When does the tensor product distribute over an infinite direct product?
It is well known that the tensor product of $R$-modules over some ring $R$ does not, in general, distribute over infinite direct products, an obvious example being $mathbb Z_p otimes_mathbb Z mathbb Q neq 0$. I also know that a sufficient condition for the tensor product to distribute is this.
What other sufficient conditions are there? For instance, it would seem intuitive that $mathbb Q otimes_mathbb Z prod_mathbb N mathbb Z cong prod_mathbb N mathbb Q$. But is it?
abstract-algebra number-theory modules tensor-products infinite-product
add a comment |
It is well known that the tensor product of $R$-modules over some ring $R$ does not, in general, distribute over infinite direct products, an obvious example being $mathbb Z_p otimes_mathbb Z mathbb Q neq 0$. I also know that a sufficient condition for the tensor product to distribute is this.
What other sufficient conditions are there? For instance, it would seem intuitive that $mathbb Q otimes_mathbb Z prod_mathbb N mathbb Z cong prod_mathbb N mathbb Q$. But is it?
abstract-algebra number-theory modules tensor-products infinite-product
1
Are you considering these as groups? Please edit the question to be more specific.
– Shaun
2 hours ago
1
@Shaun Thanks for your comment. The isomorphism should be one of $mathbb Z$-modules, in the example at the end. I'll edit accordingly.
– foaly
2 hours ago
add a comment |
It is well known that the tensor product of $R$-modules over some ring $R$ does not, in general, distribute over infinite direct products, an obvious example being $mathbb Z_p otimes_mathbb Z mathbb Q neq 0$. I also know that a sufficient condition for the tensor product to distribute is this.
What other sufficient conditions are there? For instance, it would seem intuitive that $mathbb Q otimes_mathbb Z prod_mathbb N mathbb Z cong prod_mathbb N mathbb Q$. But is it?
abstract-algebra number-theory modules tensor-products infinite-product
It is well known that the tensor product of $R$-modules over some ring $R$ does not, in general, distribute over infinite direct products, an obvious example being $mathbb Z_p otimes_mathbb Z mathbb Q neq 0$. I also know that a sufficient condition for the tensor product to distribute is this.
What other sufficient conditions are there? For instance, it would seem intuitive that $mathbb Q otimes_mathbb Z prod_mathbb N mathbb Z cong prod_mathbb N mathbb Q$. But is it?
abstract-algebra number-theory modules tensor-products infinite-product
abstract-algebra number-theory modules tensor-products infinite-product
edited 2 hours ago
Shaun
8,507113580
8,507113580
asked 3 hours ago
foaly
467515
467515
1
Are you considering these as groups? Please edit the question to be more specific.
– Shaun
2 hours ago
1
@Shaun Thanks for your comment. The isomorphism should be one of $mathbb Z$-modules, in the example at the end. I'll edit accordingly.
– foaly
2 hours ago
add a comment |
1
Are you considering these as groups? Please edit the question to be more specific.
– Shaun
2 hours ago
1
@Shaun Thanks for your comment. The isomorphism should be one of $mathbb Z$-modules, in the example at the end. I'll edit accordingly.
– foaly
2 hours ago
1
1
Are you considering these as groups? Please edit the question to be more specific.
– Shaun
2 hours ago
Are you considering these as groups? Please edit the question to be more specific.
– Shaun
2 hours ago
1
1
@Shaun Thanks for your comment. The isomorphism should be one of $mathbb Z$-modules, in the example at the end. I'll edit accordingly.
– foaly
2 hours ago
@Shaun Thanks for your comment. The isomorphism should be one of $mathbb Z$-modules, in the example at the end. I'll edit accordingly.
– foaly
2 hours ago
add a comment |
2 Answers
2
active
oldest
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For instance, it would seem intuitive that $mathbb Q otimes_mathbb Z prod_mathbb N mathbb Z cong prod_mathbb N mathbb Q$. But is it?
It is not. The natural map from the LHS to the RHS fails to be surjective; its image is the subgroup of $prod mathbb{Q}$ consisting of those sequences whose terms have a common denominator, and hence does not include, for example, $prod frac{1}{n}$.
In general, for modules over a commutative ring $k$, the tensor product $M otimes_k (-)$ preserves infinite products if $M$ is finitely presented projective. I had thought at some point about whether it suffices for $M$ just to be finitely presented, but I don't remember what the conclusion was off the top of my head.
