The solvability group criteria in Cox's Galois Theory The 2019 Stack Overflow Developer Survey Results Are InA Galois Group ProblemEvery finite abelian group is the Galois group of of some finite extension of the rationalsGroup theory with analysisGeneralized fundamental theorem of Galois theoryMAGMA Commands for Galois Theory calculationsGalois theory in reverseGalois Extension whose Galois Group is $mathbbZ_2oplusmathbbZ_4$Group Theory: Suggest video lecture (In English)Grothendieck's Galois theory: fundamental theoremMathematics, Group Theory
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The solvability group criteria in Cox's Galois Theory
The 2019 Stack Overflow Developer Survey Results Are InA Galois Group ProblemEvery finite abelian group is the Galois group of of some finite extension of the rationalsGroup theory with analysisGeneralized fundamental theorem of Galois theoryMAGMA Commands for Galois Theory calculationsGalois theory in reverseGalois Extension whose Galois Group is $mathbbZ_2oplusmathbbZ_4$Group Theory: Suggest video lecture (In English)Grothendieck's Galois theory: fundamental theoremMathematics, Group Theory
$begingroup$
It's a long time I'm studying group theory in many level of depth, heading to Co.0 and Monster groups construction. Time by time, I come in contact with Galois Theory, where the solvability strictly connects to simple groups, of course.
Actually, reading Cox's text Galois Theory, I came across a different definition than the one I ever seen, which sounds like this:
given a chain/sequence of normal subgroups from the full group G up to e, where Gn relates to e, a group is solvable if:
- descending in the sequence, each subgroup is normal in the following one;
- the index of this normal subgroup in the following one is prime.
Actually, I'm puzzled by point 2): I've always seen this point as "the quotient of neighbour subgroups is abelian".
I mean, I know every finitely generated abelian group is a direct product of cyclic groups, but I cannot see how this relates to the index to be a prime.
More than this: I've read many books on this and splitting fields and cascade and correspondence of extensions and subgroups make sense to me, but I always loose the main point, when coming to the meat:
how this abelian criteria is guaranteeing to have roots with radicals?
Every book depicts the usual example of A5, but I'm lost every time to get an intuitive view of this abelian --> radical correspondence.
Thanks as always for your precious help and support.
group-theory galois-theory
asked Mar 30 at 8:14
riccardoventrellariccardoventrella
728
$endgroup$
|
show 4 more comments
$begingroup$
It's a long time I'm studying group theory in many level of depth, heading to Co.0 and Monster groups construction. Time by time, I come in contact with Galois Theory, where the solvability strictly connects to simple groups, of course.
Actually, reading Cox's text Galois Theory, I came across a different definition than the one I ever seen, which sounds like this:
given a chain/sequence of normal subgroups from the full group G up to e, where Gn relates to e, a group is solvable if:
- descending in the sequence, each subgroup is normal in the following one;
- the index of this normal subgroup in the following one is prime.
Actually, I'm puzzled by point 2): I've always seen this point as "the quotient of neighbour subgroups is abelian".
I mean, I know every finitely generated abelian group is a direct product of cyclic groups, but I cannot see how this relates to the index to be a prime.
More than this: I've read many books on this and splitting fields and cascade and correspondence of extensions and subgroups make sense to me, but I always loose the main point, when coming to the meat:
how this abelian criteria is guaranteeing to have roots with radicals?
Every book depicts the usual example of A5, but I'm lost every time to get an intuitive view of this abelian --> radical correspondence.
Thanks as always for your precious help and support.
group-theory galois-theory
asked Mar 30 at 8:14
riccardoventrellariccardoventrella
728
$endgroup$
$begingroup$
One can refine a chain with finite Abelian quotients to a chain with finite prime order quotients, since each finite non-trivial Abelian group has a quotient of prime index.
$endgroup$
– Lord Shark the Unknown
Mar 30 at 8:19
$begingroup$
Thank LordShark, may you do an example please? For example, the Klein four group is solvable and the index of e in it is 4. So it's not prime, as far as I can see. Where am I wrong?
$endgroup$
– riccardoventrella
Mar 30 at 8:21
1
$begingroup$
$V_4$ has a subgroup of order $2$, necessarily normal.
$endgroup$
– Lord Shark the Unknown
Mar 30 at 8:23
1
$begingroup$
That is a very odd definition...What Dixon's Galois Theory? I've never heard of it and I googled it and didn't find anything...What I know is that a finite group is solvable iff it has a subnormal series from the trivial group to the whole one such that each quotient is cyclic of order dome prime. Read Lord's comment. But this is hardly used as a definition, which is usually way more general.
$endgroup$
– DonAntonio
Mar 30 at 8:26
$begingroup$
Welcome to Math.SE! Please use MathJax. For some basic information about writing math at this site see e.g. basic help on mathjax notation, mathjax tutorial and quick reference, main meta site math tutorial and equation editing how-to.
$endgroup$
– GNUSupporter 8964民主女神 地下教會
Mar 30 at 10:47
|
show 4 more comments
$begingroup$
It's a long time I'm studying group theory in many level of depth, heading to Co.0 and Monster groups construction. Time by time, I come in contact with Galois Theory, where the solvability strictly connects to simple groups, of course.
