Fine Tuning of the UniverseFine Tuned UniverseRelationship between hierarchy problem and higgs fine...
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Fine Tuning of the Universe
Fine Tuned UniverseRelationship between hierarchy problem and higgs fine tuning?Definition of Fine-TuningEarliest example of naturalness/fine-tuning argumentsMultiverse explanation of fine tuning of cosmic constantsCan dimensional regularization solve the fine-tuning problem?Are the fundamental constants of nature independent?Does the Peccei-Quinn (PQ) mechanism require fine-tuning?Why does the flatness problem (of the universe) present a fine tuning problem?Bare Cosmological Constant and Fine-Tuning Problem
$begingroup$
I'm an A level student looking into the fine tuning of various constants.
Physicists explain the extensive effects that would happen if these constants were to be changed/different and hence, how this affects the probability of life existing. What I fail to understand is why, if these constants were to be different, life wouldn't adapt to these changes. If gravity was stronger, then wouldn't the general muscle mass/stability of life be greater through evolution in order to withstand a greater force? Or am I looking at it from the wrong perspective? Some clarification on this would be appreciated.
physical-constants time-evolution cosmological-constant fine-tuning
New contributor
$endgroup$
add a comment |
$begingroup$
I'm an A level student looking into the fine tuning of various constants.
Physicists explain the extensive effects that would happen if these constants were to be changed/different and hence, how this affects the probability of life existing. What I fail to understand is why, if these constants were to be different, life wouldn't adapt to these changes. If gravity was stronger, then wouldn't the general muscle mass/stability of life be greater through evolution in order to withstand a greater force? Or am I looking at it from the wrong perspective? Some clarification on this would be appreciated.
physical-constants time-evolution cosmological-constant fine-tuning
New contributor
$endgroup$
1
$begingroup$
It's more fundamental than that: if certain constants were different, it could prevent stars and planets from forming, much less allow liquid water to exist, and then allow for organic chemistry as we know it.
$endgroup$
– Dmitry Brant
4 hours ago
$begingroup$
Some related references are cited in the introduction of "Preliminary Inconclusive Hint of Evidence Against Optimal Fine Tuning of the Cosmological Constant for Maximizing the Fraction of Baryons Becoming Life" (arxiv.org/abs/1101.2444)
$endgroup$
– Chiral Anomaly
1 hour ago
add a comment |
$begingroup$
I'm an A level student looking into the fine tuning of various constants.
Physicists explain the extensive effects that would happen if these constants were to be changed/different and hence, how this affects the probability of life existing. What I fail to understand is why, if these constants were to be different, life wouldn't adapt to these changes. If gravity was stronger, then wouldn't the general muscle mass/stability of life be greater through evolution in order to withstand a greater force? Or am I looking at it from the wrong perspective? Some clarification on this would be appreciated.
physical-constants time-evolution cosmological-constant fine-tuning
New contributor
$endgroup$
I'm an A level student looking into the fine tuning of various constants.
Physicists explain the extensive effects that would happen if these constants were to be changed/different and hence, how this affects the probability of life existing. What I fail to understand is why, if these constants were to be different, life wouldn't adapt to these changes. If gravity was stronger, then wouldn't the general muscle mass/stability of life be greater through evolution in order to withstand a greater force? Or am I looking at it from the wrong perspective? Some clarification on this would be appreciated.
physical-constants time-evolution cosmological-constant fine-tuning
physical-constants time-evolution cosmological-constant fine-tuning
New contributor
New contributor
New contributor
asked 5 hours ago
Samuel HunterSamuel Hunter
212
212
New contributor
New contributor
1
$begingroup$
It's more fundamental than that: if certain constants were different, it could prevent stars and planets from forming, much less allow liquid water to exist, and then allow for organic chemistry as we know it.
$endgroup$
– Dmitry Brant
4 hours ago
$begingroup$
Some related references are cited in the introduction of "Preliminary Inconclusive Hint of Evidence Against Optimal Fine Tuning of the Cosmological Constant for Maximizing the Fraction of Baryons Becoming Life" (arxiv.org/abs/1101.2444)
$endgroup$
– Chiral Anomaly
1 hour ago
add a comment |
1
$begingroup$
It's more fundamental than that: if certain constants were different, it could prevent stars and planets from forming, much less allow liquid water to exist, and then allow for organic chemistry as we know it.