1
To be pedantic, those groups actually are isomorphic (though not by the natural map), since both are $mathbb{Q}$-vector spaces of dimension $mathfrak{c}$. Of course, the right question is whether the natural map is an isomorphism.
– Eric Wofsey
1 hour ago
add a comment |
Here is a general criterion. (All tensor products in this answer are over $R$.)
Theorem: Let $R$ be a ring and let $M$ be a right $R$-module. Then the following are equivalent.
The functor $Motimes -$ preserves products: that is, for every family $(A_i)$ of left $R$-modules, the canonical map $Motimesprod A_ito prod Motimes A_i$ is an isomorphism.
$M$ is finitely presented.
Proof: First, suppose $M$ has a finite presentation $$R^mto R^nto Mto 0$$ and let $(A_i)$ be any family of left $R$-modules. We then get a commutative diagram
$$require{AMScd}
begin{CD}
R^motimes prod A_i @>>> R^notimes prod A_i @>>> Motimes prod A_i @>>> 0\
@VV{}V @VV{}V @VV{}V \
prod R^motimes A_i @>>> prod R^notimes A_i @>>> prod Motimes A_i @>>> 0
end{CD}$$ whose rows are exact. Now note that $R^motimes prod A_icong (prod A_i)^m$ and $prod R^motimes A_icong prod A_i^m$, and our vertical map between them is easily seen to be the canonical isomorphism which interchanges the products. So the left vertical map is an isomorphism and similarly so is the middle vertical map. By the five lemma, it follows that the right vertical map is an isomorphism, and thus $Motimes -$ preserves products.
Conversely, suppose $Motimes-$ preserves products. In particular, then, the canonical map $$varphi: Motimes R^Mto M^M$$ is an isomorphism. Considering the identity map $id:Mto M$ as an element of the product $M^M$, we have $$id=varphi(sum m_i otimes f_i)$$ for some finite collection of elements $m_iin M$ and $f_i:Mto R$. Evaluating both sides of this equation at an element $min M$ we find $$m=sum m_if_i(m).$$ Thus every element of $M$ is a linear combination of the elements $m_i$, so $M$ is finitely generated.
Now let $$0to Kto Fto Mto 0$$ be a presentation of $M$ with $F$ a finitely generated free module. To conclude $M$ is finitely presented, we must show that $K$ is finitely generated. Now let $(A_i)$ be any family of flat left $R$-modules and consider the commutative diagram
$$require{AMScd}
begin{CD}
Kotimes prod A_i @>>> Fotimes prod A_i @>>> Motimes prod A_i @>>> 0\
@VV{}V @VV{}V @VV{}V \
prod Kotimes A_i @>{alpha}>> prod Fotimes A_i @>>> prod Motimes A_i @>>> 0
end{CD}$$
which again has exact rows. The right vertical map is an isomorphism by hypothesis and the middle vertical map is an isomorphism since $F$ is finitely generated and free. Moreover, the map $alpha$ is injective since the $A_i$ are flat. A simple diagram chase now shows that the left vertical map is surjective.
Thus the canonical map $Kotimes prod A_ito prod Kotimes A_i$ is surjective for any family of flat modules $(A_i)$. In particular, the canonical map $Kotimes R^Kto K^K$ is surjective, which we have seen above implies that $K$ is finitely generated.
By similar arguments, you can show that the canonical map $Motimes prod A_itoprod Motimes A_i$ is always a surjection iff $M$ is finitely generated. Indeed, the forward direction is already contained in the forward direction of the proof above, and the reverse direction is similar to the proof of the reverse direction above.
add a comment |
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2 Answers
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For instance, it would seem intuitive that $mathbb Q otimes_mathbb Z prod_mathbb N mathbb Z cong prod_mathbb N mathbb Q$. But is it?
It is not. The natural map from the LHS to the RHS fails to be surjective; its image is the subgroup of $prod mathbb{Q}$ consisting of those sequences whose terms have a common denominator, and hence does not include, for example, $prod frac{1}{n}$.
In general, for modules over a commutative ring $k$, the tensor product $M otimes_k (-)$ preserves infinite products if $M$ is finitely presented projective. I had thought at some point about whether it suffices for $M$ just to be finitely presented, but I don't remember what the conclusion was off the top of my head.