Actually, reading Cox's text Galois Theory, I came across a different definition than the one I ever seen, which sounds like this:
given a chain/sequence of normal subgroups from the full group G up to e, where Gn relates to e, a group is solvable if:
- descending in the sequence, each subgroup is normal in the following one;
- the index of this normal subgroup in the following one is prime.
Actually, I'm puzzled by point 2): I've always seen this point as "the quotient of neighbour subgroups is abelian".
I mean, I know every finitely generated abelian group is a direct product of cyclic groups, but I cannot see how this relates to the index to be a prime.
More than this: I've read many books on this and splitting fields and cascade and correspondence of extensions and subgroups make sense to me, but I always loose the main point, when coming to the meat:
how this abelian criteria is guaranteeing to have roots with radicals?
Every book depicts the usual example of A5, but I'm lost every time to get an intuitive view of this abelian --> radical correspondence.
Thanks as always for your precious help and support.
group-theory galois-theory
asked Mar 30 at 8:14
riccardoventrellariccardoventrella
728
$endgroup$
It's a long time I'm studying group theory in many level of depth, heading to Co.0 and Monster groups construction. Time by time, I come in contact with Galois Theory, where the solvability strictly connects to simple groups, of course.
Actually, reading Cox's text Galois Theory, I came across a different definition than the one I ever seen, which sounds like this:
given a chain/sequence of normal subgroups from the full group G up to e, where Gn relates to e, a group is solvable if:
- descending in the sequence, each subgroup is normal in the following one;
- the index of this normal subgroup in the following one is prime.
Actually, I'm puzzled by point 2): I've always seen this point as "the quotient of neighbour subgroups is abelian".
I mean, I know every finitely generated abelian group is a direct product of cyclic groups, but I cannot see how this relates to the index to be a prime.
More than this: I've read many books on this and splitting fields and cascade and correspondence of extensions and subgroups make sense to me, but I always loose the main point, when coming to the meat:
how this abelian criteria is guaranteeing to have roots with radicals?
Every book depicts the usual example of A5, but I'm lost every time to get an intuitive view of this abelian --> radical correspondence.
Thanks as always for your precious help and support.
group-theory galois-theory
group-theory galois-theory
asked Mar 30 at 8:14
riccardoventrellariccardoventrella
728
asked Mar 30 at 8:14
riccardoventrellariccardoventrella
728
edited Mar 30 at 11:19
riccardoventrella
asked Mar 30 at 8:14
riccardoventrellariccardoventrella
728
asked Mar 30 at 8:14
riccardoventrellariccardoventrella
728
asked Mar 30 at 8:14
riccardoventrellariccardoventrella
728
728
$begingroup$
One can refine a chain with finite Abelian quotients to a chain with finite prime order quotients, since each finite non-trivial Abelian group has a quotient of prime index.
$endgroup$
– Lord Shark the Unknown
Mar 30 at 8:19
$begingroup$
Thank LordShark, may you do an example please? For example, the Klein four group is solvable and the index of e in it is 4. So it's not prime, as far as I can see. Where am I wrong?
$endgroup$
– riccardoventrella
Mar 30 at 8:21
1
$begingroup$
$V_4$ has a subgroup of order $2$, necessarily normal.
$endgroup$
– Lord Shark the Unknown
Mar 30 at 8:23
1
$begingroup$
That is a very odd definition...What Dixon's Galois Theory? I've never heard of it and I googled it and didn't find anything...What I know is that a finite group is solvable iff it has a subnormal series from the trivial group to the whole one such that each quotient is cyclic of order dome prime. Read Lord's comment. But this is hardly used as a definition, which is usually way more general.
$endgroup$
– DonAntonio
Mar 30 at 8:26
$begingroup$
Welcome to Math.SE! Please use MathJax. For some basic information about writing math at this site see e.g. basic help on mathjax notation, mathjax tutorial and quick reference, main meta site math tutorial and equation editing how-to.
$endgroup$
– GNUSupporter 8964民主女神 地下教會
Mar 30 at 10:47
|
show 4 more comments
$begingroup$
One can refine a chain with finite Abelian quotients to a chain with finite prime order quotients, since each finite non-trivial Abelian group has a quotient of prime index.
$endgroup$
– Lord Shark the Unknown
Mar 30 at 8:19
$begingroup$
Thank LordShark, may you do an example please? For example, the Klein four group is solvable and the index of e in it is 4. So it's not prime, as far as I can see. Where am I wrong?
$endgroup$
– riccardoventrella
Mar 30 at 8:21
1
$begingroup$
$V_4$ has a subgroup of order $2$, necessarily normal.
$endgroup$
– Lord Shark the Unknown
Mar 30 at 8:23
1
$begingroup$
That is a very odd definition...What Dixon's Galois Theory? I've never heard of it and I googled it and didn't find anything...What I know is that a finite group is solvable iff it has a subnormal series from the trivial group to the whole one such that each quotient is cyclic of order dome prime. Read Lord's comment. But this is hardly used as a definition, which is usually way more general.
$endgroup$
– DonAntonio
Mar 30 at 8:26
$begingroup$
Welcome to Math.SE! Please use MathJax. For some basic information about writing math at this site see e.g. basic help on mathjax notation, mathjax tutorial and quick reference, main meta site math tutorial and equation editing how-to.
