*DEAFENING SILENCE*
I expect my audience to be already familiar with the concept of the Great Silence, but for those who need a refreshment - it is the current situation that we find ourselves in. That despite all odds being apparently stacked in favor of Life being abundant in the universe, and by consequence intelligence as well - we see no obvious technosignatures in the sky, mainly radio signals, hence the name Great Silence.
My stance regarding possible solutions to the Fermi Paradox is to think we are, if not the earliest, among the ealiest civilizations in this side of the galaxy. And my reasoning for this is the following:
Earth has been technologically detectable for at least 64 years (circa 1958), this means that if our signal had reached any technological civilization with intent of immediate response we would have gotten that response in now in early 2020s (30 years to send, and 30 years to reply), we can be sure to a considerable degree that our interstellar neighborhood all belongs to humanity for a minimum radius of 30 light-years from the Sun. In the same train of thought, we can be sure that we are not within 60 light-years from any other nearby technological civilizations which happen to be on a similar or slightly superior technological level, else we would have already received unambiguous radio signals from space.
Moving further away from Earth, and time dilation kicks harder, had another civilization 100ly away started broadcasting in 1900s, we would be receiving their signals in the early 2000s, and the same for one 200ly away starting in the 1800s, and so on. The further we start looking into space for technosignatures, the older these civilizations would have to be in order to justify the Great Silence, and that is just a lower bound which assumes we would be receiving their signals any time soon. Now, if you consider that the age and epoch of first broadcast differ enough from one another, then those civilizations would have become detectable from Earth before we had ever finished building the first radiotelescope array.
For example, a technological civilization that goes on air circa 3000 BCE from 4000ly away would have become detectable on Earth in the year 1000 CE, only to be finally discovered post 1950. But that assumes that they had been on air for nearly 1000 years, this becomes difficult if civilizations become more silent over time due improvements in technology, security concerns, or setbacks due internal conflicts or disasters. Yet a civilization doesn't simply become invisible after switching SETI policy or technology, there is no way to stop a signal once sent, and so a predictable pattern would emerge in that civilizations appear very bright in the dawn of their development, only to minimize their radio footprint over time.
Let's picture the following, the Milky Way galaxy isn't exactly a galaxy in its prime of stellar formation, for its size and metallicity it used to be much more active in the deep past, and a deep past marked by merger events with other galaxies. The interaction between stars passing near each other and through gas clouds during a merger is one way star formation can be increased for a period of time, and thus the rate at which potentially habitable systems emerge. We also know that some regions of the galaxy have a higher average metallicity than others, it isn't like the galaxy uniformly increases its metallicity over time, the galactic thin disk sees way more action than the thick disk or halo, and so some regions could very been host to the prime conditions for planetary systems and habitable planets aeons before the Sun was born, thounsands if not millions of worlds would have a headstart of a few billion years, yet we are stuck the Great Silence, leading to the Fermi Paradox. Now, if we find out that a planet hosting Life far away from Earth, orbits a star just as old as the Sun, say like another yellow dwarf or orange dwarf, then we can start to suspect that all Life that currently inhabits the galaxy was born in the same epoch, a merger epoch approximately 5 to 8 billion years ago, and we would see clumps of similarly aged planets across the galaxy.
Let's say you want to mine a large asteroid 12km wide, at an average rocky density this would only amount to half a billionth of the Earth's mass, or about 3.2 trillion tons of resources. And there are rocks way larger than that across the whole of the solar system, most of which can be readily acessed in moons and the asteroid belt. A quick search shows that in 2019, humans have mined over 3.2 billion tones of metal of the Earth, 94% of which is iron ore - our little12 km-wide rock at 1% metal could supply almost 10x our current yearly needs. And we are talking about an asteroid that's 99% rock, your typical metallic asteroid is nearly 90-95% metals by mass, a single rock could supply the Earth with metals for the next 1000 years, or hundreds of times more infraestructure built per year if our consumption increases several fold. And so, mining your own solar system would provide nearly all the metal, rock, and volatiles you may ever need for thousands of years, and even millions of years if you reach out for other stars. You will only ever run out of stuff if you run out of personel or machinery to do so. So civilizations would be "forced" to stay at their local space, because there is nothing outside of it that they cannot obtain in their collection of worlds.
- M.O. Valent, published 09/10/2022