$endgroup$
– Dmitry Brant
4 hours ago
$begingroup$
Some related references are cited in the introduction of "Preliminary Inconclusive Hint of Evidence Against Optimal Fine Tuning of the Cosmological Constant for Maximizing the Fraction of Baryons Becoming Life" (arxiv.org/abs/1101.2444)
$endgroup$
– Chiral Anomaly
1 hour ago
1
1
$begingroup$
It's more fundamental than that: if certain constants were different, it could prevent stars and planets from forming, much less allow liquid water to exist, and then allow for organic chemistry as we know it.
$endgroup$
– Dmitry Brant
4 hours ago
$begingroup$
It's more fundamental than that: if certain constants were different, it could prevent stars and planets from forming, much less allow liquid water to exist, and then allow for organic chemistry as we know it.
$endgroup$
– Dmitry Brant
4 hours ago
$begingroup$
Some related references are cited in the introduction of "Preliminary Inconclusive Hint of Evidence Against Optimal Fine Tuning of the Cosmological Constant for Maximizing the Fraction of Baryons Becoming Life" (arxiv.org/abs/1101.2444)
$endgroup$
– Chiral Anomaly
1 hour ago
$begingroup$
Some related references are cited in the introduction of "Preliminary Inconclusive Hint of Evidence Against Optimal Fine Tuning of the Cosmological Constant for Maximizing the Fraction of Baryons Becoming Life" (arxiv.org/abs/1101.2444)
$endgroup$
– Chiral Anomaly
1 hour ago
add a comment |
1 Answer
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$begingroup$
The variation you are talking about here would still be considered relatively 'fine-tuned', in the following sense:
If the strength of gravity was stronger by such an amount such that the processes that govern the formation of stars, planets, complex molecules, and life were relatively unchanged (in that they still take place in a recognizable fashion), then the strength of gravity must be quite similar to what we observe. If this were the case, yes, there is no reason that life might not develop to be a bit tougher.
However, such a difference would have to be very small indeed. Arguments about fine-tuning are based on the observation that even relatively small changes to certain constants would be enough to drastically change the make-up of the universe.
For example, Paul Davies notes that if the strong force were 2% stronger than it is, hydrogen would fuse to form diprotons as opposed to helium as it would be energetically favorable. This would drastically alter structure formation in the early universe, leading to a today where planets do not even exist, let alone weak or strong animals on them. I should note here that the 2% figure quoted by Davies may not be accurate, but this is the idea at play here.
In short, the problems from fine-tuning start to occur far before life would ever develop in the first place.
$endgroup$
$begingroup$
also look at the triple $alpha$ process (en.wikipedia.org/wiki/Triple-alpha_process) which appears terribly fine tuned, and is the only way to make lots of carbon and oxygen, which are life's favorite elements.
$endgroup$
– JEB
2 hours ago
add a comment |
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$begingroup$
The variation you are talking about here would still be considered relatively 'fine-tuned', in the following sense:
If the strength of gravity was stronger by such an amount such that the processes that govern the formation of stars, planets, complex molecules, and life were relatively unchanged (in that they still take place in a recognizable fashion), then the strength of gravity must be quite similar to what we observe. If this were the case, yes, there is no reason that life might not develop to be a bit tougher.
However, such a difference would have to be very small indeed. Arguments about fine-tuning are based on the observation that even relatively small changes to certain constants would be enough to drastically change the make-up of the universe.
For example, Paul Davies notes that if the strong force were 2% stronger than it is, hydrogen would fuse to form diprotons as opposed to helium as it would be energetically favorable. This would drastically alter structure formation in the early universe, leading to a today where planets do not even exist, let alone weak or strong animals on them. I should note here that the 2% figure quoted by Davies may not be accurate, but this is the idea at play here.
In short, the problems from fine-tuning start to occur far before life would ever develop in the first place.
$endgroup$
$begingroup$
also look at the triple $alpha$ process (en.wikipedia.org/wiki/Triple-alpha_process) which appears terribly fine tuned, and is the only way to make lots of carbon and oxygen, which are life's favorite elements.
$endgroup$
– JEB
2 hours ago
add a comment |
$begingroup$
The variation you are talking about here would still be considered relatively 'fine-tuned', in the following sense:
If the strength of gravity was stronger by such an amount such that the processes that govern the formation of stars, planets, complex molecules, and life were relatively unchanged (in that they still take place in a recognizable fashion), then the strength of gravity must be quite similar to what we observe. If this were the case, yes, there is no reason that life might not develop to be a bit tougher.
However, such a difference would have to be very small indeed. Arguments about fine-tuning are based on the observation that even relatively small changes to certain constants would be enough to drastically change the make-up of the universe.