$endgroup$
– GNUSupporter 8964民主女神 地下教會
Mar 30 at 10:47
$begingroup$
One can refine a chain with finite Abelian quotients to a chain with finite prime order quotients, since each finite non-trivial Abelian group has a quotient of prime index.
$endgroup$
– Lord Shark the Unknown
Mar 30 at 8:19
$begingroup$
One can refine a chain with finite Abelian quotients to a chain with finite prime order quotients, since each finite non-trivial Abelian group has a quotient of prime index.
$endgroup$
– Lord Shark the Unknown
Mar 30 at 8:19
$begingroup$
Thank LordShark, may you do an example please? For example, the Klein four group is solvable and the index of e in it is 4. So it's not prime, as far as I can see. Where am I wrong?
$endgroup$
– riccardoventrella
Mar 30 at 8:21
$begingroup$
Thank LordShark, may you do an example please? For example, the Klein four group is solvable and the index of e in it is 4. So it's not prime, as far as I can see. Where am I wrong?
$endgroup$
– riccardoventrella
Mar 30 at 8:21
1
1
$begingroup$
$V_4$ has a subgroup of order $2$, necessarily normal.
$endgroup$
– Lord Shark the Unknown
Mar 30 at 8:23
$begingroup$
$V_4$ has a subgroup of order $2$, necessarily normal.
$endgroup$
– Lord Shark the Unknown
Mar 30 at 8:23
1
1
$begingroup$
That is a very odd definition...What Dixon's Galois Theory? I've never heard of it and I googled it and didn't find anything...What I know is that a finite group is solvable iff it has a subnormal series from the trivial group to the whole one such that each quotient is cyclic of order dome prime. Read Lord's comment. But this is hardly used as a definition, which is usually way more general.
$endgroup$
– DonAntonio
Mar 30 at 8:26
$begingroup$
That is a very odd definition...What Dixon's Galois Theory? I've never heard of it and I googled it and didn't find anything...What I know is that a finite group is solvable iff it has a subnormal series from the trivial group to the whole one such that each quotient is cyclic of order dome prime. Read Lord's comment. But this is hardly used as a definition, which is usually way more general.
$endgroup$
– DonAntonio
Mar 30 at 8:26
$begingroup$
Welcome to Math.SE! Please use MathJax. For some basic information about writing math at this site see e.g. basic help on mathjax notation, mathjax tutorial and quick reference, main meta site math tutorial and equation editing how-to.
$endgroup$
– GNUSupporter 8964民主女神 地下教會
Mar 30 at 10:47
$begingroup$
Welcome to Math.SE! Please use MathJax. For some basic information about writing math at this site see e.g. basic help on mathjax notation, mathjax tutorial and quick reference, main meta site math tutorial and equation editing how-to.
$endgroup$
– GNUSupporter 8964民主女神 地下教會
Mar 30 at 10:47
|
show 4 more comments
1 Answer
1
active
oldest
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$begingroup$
Essentially, both definitions are equivalent (at least, for finite nontrivial groups)- clearly, if $N$ is a normal subgroup of $M$ such that $|M/N|$ is prime, then $M/N$ will be cyclic so that $M/N$ is abelian.
For the other direction:
First, we shall indulge an examination of maximal normal subgroups. A maximal normal subgroup (MNS) is defined here as some subgroup, $N$ of $G$, satisfying $Ntrianglelefteq G$, $Nneq G$, and for any $M$ such that $Ntrianglelefteq Mtrianglelefteq G$, either $M=N$ or $M=G$.
A conclusion that directly follows from this definition is that, in a finite group $G$ any normal subgroup $neq G$, $E$, is contained in some MNS. If this were not the case, we could find at least one $F_1$ such that $Etrianglelefteq F_1trianglelefteq G$ with $Eneq F_1$ and $F_1neq G$, as otherwise $E$ itself would be an MNS containing $E$. Now it must not be the case that $F_1$ is contained in an MNS as otherwise $E$ would be too, so we must have $F_1trianglelefteq F_2trianglelefteq G$ with $F_1neq F_2$ and $F_2neq G$. We can carry on concluding the existence of infinitely many normal subgroups $F_k$, each strictly between $F_k-1$ and $G$. But $G$ is finite and since each $F_ksupsetneq F_k-1$ we have for each $k$, $|F_k|>|F_k-1|$ which would mean that for some $rleq |G|-|E|$ we will have $F_r=G$. This contradiction leads us to conclude that each normal subgroup of some finite $G$ is contained in an MNS.
The next step is to note that if $f:Grightarrow H$ is a homomorphism and $Jtrianglelefteq H$, then $f^-1(J)trianglelefteq G$ (this is fairly straightforward). If $N$ is an MNS of $G$ and $G$ is nontrivial, consider the canonical homomorphism $f:Grightarrow G/N$- if $M$ is any proper normal subgroup of $G/N$, $f^-1(M)$ will be a proper normal subgroup of $G$ such that $f^-1(M)supsetneq N$ which is impossible. So if $N$ is an MNS of $G$, $G/N$ is simple. In particular, if $G/N$ is finite and abelian $G/N$ has no proper subgroups and must be of prime order.
