Nobody knows. To know this, we would need to know the correct theory which describes how regions of the universe like our own are generated.brushman said:What's the probability of a universe capable of life? In other words, what's the probability that the laws of the universe allow for life?
And if the probability is low, does that imply there are infinite universes? Or there is a "god"?
brushman said:What's the probability of a universe capable of life? In other words, what's the probability that the laws of the universe allow for life?
And if the probability is low, does that imply there are infinite universes? Or there is a "god"?
bapowell said:Why do all answers to this question overlook the terribly complicated and unknown processes by which life gets started once (and if) a habitable place in the universe exists? You might succeed in finding another Earth in our very universe (surely many such planets exist) but until you understand how nucleic acids synthesize out of the primordial soup, questions like this are moot.
Right, except I don't think my objection is a marginal detail like paint on a time machine. It's completely central to the discussion. The question of whether or not intelligent life exists elsewhere in the universe is deeply important, and fun to think about. But people tend to get lost in debates about cosmological constants, bubbles in the string landscape, the Drake equation, etc. This are 0th order requirements for the existence of life. However, it's the sort of '1st order' problem -- the actual development of life -- that is not too well understood at present and seems to be fully ignored by most physicists. I'm a physicist myself, so it's not like I'm some pissed off biologist that's disgruntled that my science is being ignored ;) I just think we should at least acknowledge that we are ignoring abiogenesis completely when we are supposedly discussing whether a certain universe or planet is 'capable of life'.Visigoth said:Physicists generally don't concern over the structural dynamics of the paint on a spaceship with the ability to travel through time. :P
bapowell said:Right, except I don't think my objection is a marginal detail like paint on a time machine. It's completely central to the discussion. The question of whether or not intelligent life exists elsewhere in the universe is deeply important, and fun to think about. But people tend to get lost in debates about cosmological constants, bubbles in the string landscape, the Drake equation, etc. This are 0th order requirements for the existence of life. However, it's the sort of '1st order' problem -- the actual development of life -- that is not too well understood at present and seems to be fully ignored by most physicists. I'm a physicist myself, so it's not like I'm some pissed off biologist that's disgruntled that my science is being ignored ;) I just think we should at least acknowledge that we are ignoring abiogenesis completely when we are supposedly discussing whether a certain universe or planet is 'capable of life'.
Chalnoth said:I'd just like to add a small point: though our current evidence is wholly and utterly insufficient to come close to pinning down what portion of the universe contains life, the evidence most definitely seems to point in the direction of vast volumes of space that are barren and lifeless, with some small regions here and there (like our own) that contain the occasional life-bearing planet.
mathman said:I wonder where you got this information. I have been under the impression that our sun was a rather ordinary star. I would assume that similar stars would have similar planetary systems, including some earthlike planets. I doubt if they are particularly rare.
You're both a little bit off from what I meant. What I meant is that I expect that the vast majority of Hubble volumes are entirely devoid of life.Visigoth said:I think what he's suggesting is that the amount of empty space far exceeds the amount of occupied space in the Universe. Certainly, there's trillions and trillions of stars in our galaxy alone, but the amount of empty space between those stars, and between our galaxy and others, is exponentially larger.
Is this your guess or is there some study which leads to this conclusion?Chalnoth said:You're both a little bit off from what I meant. What I meant is that I expect that the vast majority of Hubble volumes are entirely devoid of life.
Well, as I said, without knowing how Hubble volumes like our own get started, we can't really know this for sure.mathman said:Is this your guess or is there some study which leads to this conclusion?
Aren't the physical constants supposed to be the same throughout the observable universe?The second bit of suggestive evidence comes from dumb examinations of the physical constants: slight changes in most of them result in a universe which would be devoid of life. Now, these are rather dumb examinations, because without the correct theory explaining how new Hubble volumes get started, we don't have the probability distribution for these constants. But taking either a dumb flat prior or a logarithmic one seems to indicate that the region of parameter space available to life is likely to be a tiny fraction of the whole.
Yes, but we also know that the observable universe is but a small fraction of the whole.mathman said:Aren't the physical constants supposed to be the same throughout the observable universe?
The probability of a universe capable of life is currently unknown and is still a topic of debate among scientists. Some theories suggest that the probability is very low, while others argue that it is near certain. It is also important to note that the concept of probability may not apply to the existence of our universe as it is a unique and singular event.
Currently, there is no way to accurately calculate the probability of a universe capable of life. This is because there are many unknown factors and variables that contribute to the formation of our universe. Additionally, the concept of probability may not be applicable to the existence of our universe as it is a singular event.
There are many factors that contribute to the probability of a universe capable of life. These include the physical laws and constants of the universe, the initial conditions of the Big Bang, the distribution of matter and energy, and the existence of complex molecules necessary for life. However, it is difficult to determine the exact role each of these factors plays in the probability of a universe capable of life.
There are various theories and explanations for the probability of a universe capable of life. Some scientists argue that the fine-tuning of the physical constants and laws of the universe points to a higher probability of a universe capable of life. Others suggest the possibility of a multiverse, where our universe is just one of many, with different physical laws and constants in each, increasing the chances of a universe capable of life.
The concept of probability plays a significant role in our understanding of the universe. It helps us make predictions and calculations about the likelihood of events occurring. However, in the case of the existence of our universe, the concept of probability may not be applicable as it is a unique and singular event. Therefore, it is important to approach the topic with an open mind and continue to explore and research to gain a deeper understanding of our universe.