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A ring with ACC on prime ideals, whose spectrum is non-noetherian.

I am currently working on the converse of the exercise #12 on chapter 6 of Atiyah-Macdonald's book on commutative algebra. The problem is asking whether there is a ring $A$, which satisfies the ascending chain condition on prime ideals(That is, every chain of prime ideals of a ring $A$ stabilizes) such that Spec($A$) is a non-noetherian space.

The problem is asking whether there is a ring $A$ which satisfies the ascending chain condition on prime ideals (that is, every chain of prime ideals of a ring $A$ stabilizes) such that $\mathrm{Spec}(A)$ is a non-noetherian space.

What I've tried so far was first, struggling with the proof that spec($A$) is noetherian when $A$ satisfies ACC on prime ideals, but I got stuck because I failed to extract ascending chains of prime ideals.

So I tried to find a counterexample. So, I looked up some examples of non-noetherian rings so that I can have non-noetherian spectrum. (It was tough for most cases since non-noetherian rings can have a noetherian spectrum. For example, the integral closure of $\mathbb{Z}$ in $\mathbb{C}$ is not noetherian. However, I couldn't understand whether it's spectrum is noetherian or not.) butBut, in every cases, I also couldn't find an appropriate counterexample.

Is there any hint or comment about what I should consider? Any help will be appreciated.

A ring with ACC on prime ideals, whose spectrum is non-noetherian.

I am currently working on the converse of the exercise #12 on chapter 6 of Atiyah-Macdonald's book on commutative algebra. The problem is asking whether there is a ring $A$, which satisfies the ascending chain condition on prime ideals(That is, every chain of prime ideals of a ring $A$ stabilizes) such that Spec($A$) is a non-noetherian space.

What I've tried so far was first, struggling with the proof that spec($A$) is noetherian when $A$ satisfies ACC on prime ideals, but I got stuck because I failed to extract ascending chains of prime ideals.

So I tried to find a counterexample. So, I looked up some examples of non-noetherian rings so that I can have non-noetherian spectrum(It was tough for most cases since non-noetherian rings can have a noetherian spectrum. For example, the integral closure of $\mathbb{Z}$ in $\mathbb{C}$ is not noetherian. However, I couldn't understand whether it's spectrum is noetherian or not.) but, in every cases, I also couldn't find an appropriate counterexample.

Is there any hint or comment about what I should consider? Any help will be appreciated.

A ring with ACC on prime ideals whose spectrum is non-noetherian.

I am currently working on the converse of the exercise #12 on chapter 6 of Atiyah-Macdonald's book on commutative algebra.

The problem is asking whether there is a ring $A$ which satisfies the ascending chain condition on prime ideals (that is, every chain of prime ideals of a ring $A$ stabilizes) such that $\mathrm{Spec}(A)$ is a non-noetherian space.

What I've tried so far was first, struggling with the proof that spec($A$) is noetherian when $A$ satisfies ACC on prime ideals, but I got stuck because I failed to extract ascending chains of prime ideals.

So I tried to find a counterexample. So, I looked up some examples of non-noetherian rings so that I can have non-noetherian spectrum. (It was tough for most cases since non-noetherian rings can have a noetherian spectrum. For example, the integral closure of $\mathbb{Z}$ in $\mathbb{C}$ is not noetherian. However, I couldn't understand whether it's spectrum is noetherian or not.) But, in every cases, I also couldn't find an appropriate counterexample.

Is there any hint or comment about what I should consider? Any help will be appreciated.

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A ring with ACC on prime ideals, whose spectrum is non-noetherian.

I am currently working on the converse of the exercise #12 on chapter 6 of Atiyah-Macdonald's book on commutative algebra. The problem is asking whether there is a ring $A$, which satisfies the ascending chain condition on prime ideals(That is, every chain of prime ideals of a ring $A$ stabilizes) such that Spec($A$) is a non-noetherian space.

What I've tried so far was first, struggling with the proof that spec($A$) is noetherian when $A$ satisfies ACC on prime ideals, but I got stuck because I failed to extract ascending chains of prime ideals.

So I tried to find a counterexample. So, I looked up some examples of non-noetherian rings so that I can have non-noetherian spectrum(It was tough for most cases since non-noetherian rings can have a noetherian spectrum. For example, the integral closure of $\mathbb{Z}$ in $\mathbb{C}$ is not noetherian. However, I couldn't understand whether it's spectrum is noetherian or not.) but, in every cases, I also couldn't find an appropriate counterexample.

Is there any hint or comment about what I should consider? Any help will be appreciated.