Finally, let us turn our attention towards solvable groups. Let $G$ be a finite nontrivial solvable group- it has a solvable series with at least two members (namely, $e$ and $G$ itself). Let this series be $e=H_0subset H_1subset H_2subset...subset H_m-1subset H_m=G$ where for each $i$, $H_ineq H_i+1$. Consider for some arbitrary $0leq ileq m-1$, $H_i$ and $H_i+1$.
Since $H_itrianglelefteq H_i+1$ there is an MNS, $K_i,1$ of $H_i$ in $H_i+1$. Since $(H_i+1/H_i)/(K_i,1/H_i)cong H_i+1/K_i,1$ we have that $H_i+1/K_i,1$ is abelian- since $K_i,1$ is an MNS of $H_i+1$, $H_i+1/K_i,1$ is a group of prime order. And it is clear that $K_i,1/H_i$ is abelian as it is a subgroup of $H_i+1/H_i$. We then repeat this process generating $K_i,j+1$ as an MNS in $K_i,j$ containing $H_i$. This process terminates eventually as $|H_i|leq|K_i,j+1|<|K_i,j|$ for each $j$. We repeat this procedure till termination for each $i$ and so we have generated a "prime series" of $G$.
Edit to answer comment (because it was too long to be a comment): Well, suppose $K$ is a field extension of $F$ (a field of characteristic $0$) such that $Gal(K:F)$ is solvable. We know, then (by the above answer) that $Gal(K:F)$ has a sequence of subgroups, each a normal subgroup of the following term such that the order of each quotient is a prime. Suppose $H_i$ and $H_i+1$ are two adjacent subgroups in the "prime series". By the fundamental theorem of Galois theory, there exist fields between $F$ and $K$, $F_i$ and $F_i+1$ that correspond to $H_i$ and $H_i+1$ such that one is a field extension of prime degree over the other. The condition that $H_i$ be a normal subgroup of $H_i+1$ implies that $F_i$ is a splitting field over $F_i+1$. Those are all the facts one can extract rather immediately from the setup of the problem.
It turns out that under the right conditions on $F$, (i.e., $F$ having the 'right' roots of unity) any pair of extensions of $F$, $B$ and $C$, such that $[B:C]$ is prime and $B$ is a splitting field over $C$ immediately gives us that $B$ is a radical extension over $C$- this is the core of the proof. Now (again, by the fundamental theorem of Galois theory) each normal subgroup of $Gal(K:F)$ in its "prime series" corresponds to a splitting field between $F$ and $K$- in particular, $Gal(K:F)$ corresponds to $F$, the "smallest field" and the trivial group corresponds to $K$, the "largest field". Since each field is a radical/ root extension over a "smaller" field in the series of intermediate fields and $F$ corresponds to the smallest field and $K$ to the largest, $K$ is a radical extension over $F$ (as if $A$ is a radical extension over $B$ and $B$ is a radical extension over $C$, $A$ is a radical extension over $C$ as well).
So the core idea is to fill in the space between $K$ and $F$ with intermediate fields, $L_0,L_1,...,L_n$, such that $L_0=F$, $L_n=K$, and to use the conditions on $Gal(K:F)$ to show that each $L_i+1$ is a radical extension of $L_i$- this is enough to prove $K$ is a radical extension over $F$
(this is just the basic idea- I have obviously skimmed over many of the details and intricacies of the proof)
answered Mar 30 at 9:14
Cardioid_Ass_22Cardioid_Ass_22
47815
$endgroup$
$begingroup$
Thanks for you answer. However, as told above, I really loose the core reasoning of "abelian quotients" imply "roots with radical". I cannot see any book really touching the meat of that using a bit of intuition.
$endgroup$
– riccardoventrella
Mar 30 at 11:25
$begingroup$
@riccardoventrella I have tried to address your concerns in an edit to my answer. I hope that gives you a better understanding of the connection between solvable groups and radical extensions. If you want a more comprehensive explanation, I can send you a document that works through the all salient details of (a version of) the standard proof.
$endgroup$
– Cardioid_Ass_22
Mar 30 at 11:57
$begingroup$
Thanks, your answer now encompass the radical extensions quite well, I will look through it carefully, but starts having more sense. Thanks for your time and efforts.
$endgroup$
– riccardoventrella
Mar 30 at 13:31
add a comment |
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Essentially, both definitions are equivalent (at least, for finite nontrivial groups)- clearly, if $N$ is a normal subgroup of $M$ such that $|M/N|$ is prime, then $M/N$ will be cyclic so that $M/N$ is abelian.
For the other direction:
First, we shall indulge an examination of maximal normal subgroups. A maximal normal subgroup (MNS) is defined here as some subgroup, $N$ of $G$, satisfying $Ntrianglelefteq G$, $Nneq G$, and for any $M$ such that $Ntrianglelefteq Mtrianglelefteq G$, either $M=N$ or $M=G$.