1
To be pedantic, those groups actually are isomorphic (though not by the natural map), since both are $mathbb{Q}$-vector spaces of dimension $mathfrak{c}$. Of course, the right question is whether the natural map is an isomorphism.
– Eric Wofsey
1 hour ago
add a comment |
For instance, it would seem intuitive that $mathbb Q otimes_mathbb Z prod_mathbb N mathbb Z cong prod_mathbb N mathbb Q$. But is it?
It is not. The natural map from the LHS to the RHS fails to be surjective; its image is the subgroup of $prod mathbb{Q}$ consisting of those sequences whose terms have a common denominator, and hence does not include, for example, $prod frac{1}{n}$.
In general, for modules over a commutative ring $k$, the tensor product $M otimes_k (-)$ preserves infinite products if $M$ is finitely presented projective. I had thought at some point about whether it suffices for $M$ just to be finitely presented, but I don't remember what the conclusion was off the top of my head.
1
To be pedantic, those groups actually are isomorphic (though not by the natural map), since both are $mathbb{Q}$-vector spaces of dimension $mathfrak{c}$. Of course, the right question is whether the natural map is an isomorphism.
– Eric Wofsey
1 hour ago
add a comment |
For instance, it would seem intuitive that $mathbb Q otimes_mathbb Z prod_mathbb N mathbb Z cong prod_mathbb N mathbb Q$. But is it?
It is not. The natural map from the LHS to the RHS fails to be surjective; its image is the subgroup of $prod mathbb{Q}$ consisting of those sequences whose terms have a common denominator, and hence does not include, for example, $prod frac{1}{n}$.
In general, for modules over a commutative ring $k$, the tensor product $M otimes_k (-)$ preserves infinite products if $M$ is finitely presented projective. I had thought at some point about whether it suffices for $M$ just to be finitely presented, but I don't remember what the conclusion was off the top of my head.
For instance, it would seem intuitive that $mathbb Q otimes_mathbb Z prod_mathbb N mathbb Z cong prod_mathbb N mathbb Q$. But is it?
It is not. The natural map from the LHS to the RHS fails to be surjective; its image is the subgroup of $prod mathbb{Q}$ consisting of those sequences whose terms have a common denominator, and hence does not include, for example, $prod frac{1}{n}$.
In general, for modules over a commutative ring $k$, the tensor product $M otimes_k (-)$ preserves infinite products if $M$ is finitely presented projective. I had thought at some point about whether it suffices for $M$ just to be finitely presented, but I don't remember what the conclusion was off the top of my head.
answered 1 hour ago
Qiaochu Yuan
277k32581919
277k32581919
1
To be pedantic, those groups actually are isomorphic (though not by the natural map), since both are $mathbb{Q}$-vector spaces of dimension $mathfrak{c}$. Of course, the right question is whether the natural map is an isomorphism.
– Eric Wofsey
1 hour ago
add a comment |
1
To be pedantic, those groups actually are isomorphic (though not by the natural map), since both are $mathbb{Q}$-vector spaces of dimension $mathfrak{c}$. Of course, the right question is whether the natural map is an isomorphism.
– Eric Wofsey
1 hour ago
1
1
To be pedantic, those groups actually are isomorphic (though not by the natural map), since both are $mathbb{Q}$-vector spaces of dimension $mathfrak{c}$. Of course, the right question is whether the natural map is an isomorphism.
– Eric Wofsey
1 hour ago
To be pedantic, those groups actually are isomorphic (though not by the natural map), since both are $mathbb{Q}$-vector spaces of dimension $mathfrak{c}$. Of course, the right question is whether the natural map is an isomorphism.
– Eric Wofsey
1 hour ago
add a comment |
Here is a general criterion. (All tensor products in this answer are over $R$.)
Theorem: Let $R$ be a ring and let $M$ be a right $R$-module. Then the following are equivalent.
The functor $Motimes -$ preserves products: that is, for every family $(A_i)$ of left $R$-modules, the canonical map $Motimesprod A_ito prod Motimes A_i$ is an isomorphism.
$M$ is finitely presented.
