasons.
The distances of space are certainly one holding us back now.
One thing I keep wondering, though, is whether “life” is tied more to the particular chemistry and environment it uses or to its patterns (the abstract information structure that can, in principle, be re-instantiated on different substrates).
If it’s the patterns that matter, do you think it’s actually impossible for those patterns to be transmitted across interstellar distances? Just like a cup of ocean water is packed with DNA, it’s at least conceivable that what we call “cosmic background noise” could, in principle, hide extremely compressed life-patterns that only an advanced civilization could recognize and reconstruct back into something we’d meaningfully call “alive.” And of course, the more efficiently you code that information, the more it statistically has to look like random noise.
Not saying this is likely -- just that if the essence of life is informational rather than chemical, "traveling" could look very different for any life that is suitably advanced.
The resource thing always gets me. More ideas of things like dyson sphere's. Where does the material from them come from?
Probably from deconstructing the solar system's asteroids and planets. I imagine a Dyson sphere would be less structurally sound and harder to get right – due to gravitational forces on the material – than a Dyson swarm or matryoshka brain. The latter made of independent satellites orbiting the sun and collecting light from concentric orbits at various distances.
Sandboxed. Yep.
Of course we are, but my question is why is that notable?
You also breathe a nitrogen-oxygen-hydrogen mixture, and have a body that is built to walk around at 1g on a planet between 0-100 degrees F.
That doesn’t seem to bother people.
> Of course we are, but my question is why is that notable?
> You also breathe a nitrogen-oxygen-hydrogen mixture, and have a body that is built to walk around at 1g on a planet between 0-100 degrees F.
> That doesn’t seem to bother people.
Humans like to explore. We've populated the globe from our starting position in East Africa.
When we look to the skies, beyond our own galaxy, and into the early history of the universe, we are seeing a world that will never get to explore first-hand. Humans like to explore.
I mean we have a way today to get to a fraction of light speed with the nuclear bombs for propulsion method. Technically it’s even survivable for a person.
Who remembers the Star Trek movie where one of the voyagers came back as v’ger - the humongous sentient entity of accumulated space junk?
> Who remembers the Star Trek movie where one of the voyagers came back as v’ger - the humongous sentient entity of accumulated space junk?
Everyone.
I watched it the first time around in a cinema in West Germany. That was a British cinema in Deutchland - a BFBS jobbie.
Times have changed somewhat!
It was more like assimilating everything it encountered in minute detail, but the living beings were no longer "living" as such once assimilated. It was creepy.
I remember as a kid seeing the first photos of Uranus and Neptune from the Voyager probes. What's sad to me is they remain to this day the only time we've ever visited these ice giants. There have been a number of proposals over the years but none have been selected and it seems like 2045-2050 is the soonest we could get to Uranus (more for Neptune) but that pretty much requires a launch by 2034 and we've pretty much run out of time for a mission to be selected to that window given that it would be a complex and expensive flagship mission. I guess it depends on whether it's a flyby (like New Horizons) or an intercept mission, which would take substantially longer.
Obital mechanics are a funny thing however. You see this with the complicated BepiColombo trajectory to Mercury [1] that requires multiple passes on Venus. Mercury orbits at ~48km/s (compared to Earth's 30km/s). Fun fact: the escape velocity of the Sun is 42km/s so it's easier to leave the Solar System than intercept Mercury.
One difficulty is there aren't large gas giants to slingshot or brake around.
Uranus's orbital velocity is ~6.8km/s so it's both really far and requires a ton of delta-V to slow down to intercept.
Anyway, I digress.
So Voyager 1's speed seems to be ~17km/s, I guess relative to the Sun. People talk about the time required for interplanetary (let alone interstellar) travel but we can do much better than this with relatively near-future technology.
We need a whole bunch more Earth-orbit space infrastructure and industry to do anything, really. Lower launch costs in particular. I think this future is orbital rings [2]. This would revolutionize getting stuff into orbit but also launching vehicles to other planets. Basically you accelerate on the inside of the ring at ~2G with magnetic levitation to counter the linear momentum. You can reasonably get ~15km/s with this, adding to the EArth's 30km/s ideally so even without fuel you can get to ~45km/s.
[1]: https://www.youtube.com/watch?v=BK3F4fmqtbA
[2]: https://www.youtube.com/watch?v=LMbI6sk-62E
I see China is proposing a fair few missions to the outer system with Jutiper in a few years with Uranus and Neptune to follow. But they are just proposals still, but it is good to see they are at least considering it.
Despite all our rage we are still just rats in a solar system cage.
It's expected never to encounter any other object in all eternity. Unless of course someone deliberately aims for it. I heard once it will eventually lose it's form entirely and just drift through space as a melted lump of metal. For some reason that reminds me of Red Dwarf.
We are going to lose it before long i wonder if it will be possible to find it on a future date in theory.