A conclusion that directly follows from this definition is that, in a finite group $G$ any normal subgroup $neq G$, $E$, is contained in some MNS. If this were not the case, we could find at least one $F_1$ such that $Etrianglelefteq F_1trianglelefteq G$ with $Eneq F_1$ and $F_1neq G$, as otherwise $E$ itself would be an MNS containing $E$. Now it must not be the case that $F_1$ is contained in an MNS as otherwise $E$ would be too, so we must have $F_1trianglelefteq F_2trianglelefteq G$ with $F_1neq F_2$ and $F_2neq G$. We can carry on concluding the existence of infinitely many normal subgroups $F_k$, each strictly between $F_k-1$ and $G$. But $G$ is finite and since each $F_ksupsetneq F_k-1$ we have for each $k$, $|F_k|>|F_k-1|$ which would mean that for some $rleq |G|-|E|$ we will have $F_r=G$. This contradiction leads us to conclude that each normal subgroup of some finite $G$ is contained in an MNS.
The next step is to note that if $f:Grightarrow H$ is a homomorphism and $Jtrianglelefteq H$, then $f^-1(J)trianglelefteq G$ (this is fairly straightforward). If $N$ is an MNS of $G$ and $G$ is nontrivial, consider the canonical homomorphism $f:Grightarrow G/N$- if $M$ is any proper normal subgroup of $G/N$, $f^-1(M)$ will be a proper normal subgroup of $G$ such that $f^-1(M)supsetneq N$ which is impossible. So if $N$ is an MNS of $G$, $G/N$ is simple. In particular, if $G/N$ is finite and abelian $G/N$ has no proper subgroups and must be of prime order.
Finally, let us turn our attention towards solvable groups. Let $G$ be a finite nontrivial solvable group- it has a solvable series with at least two members (namely, $e$ and $G$ itself). Let this series be $e=H_0subset H_1subset H_2subset...subset H_m-1subset H_m=G$ where for each $i$, $H_ineq H_i+1$. Consider for some arbitrary $0leq ileq m-1$, $H_i$ and $H_i+1$.
Since $H_itrianglelefteq H_i+1$ there is an MNS, $K_i,1$ of $H_i$ in $H_i+1$. Since $(H_i+1/H_i)/(K_i,1/H_i)cong H_i+1/K_i,1$ we have that $H_i+1/K_i,1$ is abelian- since $K_i,1$ is an MNS of $H_i+1$, $H_i+1/K_i,1$ is a group of prime order. And it is clear that $K_i,1/H_i$ is abelian as it is a subgroup of $H_i+1/H_i$. We then repeat this process generating $K_i,j+1$ as an MNS in $K_i,j$ containing $H_i$. This process terminates eventually as $|H_i|leq|K_i,j+1|<|K_i,j|$ for each $j$. We repeat this procedure till termination for each $i$ and so we have generated a "prime series" of $G$.
Edit to answer comment (because it was too long to be a comment): Well, suppose $K$ is a field extension of $F$ (a field of characteristic $0$) such that $Gal(K:F)$ is solvable. We know, then (by the above answer) that $Gal(K:F)$ has a sequence of subgroups, each a normal subgroup of the following term such that the order of each quotient is a prime. Suppose $H_i$ and $H_i+1$ are two adjacent subgroups in the "prime series". By the fundamental theorem of Galois theory, there exist fields between $F$ and $K$, $F_i$ and $F_i+1$ that correspond to $H_i$ and $H_i+1$ such that one is a field extension of prime degree over the other. The condition that $H_i$ be a normal subgroup of $H_i+1$ implies that $F_i$ is a splitting field over $F_i+1$. Those are all the facts one can extract rather immediately from the setup of the problem.
It turns out that under the right conditions on $F$, (i.e., $F$ having the 'right' roots of unity) any pair of extensions of $F$, $B$ and $C$, such that $[B:C]$ is prime and $B$ is a splitting field over $C$ immediately gives us that $B$ is a radical extension over $C$- this is the core of the proof. Now (again, by the fundamental theorem of Galois theory) each normal subgroup of $Gal(K:F)$ in its "prime series" corresponds to a splitting field between $F$ and $K$- in particular, $Gal(K:F)$ corresponds to $F$, the "smallest field" and the trivial group corresponds to $K$, the "largest field". Since each field is a radical/ root extension over a "smaller" field in the series of intermediate fields and $F$ corresponds to the smallest field and $K$ to the largest, $K$ is a radical extension over $F$ (as if $A$ is a radical extension over $B$ and $B$ is a radical extension over $C$, $A$ is a radical extension over $C$ as well).
So the core idea is to fill in the space between $K$ and $F$ with intermediate fields, $L_0,L_1,...,L_n$, such that $L_0=F$, $L_n=K$, and to use the conditions on $Gal(K:F)$ to show that each $L_i+1$ is a radical extension of $L_i$- this is enough to prove $K$ is a radical extension over $F$
(this is just the basic idea- I have obviously skimmed over many of the details and intricacies of the proof)
answered Mar 30 at 9:14
Cardioid_Ass_22Cardioid_Ass_22
47815
$endgroup$
$begingroup$
Thanks for you answer. However, as told above, I really loose the core reasoning of "abelian quotients" imply "roots with radical". I cannot see any book really touching the meat of that using a bit of intuition.
$endgroup$
– riccardoventrella
Mar 30 at 11:25
$begingroup$
@riccardoventrella I have tried to address your concerns in an edit to my answer. I hope that gives you a better understanding of the connection between solvable groups and radical extensions. If you want a more comprehensive explanation, I can send you a document that works through the all salient details of (a version of) the standard proof.