Proof: First, suppose $M$ has a finite presentation $$R^mto R^nto Mto 0$$ and let $(A_i)$ be any family of left $R$-modules. We then get a commutative diagram
$$require{AMScd}
begin{CD}
R^motimes prod A_i @>>> R^notimes prod A_i @>>> Motimes prod A_i @>>> 0\
@VV{}V @VV{}V @VV{}V \
prod R^motimes A_i @>>> prod R^notimes A_i @>>> prod Motimes A_i @>>> 0
end{CD}$$ whose rows are exact. Now note that $R^motimes prod A_icong (prod A_i)^m$ and $prod R^motimes A_icong prod A_i^m$, and our vertical map between them is easily seen to be the canonical isomorphism which interchanges the products. So the left vertical map is an isomorphism and similarly so is the middle vertical map. By the five lemma, it follows that the right vertical map is an isomorphism, and thus $Motimes -$ preserves products.
Conversely, suppose $Motimes-$ preserves products. In particular, then, the canonical map $$varphi: Motimes R^Mto M^M$$ is an isomorphism. Considering the identity map $id:Mto M$ as an element of the product $M^M$, we have $$id=varphi(sum m_i otimes f_i)$$ for some finite collection of elements $m_iin M$ and $f_i:Mto R$. Evaluating both sides of this equation at an element $min M$ we find $$m=sum m_if_i(m).$$ Thus every element of $M$ is a linear combination of the elements $m_i$, so $M$ is finitely generated.
Now let $$0to Kto Fto Mto 0$$ be a presentation of $M$ with $F$ a finitely generated free module. To conclude $M$ is finitely presented, we must show that $K$ is finitely generated. Now let $(A_i)$ be any family of flat left $R$-modules and consider the commutative diagram
$$require{AMScd}
begin{CD}
Kotimes prod A_i @>>> Fotimes prod A_i @>>> Motimes prod A_i @>>> 0\
@VV{}V @VV{}V @VV{}V \
prod Kotimes A_i @>{alpha}>> prod Fotimes A_i @>>> prod Motimes A_i @>>> 0
end{CD}$$
which again has exact rows. The right vertical map is an isomorphism by hypothesis and the middle vertical map is an isomorphism since $F$ is finitely generated and free. Moreover, the map $alpha$ is injective since the $A_i$ are flat. A simple diagram chase now shows that the left vertical map is surjective.
Thus the canonical map $Kotimes prod A_ito prod Kotimes A_i$ is surjective for any family of flat modules $(A_i)$. In particular, the canonical map $Kotimes R^Kto K^K$ is surjective, which we have seen above implies that $K$ is finitely generated.
By similar arguments, you can show that the canonical map $Motimes prod A_itoprod Motimes A_i$ is always a surjection iff $M$ is finitely generated. Indeed, the forward direction is already contained in the forward direction of the proof above, and the reverse direction is similar to the proof of the reverse direction above.
add a comment |
Here is a general criterion. (All tensor products in this answer are over $R$.)
Theorem: Let $R$ be a ring and let $M$ be a right $R$-module. Then the following are equivalent.
The functor $Motimes -$ preserves products: that is, for every family $(A_i)$ of left $R$-modules, the canonical map $Motimesprod A_ito prod Motimes A_i$ is an isomorphism.
$M$ is finitely presented.
Proof: First, suppose $M$ has a finite presentation $$R^mto R^nto Mto 0$$ and let $(A_i)$ be any family of left $R$-modules. We then get a commutative diagram
$$require{AMScd}
begin{CD}
R^motimes prod A_i @>>> R^notimes prod A_i @>>> Motimes prod A_i @>>> 0\
@VV{}V @VV{}V @VV{}V \
prod R^motimes A_i @>>> prod R^notimes A_i @>>> prod Motimes A_i @>>> 0
end{CD}$$ whose rows are exact. Now note that $R^motimes prod A_icong (prod A_i)^m$ and $prod R^motimes A_icong prod A_i^m$, and our vertical map between them is easily seen to be the canonical isomorphism which interchanges the products. So the left vertical map is an isomorphism and similarly so is the middle vertical map. By the five lemma, it follows that the right vertical map is an isomorphism, and thus $Motimes -$ preserves products.
Conversely, suppose $Motimes-$ preserves products. In particular, then, the canonical map $$varphi: Motimes R^Mto M^M$$ is an isomorphism. Considering the identity map $id:Mto M$ as an element of the product $M^M$, we have $$id=varphi(sum m_i otimes f_i)$$ for some finite collection of elements $m_iin M$ and $f_i:Mto R$. Evaluating both sides of this equation at an element $min M$ we find $$m=sum m_if_i(m).$$ Thus every element of $M$ is a linear combination of the elements $m_i$, so $M$ is finitely generated.