For example, Paul Davies notes that if the strong force were 2% stronger than it is, hydrogen would fuse to form diprotons as opposed to helium as it would be energetically favorable. This would drastically alter structure formation in the early universe, leading to a today where planets do not even exist, let alone weak or strong animals on them. I should note here that the 2% figure quoted by Davies may not be accurate, but this is the idea at play here.
In short, the problems from fine-tuning start to occur far before life would ever develop in the first place.
$endgroup$
$begingroup$
also look at the triple $alpha$ process (en.wikipedia.org/wiki/Triple-alpha_process) which appears terribly fine tuned, and is the only way to make lots of carbon and oxygen, which are life's favorite elements.
$endgroup$
– JEB
2 hours ago
add a comment |
$begingroup$
The variation you are talking about here would still be considered relatively 'fine-tuned', in the following sense:
If the strength of gravity was stronger by such an amount such that the processes that govern the formation of stars, planets, complex molecules, and life were relatively unchanged (in that they still take place in a recognizable fashion), then the strength of gravity must be quite similar to what we observe. If this were the case, yes, there is no reason that life might not develop to be a bit tougher.
However, such a difference would have to be very small indeed. Arguments about fine-tuning are based on the observation that even relatively small changes to certain constants would be enough to drastically change the make-up of the universe.
For example, Paul Davies notes that if the strong force were 2% stronger than it is, hydrogen would fuse to form diprotons as opposed to helium as it would be energetically favorable. This would drastically alter structure formation in the early universe, leading to a today where planets do not even exist, let alone weak or strong animals on them. I should note here that the 2% figure quoted by Davies may not be accurate, but this is the idea at play here.
In short, the problems from fine-tuning start to occur far before life would ever develop in the first place.
$endgroup$
The variation you are talking about here would still be considered relatively 'fine-tuned', in the following sense:
If the strength of gravity was stronger by such an amount such that the processes that govern the formation of stars, planets, complex molecules, and life were relatively unchanged (in that they still take place in a recognizable fashion), then the strength of gravity must be quite similar to what we observe. If this were the case, yes, there is no reason that life might not develop to be a bit tougher.
However, such a difference would have to be very small indeed. Arguments about fine-tuning are based on the observation that even relatively small changes to certain constants would be enough to drastically change the make-up of the universe.
For example, Paul Davies notes that if the strong force were 2% stronger than it is, hydrogen would fuse to form diprotons as opposed to helium as it would be energetically favorable. This would drastically alter structure formation in the early universe, leading to a today where planets do not even exist, let alone weak or strong animals on them. I should note here that the 2% figure quoted by Davies may not be accurate, but this is the idea at play here.
In short, the problems from fine-tuning start to occur far before life would ever develop in the first place.
edited 4 hours ago
answered 4 hours ago
gabegabe
13711
13711
$begingroup$
also look at the triple $alpha$ process (en.wikipedia.org/wiki/Triple-alpha_process) which appears terribly fine tuned, and is the only way to make lots of carbon and oxygen, which are life's favorite elements.
$endgroup$
– JEB
2 hours ago
add a comment |
$begingroup$
also look at the triple $alpha$ process (en.wikipedia.org/wiki/Triple-alpha_process) which appears terribly fine tuned, and is the only way to make lots of carbon and oxygen, which are life's favorite elements.
$endgroup$
– JEB
2 hours ago
$begingroup$
also look at the triple $alpha$ process (en.wikipedia.org/wiki/Triple-alpha_process) which appears terribly fine tuned, and is the only way to make lots of carbon and oxygen, which are life's favorite elements.
$endgroup$
– JEB
2 hours ago
$begingroup$
also look at the triple $alpha$ process (en.wikipedia.org/wiki/Triple-alpha_process) which appears terribly fine tuned, and is the only way to make lots of carbon and oxygen, which are life's favorite elements.
$endgroup$
– JEB
2 hours ago
add a comment |
Samuel Hunter is a new contributor. Be nice, and check out our Code of Conduct.
Samuel Hunter is a new contributor. Be nice, and check out our Code of Conduct.
Samuel Hunter is a new contributor. Be nice, and check out our Code of Conduct.
Samuel Hunter is a new contributor. Be nice, and check out our Code of Conduct.
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It's more fundamental than that: if certain constants were different, it could prevent stars and planets from forming, much less allow liquid water to exist, and then allow for organic chemistry as we know it.
$endgroup$
– Dmitry Brant
4 hours ago
$begingroup$
Some related references are cited in the introduction of "Preliminary Inconclusive Hint of Evidence Against Optimal Fine Tuning of the Cosmological Constant for Maximizing the Fraction of Baryons Becoming Life" (arxiv.org/abs/1101.2444)
$endgroup$
– Chiral Anomaly
1 hour ago