$endgroup$
– Cardioid_Ass_22
Mar 30 at 11:57
$begingroup$
Thanks, your answer now encompass the radical extensions quite well, I will look through it carefully, but starts having more sense. Thanks for your time and efforts.
$endgroup$
– riccardoventrella
Mar 30 at 13:31
add a comment |
$begingroup$
Essentially, both definitions are equivalent (at least, for finite nontrivial groups)- clearly, if $N$ is a normal subgroup of $M$ such that $|M/N|$ is prime, then $M/N$ will be cyclic so that $M/N$ is abelian.
For the other direction:
First, we shall indulge an examination of maximal normal subgroups. A maximal normal subgroup (MNS) is defined here as some subgroup, $N$ of $G$, satisfying $Ntrianglelefteq G$, $Nneq G$, and for any $M$ such that $Ntrianglelefteq Mtrianglelefteq G$, either $M=N$ or $M=G$.
A conclusion that directly follows from this definition is that, in a finite group $G$ any normal subgroup $neq G$, $E$, is contained in some MNS. If this were not the case, we could find at least one $F_1$ such that $Etrianglelefteq F_1trianglelefteq G$ with $Eneq F_1$ and $F_1neq G$, as otherwise $E$ itself would be an MNS containing $E$. Now it must not be the case that $F_1$ is contained in an MNS as otherwise $E$ would be too, so we must have $F_1trianglelefteq F_2trianglelefteq G$ with $F_1neq F_2$ and $F_2neq G$. We can carry on concluding the existence of infinitely many normal subgroups $F_k$, each strictly between $F_k-1$ and $G$. But $G$ is finite and since each $F_ksupsetneq F_k-1$ we have for each $k$, $|F_k|>|F_k-1|$ which would mean that for some $rleq |G|-|E|$ we will have $F_r=G$. This contradiction leads us to conclude that each normal subgroup of some finite $G$ is contained in an MNS.
The next step is to note that if $f:Grightarrow H$ is a homomorphism and $Jtrianglelefteq H$, then $f^-1(J)trianglelefteq G$ (this is fairly straightforward). If $N$ is an MNS of $G$ and $G$ is nontrivial, consider the canonical homomorphism $f:Grightarrow G/N$- if $M$ is any proper normal subgroup of $G/N$, $f^-1(M)$ will be a proper normal subgroup of $G$ such that $f^-1(M)supsetneq N$ which is impossible. So if $N$ is an MNS of $G$, $G/N$ is simple. In particular, if $G/N$ is finite and abelian $G/N$ has no proper subgroups and must be of prime order.
Finally, let us turn our attention towards solvable groups. Let $G$ be a finite nontrivial solvable group- it has a solvable series with at least two members (namely, $e$ and $G$ itself). Let this series be $e=H_0subset H_1subset H_2subset...subset H_m-1subset H_m=G$ where for each $i$, $H_ineq H_i+1$. Consider for some arbitrary $0leq ileq m-1$, $H_i$ and $H_i+1$.
Since $H_itrianglelefteq H_i+1$ there is an MNS, $K_i,1$ of $H_i$ in $H_i+1$. Since $(H_i+1/H_i)/(K_i,1/H_i)cong H_i+1/K_i,1$ we have that $H_i+1/K_i,1$ is abelian- since $K_i,1$ is an MNS of $H_i+1$, $H_i+1/K_i,1$ is a group of prime order. And it is clear that $K_i,1/H_i$ is abelian as it is a subgroup of $H_i+1/H_i$. We then repeat this process generating $K_i,j+1$ as an MNS in $K_i,j$ containing $H_i$. This process terminates eventually as $|H_i|leq|K_i,j+1|<|K_i,j|$ for each $j$. We repeat this procedure till termination for each $i$ and so we have generated a "prime series" of $G$.
Edit to answer comment (because it was too long to be a comment): Well, suppose $K$ is a field extension of $F$ (a field of characteristic $0$) such that $Gal(K:F)$ is solvable. We know, then (by the above answer) that $Gal(K:F)$ has a sequence of subgroups, each a normal subgroup of the following term such that the order of each quotient is a prime. Suppose $H_i$ and $H_i+1$ are two adjacent subgroups in the "prime series". By the fundamental theorem of Galois theory, there exist fields between $F$ and $K$, $F_i$ and $F_i+1$ that correspond to $H_i$ and $H_i+1$ such that one is a field extension of prime degree over the other. The condition that $H_i$ be a normal subgroup of $H_i+1$ implies that $F_i$ is a splitting field over $F_i+1$. Those are all the facts one can extract rather immediately from the setup of the problem.
It turns out that under the right conditions on $F$, (i.e., $F$ having the 'right' roots of unity) any pair of extensions of $F$, $B$ and $C$, such that $[B:C]$ is prime and $B$ is a splitting field over $C$ immediately gives us that $B$ is a radical extension over $C$- this is the core of the proof. Now (again, by the fundamental theorem of Galois theory) each normal subgroup of $Gal(K:F)$ in its "prime series" corresponds to a splitting field between $F$ and $K$- in particular, $Gal(K:F)$ corresponds to $F$, the "smallest field" and the trivial group corresponds to $K$, the "largest field". Since each field is a radical/ root extension over a "smaller" field in the series of intermediate fields and $F$ corresponds to the smallest field and $K$ to the largest, $K$ is a radical extension over $F$ (as if $A$ is a radical extension over $B$ and $B$ is a radical extension over $C$, $A$ is a radical extension over $C$ as well).