Now let $$0to Kto Fto Mto 0$$ be a presentation of $M$ with $F$ a finitely generated free module. To conclude $M$ is finitely presented, we must show that $K$ is finitely generated. Now let $(A_i)$ be any family of flat left $R$-modules and consider the commutative diagram
$$require{AMScd}
begin{CD}
Kotimes prod A_i @>>> Fotimes prod A_i @>>> Motimes prod A_i @>>> 0\
@VV{}V @VV{}V @VV{}V \
prod Kotimes A_i @>{alpha}>> prod Fotimes A_i @>>> prod Motimes A_i @>>> 0
end{CD}$$
which again has exact rows. The right vertical map is an isomorphism by hypothesis and the middle vertical map is an isomorphism since $F$ is finitely generated and free. Moreover, the map $alpha$ is injective since the $A_i$ are flat. A simple diagram chase now shows that the left vertical map is surjective.
Thus the canonical map $Kotimes prod A_ito prod Kotimes A_i$ is surjective for any family of flat modules $(A_i)$. In particular, the canonical map $Kotimes R^Kto K^K$ is surjective, which we have seen above implies that $K$ is finitely generated.
By similar arguments, you can show that the canonical map $Motimes prod A_itoprod Motimes A_i$ is always a surjection iff $M$ is finitely generated. Indeed, the forward direction is already contained in the forward direction of the proof above, and the reverse direction is similar to the proof of the reverse direction above.
add a comment |
Here is a general criterion. (All tensor products in this answer are over $R$.)
Theorem: Let $R$ be a ring and let $M$ be a right $R$-module. Then the following are equivalent.
The functor $Motimes -$ preserves products: that is, for every family $(A_i)$ of left $R$-modules, the canonical map $Motimesprod A_ito prod Motimes A_i$ is an isomorphism.
$M$ is finitely presented.
Proof: First, suppose $M$ has a finite presentation $$R^mto R^nto Mto 0$$ and let $(A_i)$ be any family of left $R$-modules. We then get a commutative diagram
$$require{AMScd}
begin{CD}
R^motimes prod A_i @>>> R^notimes prod A_i @>>> Motimes prod A_i @>>> 0\
@VV{}V @VV{}V @VV{}V \
prod R^motimes A_i @>>> prod R^notimes A_i @>>> prod Motimes A_i @>>> 0
end{CD}$$ whose rows are exact. Now note that $R^motimes prod A_icong (prod A_i)^m$ and $prod R^motimes A_icong prod A_i^m$, and our vertical map between them is easily seen to be the canonical isomorphism which interchanges the products. So the left vertical map is an isomorphism and similarly so is the middle vertical map. By the five lemma, it follows that the right vertical map is an isomorphism, and thus $Motimes -$ preserves products.
Conversely, suppose $Motimes-$ preserves products. In particular, then, the canonical map $$varphi: Motimes R^Mto M^M$$ is an isomorphism. Considering the identity map $id:Mto M$ as an element of the product $M^M$, we have $$id=varphi(sum m_i otimes f_i)$$ for some finite collection of elements $m_iin M$ and $f_i:Mto R$. Evaluating both sides of this equation at an element $min M$ we find $$m=sum m_if_i(m).$$ Thus every element of $M$ is a linear combination of the elements $m_i$, so $M$ is finitely generated.
Now let $$0to Kto Fto Mto 0$$ be a presentation of $M$ with $F$ a finitely generated free module. To conclude $M$ is finitely presented, we must show that $K$ is finitely generated. Now let $(A_i)$ be any family of flat left $R$-modules and consider the commutative diagram
$$require{AMScd}
begin{CD}
Kotimes prod A_i @>>> Fotimes prod A_i @>>> Motimes prod A_i @>>> 0\
@VV{}V @VV{}V @VV{}V \
prod Kotimes A_i @>{alpha}>> prod Fotimes A_i @>>> prod Motimes A_i @>>> 0
end{CD}$$
which again has exact rows. The right vertical map is an isomorphism by hypothesis and the middle vertical map is an isomorphism since $F$ is finitely generated and free. Moreover, the map $alpha$ is injective since the $A_i$ are flat. A simple diagram chase now shows that the left vertical map is surjective.