Sure, but we're talking insane amounts of time unless it hits something head one. Even the electronics are still alive and in 2024 after a long break we managed to get signals back. It is anybody's guess at this point how long the craft will remain functional but it will take a long, long time (long after humanity will either have destroyed itself or has figured out how to overtake it) before it is 'a melted lump of metal'.
Look at the metal that we routinely dig up in the hostile environment known as 'Earth' and which wasn't particularly designed to be long lasting. Voyager is just that: designed to last for a really long time. At a minimum several millennia, though of course by that time the electronics will no longer function, and not because they no longer have power but simply because they have degraded due to their rather more sensitive nature than the rest of the craft.
I doubt that’s true. At minimum it’s going to hit an enormous quantity of micrometer sized objects.
It’s gravitationally bound to the Milky way so it’s going to keep wandering into and out of star systems for a very long time. We’re talking a large multiple of the age of the universe meanwhile plenty of space rocks show encounters with other space rocks on a vastly smaller timescale. If nothing else it’s got decent odds of being part of the star formation process. Stars are ~10% of the milky way’s mass and star formation is going to continue for a while.
Supposing that it does become part of a new star, and some "nearby" civilization had sufficiently precise instruments...would that be a detectable anomaly? Like some atoms of Plutonium still haven't decayed, and isn't that weird that Plutonium's spectral signature is present in this new star? Or is that just something that happens because some plutonium is created in a supernova and might just have been floating around anyway.
Based on the interstellar density it will take a billion years to ablate just a millimetre off its outer layer.
The chance of impacting anything larger than that is internal, same as an encounter with another star. In 40,000 years it will get to within 1.6 light years from a star, that’s such an unimaginable distance it’s irrelevant.
In 100 million to 1 billion years you may not be able to recover audio from the golden record, but until that point they will be lasting remnants of a civilisation long gone, and never be encountered.
Voyagers will only impact a few thousand kilograms of material before all stars die out in 10^14 years, it will still be an object after the final stars fade.
The biggest risk to voyager now is if proton decay is a thing, or if a civilisation deliberately seeks it out, which seems very unlikely given how many natural lumps of iron int he 1 ton range flying through interstellar space.
“In 40,000 years it will get to within 1.6 light years from a star, that’s such an unimaginable distance it’s irrelevant.”
On most human timescales that’s a long time, but here it’s only 0.004% of a billion years and in general stars are ~5 light years between closest stars in our neighborhood. If you assume zero significant impacts means it’s around in 100+ billion years there will be many vastly closer passes than 1.6 lightyears. It’s the kind of thing you really need to simulate because gravity plays a larger role the closer voyager gets to another star.
Quite. It will hit the occasional something, eventually. If nothing else it will be mildly bathed in radiation of some sort.
It's going to hit gas that will slowly but inexorably sputter it to nothing.
'Slowly' is doing a lot of work there. We're talking about very large amounts of time.
Like 10^200 years
In 10^40 years it will barely have scratched the surface. Unless protons decay.
I'm imagining the sun going nova and the Voyagers surfing on that wave...
I wonder where (and in what state) they'll be by then.
I know what state I will be in by then :)
You never know! Maybe at that point all your atoms will have been recycled into a brand new consciousness absorbed into ChatGPT 7.0.
Its gonna prove the closed manifold hypothesis when it shows up coming from the opposite direction in a few hundred million years
> I heard once it will eventually lose it's form entirely
It will be sitting at something like -450F. Could it really lose form!? Is the idea that all the phonons could converge to one point, shifting an atom of metal (which will happen infinitely with infinite time)? Maybe with random photons/hydrogen/whatever "continuously" adding energy?
Neat.
From what I recall, one of the hazards of long term space travel is that nearly any material will start sublimating atoms in the hard vacuum of space, with things like cosmic rays adding to the woes. Some over time it will start deteriorating.
Not sure about “melting” into an amorphous mass, I guess in theory the probes gravity could do that, but I would imagine even the tiniest force would disturb that and dissipate it.
One issue is that over long enough timeframes, even atoms that we consider stable will decay - particularly ones that are heavier than iron, which will decay towards iron or nickel. That decay will eventually compromise the structure of the probes.
No chance of it ever being hit by anything?
> It's expected never to encounter any other object in all eternity.
This is read as "near zero" rather than "no chance". "Expected" is a word of uncertainty.
I think the rough napkin math would be: take the volume that the probe will sweep through and multiply it by the volume of matter in the universe/volume of the universe.
So a virtual impossiblity? That's a finite improbability rather than an infinite improbability. I think I need a fresh cup of really hot tea.
Space is well named.
You think it’s a long way down to the shops, but that’s peanuts compared to space.
Ah, so this is how asteroids are made!
It's cold out there, why would it melt?
It would ablate due to interstellar hydrogen, but that’s so rare over a billion years you’re taking a few millimetres.
It's got a very long time to do so. Like how a bowl of water evaporates at room temperature.
Heat ray from a passing flying saucer?
Radiation?