So the core idea is to fill in the space between $K$ and $F$ with intermediate fields, $L_0,L_1,...,L_n$, such that $L_0=F$, $L_n=K$, and to use the conditions on $Gal(K:F)$ to show that each $L_i+1$ is a radical extension of $L_i$- this is enough to prove $K$ is a radical extension over $F$
(this is just the basic idea- I have obviously skimmed over many of the details and intricacies of the proof)
answered Mar 30 at 9:14
Cardioid_Ass_22Cardioid_Ass_22
47815
$endgroup$
$begingroup$
Thanks for you answer. However, as told above, I really loose the core reasoning of "abelian quotients" imply "roots with radical". I cannot see any book really touching the meat of that using a bit of intuition.
$endgroup$
– riccardoventrella
Mar 30 at 11:25
$begingroup$
@riccardoventrella I have tried to address your concerns in an edit to my answer. I hope that gives you a better understanding of the connection between solvable groups and radical extensions. If you want a more comprehensive explanation, I can send you a document that works through the all salient details of (a version of) the standard proof.
$endgroup$
– Cardioid_Ass_22
Mar 30 at 11:57
$begingroup$
Thanks, your answer now encompass the radical extensions quite well, I will look through it carefully, but starts having more sense. Thanks for your time and efforts.
$endgroup$
– riccardoventrella
Mar 30 at 13:31
add a comment |
$begingroup$
Essentially, both definitions are equivalent (at least, for finite nontrivial groups)- clearly, if $N$ is a normal subgroup of $M$ such that $|M/N|$ is prime, then $M/N$ will be cyclic so that $M/N$ is abelian.
For the other direction:
First, we shall indulge an examination of maximal normal subgroups. A maximal normal subgroup (MNS) is defined here as some subgroup, $N$ of $G$, satisfying $Ntrianglelefteq G$, $Nneq G$, and for any $M$ such that $Ntrianglelefteq Mtrianglelefteq G$, either $M=N$ or $M=G$.
A conclusion that directly follows from this definition is that, in a finite group $G$ any normal subgroup $neq G$, $E$, is contained in some MNS. If this were not the case, we could find at least one $F_1$ such that $Etrianglelefteq F_1trianglelefteq G$ with $Eneq F_1$ and $F_1neq G$, as otherwise $E$ itself would be an MNS containing $E$. Now it must not be the case that $F_1$ is contained in an MNS as otherwise $E$ would be too, so we must have $F_1trianglelefteq F_2trianglelefteq G$ with $F_1neq F_2$ and $F_2neq G$. We can carry on concluding the existence of infinitely many normal subgroups $F_k$, each strictly between $F_k-1$ and $G$. But $G$ is finite and since each $F_ksupsetneq F_k-1$ we have for each $k$, $|F_k|>|F_k-1|$ which would mean that for some $rleq |G|-|E|$ we will have $F_r=G$. This contradiction leads us to conclude that each normal subgroup of some finite $G$ is contained in an MNS.
The next step is to note that if $f:Grightarrow H$ is a homomorphism and $Jtrianglelefteq H$, then $f^-1(J)trianglelefteq G$ (this is fairly straightforward). If $N$ is an MNS of $G$ and $G$ is nontrivial, consider the canonical homomorphism $f:Grightarrow G/N$- if $M$ is any proper normal subgroup of $G/N$, $f^-1(M)$ will be a proper normal subgroup of $G$ such that $f^-1(M)supsetneq N$ which is impossible. So if $N$ is an MNS of $G$, $G/N$ is simple. In particular, if $G/N$ is finite and abelian $G/N$ has no proper subgroups and must be of prime order.
Finally, let us turn our attention towards solvable groups. Let $G$ be a finite nontrivial solvable group- it has a solvable series with at least two members (namely, $e$ and $G$ itself). Let this series be $e=H_0subset H_1subset H_2subset...subset H_m-1subset H_m=G$ where for each $i$, $H_ineq H_i+1$. Consider for some arbitrary $0leq ileq m-1$, $H_i$ and $H_i+1$.
Since $H_itrianglelefteq H_i+1$ there is an MNS, $K_i,1$ of $H_i$ in $H_i+1$. Since $(H_i+1/H_i)/(K_i,1/H_i)cong H_i+1/K_i,1$ we have that $H_i+1/K_i,1$ is abelian- since $K_i,1$ is an MNS of $H_i+1$, $H_i+1/K_i,1$ is a group of prime order. And it is clear that $K_i,1/H_i$ is abelian as it is a subgroup of $H_i+1/H_i$. We then repeat this process generating $K_i,j+1$ as an MNS in $K_i,j$ containing $H_i$. This process terminates eventually as $|H_i|leq|K_i,j+1|<|K_i,j|$ for each $j$. We repeat this procedure till termination for each $i$ and so we have generated a "prime series" of $G$.