Thus the canonical map $Kotimes prod A_ito prod Kotimes A_i$ is surjective for any family of flat modules $(A_i)$. In particular, the canonical map $Kotimes R^Kto K^K$ is surjective, which we have seen above implies that $K$ is finitely generated.
By similar arguments, you can show that the canonical map $Motimes prod A_itoprod Motimes A_i$ is always a surjection iff $M$ is finitely generated. Indeed, the forward direction is already contained in the forward direction of the proof above, and the reverse direction is similar to the proof of the reverse direction above.
Here is a general criterion. (All tensor products in this answer are over $R$.)
Theorem: Let $R$ be a ring and let $M$ be a right $R$-module. Then the following are equivalent.
The functor $Motimes -$ preserves products: that is, for every family $(A_i)$ of left $R$-modules, the canonical map $Motimesprod A_ito prod Motimes A_i$ is an isomorphism.
$M$ is finitely presented.
Proof: First, suppose $M$ has a finite presentation $$R^mto R^nto Mto 0$$ and let $(A_i)$ be any family of left $R$-modules. We then get a commutative diagram
$$require{AMScd}
begin{CD}
R^motimes prod A_i @>>> R^notimes prod A_i @>>> Motimes prod A_i @>>> 0\
@VV{}V @VV{}V @VV{}V \
prod R^motimes A_i @>>> prod R^notimes A_i @>>> prod Motimes A_i @>>> 0
end{CD}$$ whose rows are exact. Now note that $R^motimes prod A_icong (prod A_i)^m$ and $prod R^motimes A_icong prod A_i^m$, and our vertical map between them is easily seen to be the canonical isomorphism which interchanges the products. So the left vertical map is an isomorphism and similarly so is the middle vertical map. By the five lemma, it follows that the right vertical map is an isomorphism, and thus $Motimes -$ preserves products.
Conversely, suppose $Motimes-$ preserves products. In particular, then, the canonical map $$varphi: Motimes R^Mto M^M$$ is an isomorphism. Considering the identity map $id:Mto M$ as an element of the product $M^M$, we have $$id=varphi(sum m_i otimes f_i)$$ for some finite collection of elements $m_iin M$ and $f_i:Mto R$. Evaluating both sides of this equation at an element $min M$ we find $$m=sum m_if_i(m).$$ Thus every element of $M$ is a linear combination of the elements $m_i$, so $M$ is finitely generated.
Now let $$0to Kto Fto Mto 0$$ be a presentation of $M$ with $F$ a finitely generated free module. To conclude $M$ is finitely presented, we must show that $K$ is finitely generated. Now let $(A_i)$ be any family of flat left $R$-modules and consider the commutative diagram
$$require{AMScd}
begin{CD}
Kotimes prod A_i @>>> Fotimes prod A_i @>>> Motimes prod A_i @>>> 0\
@VV{}V @VV{}V @VV{}V \
prod Kotimes A_i @>{alpha}>> prod Fotimes A_i @>>> prod Motimes A_i @>>> 0
end{CD}$$
which again has exact rows. The right vertical map is an isomorphism by hypothesis and the middle vertical map is an isomorphism since $F$ is finitely generated and free. Moreover, the map $alpha$ is injective since the $A_i$ are flat. A simple diagram chase now shows that the left vertical map is surjective.
Thus the canonical map $Kotimes prod A_ito prod Kotimes A_i$ is surjective for any family of flat modules $(A_i)$. In particular, the canonical map $Kotimes R^Kto K^K$ is surjective, which we have seen above implies that $K$ is finitely generated.
By similar arguments, you can show that the canonical map $Motimes prod A_itoprod Motimes A_i$ is always a surjection iff $M$ is finitely generated. Indeed, the forward direction is already contained in the forward direction of the proof above, and the reverse direction is similar to the proof of the reverse direction above.
edited 12 mins ago
answered 47 mins ago
Eric Wofsey
179k12204331
179k12204331
add a comment |
add a comment |
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1
Are you considering these as groups? Please edit the question to be more specific.
– Shaun
2 hours ago
1
@Shaun Thanks for your comment. The isomorphism should be one of $mathbb Z$-modules, in the example at the end. I'll edit accordingly.
– foaly
2 hours ago