mfb said:Without gravity there would be no stars and no structures at all. We would just have a thin cloud of hydrogen and helium atoms, probably with a few hydrogen molecules.
A lower gravitational constant tends to make gravitationally bound objects larger. For the lifetime of stars there are several competing changes in different directions, hard to tell what would win. Gas giants would be more common compared to rock planets.
I agree, just looking for published material on this questions. But can't seem to find any.mfb said:I don't know specific limits.
A general thing to keep in mind: These limits are typically for "life as we know it". Different parameters could lead to life-like structures that look completely different.
I think even this is hard to imagine. Assuming molecules to exist would require a cosmological model which is consistent with this assumption. It seems that a spacetime without attractive gravity would expand exponentially or would be flat. So, "reheating" with condensation of matter wouldn't happen.mfb said:Without gravity there would be no stars and no structures at all. We would just have a thin cloud of hydrogen and helium atoms, probably with a few hydrogen molecules.
Do you have a cosmological model (without gravity) in mind according to which hydrogen atoms would be created?mfb said:You should always have a few odd neutral hydrogen collisions that form molecules.
Anthropic constraints on G refer to the idea that the fundamental physical constants of the universe, such as the gravitational constant G, are finely-tuned to allow for the existence of life. This concept is often used in the anthropic principle, which states that the observed values of these constants must be compatible with the existence of observers.
G is a crucial factor in the formation and evolution of stars and galaxies. It determines the strength of gravitational attraction between objects, which plays a key role in the collapse of gas clouds to form stars and the formation of galactic structures.
While there is currently no strong evidence to suggest that the value of G has changed over time, some theories such as varying speed of light (VSL) propose that G and other physical constants may have had different values in the past. However, these theories are still highly debated and have not been widely accepted.
G is one of the key factors in determining the rate of expansion of the universe. The value of G, along with the density of matter in the universe, influences the strength of gravitational attraction between objects. This can either slow down or accelerate the expansion of the universe.
Anthropic constraints on G suggest that the values of physical constants in our universe are highly fine-tuned to allow for the existence of life. This has led some scientists to believe that the chances of finding intelligent life elsewhere in the universe may be slim, as the conditions necessary for life to exist may be rare. However, this is still a highly debated topic and further research is needed.