Edit to answer comment (because it was too long to be a comment): Well, suppose $K$ is a field extension of $F$ (a field of characteristic $0$) such that $Gal(K:F)$ is solvable. We know, then (by the above answer) that $Gal(K:F)$ has a sequence of subgroups, each a normal subgroup of the following term such that the order of each quotient is a prime. Suppose $H_i$ and $H_i+1$ are two adjacent subgroups in the "prime series". By the fundamental theorem of Galois theory, there exist fields between $F$ and $K$, $F_i$ and $F_i+1$ that correspond to $H_i$ and $H_i+1$ such that one is a field extension of prime degree over the other. The condition that $H_i$ be a normal subgroup of $H_i+1$ implies that $F_i$ is a splitting field over $F_i+1$. Those are all the facts one can extract rather immediately from the setup of the problem.
It turns out that under the right conditions on $F$, (i.e., $F$ having the 'right' roots of unity) any pair of extensions of $F$, $B$ and $C$, such that $[B:C]$ is prime and $B$ is a splitting field over $C$ immediately gives us that $B$ is a radical extension over $C$- this is the core of the proof. Now (again, by the fundamental theorem of Galois theory) each normal subgroup of $Gal(K:F)$ in its "prime series" corresponds to a splitting field between $F$ and $K$- in particular, $Gal(K:F)$ corresponds to $F$, the "smallest field" and the trivial group corresponds to $K$, the "largest field". Since each field is a radical/ root extension over a "smaller" field in the series of intermediate fields and $F$ corresponds to the smallest field and $K$ to the largest, $K$ is a radical extension over $F$ (as if $A$ is a radical extension over $B$ and $B$ is a radical extension over $C$, $A$ is a radical extension over $C$ as well).
So the core idea is to fill in the space between $K$ and $F$ with intermediate fields, $L_0,L_1,...,L_n$, such that $L_0=F$, $L_n=K$, and to use the conditions on $Gal(K:F)$ to show that each $L_i+1$ is a radical extension of $L_i$- this is enough to prove $K$ is a radical extension over $F$
(this is just the basic idea- I have obviously skimmed over many of the details and intricacies of the proof)
answered Mar 30 at 9:14
Cardioid_Ass_22Cardioid_Ass_22
47815
$endgroup$
Essentially, both definitions are equivalent (at least, for finite nontrivial groups)- clearly, if $N$ is a normal subgroup of $M$ such that $|M/N|$ is prime, then $M/N$ will be cyclic so that $M/N$ is abelian.
For the other direction:
First, we shall indulge an examination of maximal normal subgroups. A maximal normal subgroup (MNS) is defined here as some subgroup, $N$ of $G$, satisfying $Ntrianglelefteq G$, $Nneq G$, and for any $M$ such that $Ntrianglelefteq Mtrianglelefteq G$, either $M=N$ or $M=G$.
A conclusion that directly follows from this definition is that, in a finite group $G$ any normal subgroup $neq G$, $E$, is contained in some MNS. If this were not the case, we could find at least one $F_1$ such that $Etrianglelefteq F_1trianglelefteq G$ with $Eneq F_1$ and $F_1neq G$, as otherwise $E$ itself would be an MNS containing $E$. Now it must not be the case that $F_1$ is contained in an MNS as otherwise $E$ would be too, so we must have $F_1trianglelefteq F_2trianglelefteq G$ with $F_1neq F_2$ and $F_2neq G$. We can carry on concluding the existence of infinitely many normal subgroups $F_k$, each strictly between $F_k-1$ and $G$. But $G$ is finite and since each $F_ksupsetneq F_k-1$ we have for each $k$, $|F_k|>|F_k-1|$ which would mean that for some $rleq |G|-|E|$ we will have $F_r=G$. This contradiction leads us to conclude that each normal subgroup of some finite $G$ is contained in an MNS.
The next step is to note that if $f:Grightarrow H$ is a homomorphism and $Jtrianglelefteq H$, then $f^-1(J)trianglelefteq G$ (this is fairly straightforward). If $N$ is an MNS of $G$ and $G$ is nontrivial, consider the canonical homomorphism $f:Grightarrow G/N$- if $M$ is any proper normal subgroup of $G/N$, $f^-1(M)$ will be a proper normal subgroup of $G$ such that $f^-1(M)supsetneq N$ which is impossible. So if $N$ is an MNS of $G$, $G/N$ is simple. In particular, if $G/N$ is finite and abelian $G/N$ has no proper subgroups and must be of prime order.
Finally, let us turn our attention towards solvable groups. Let $G$ be a finite nontrivial solvable group- it has a solvable series with at least two members (namely, $e$ and $G$ itself). Let this series be $e=H_0subset H_1subset H_2subset...subset H_m-1subset H_m=G$ where for each $i$, $H_ineq H_i+1$. Consider for some arbitrary $0leq ileq m-1$, $H_i$ and $H_i+1$.
Since $H_itrianglelefteq H_i+1$ there is an MNS, $K_i,1$ of $H_i$ in $H_i+1$. Since $(H_i+1/H_i)/(K_i,1/H_i)cong H_i+1/K_i,1$ we have that $H_i+1/K_i,1$ is abelian- since $K_i,1$ is an MNS of $H_i+1$, $H_i+1/K_i,1$ is a group of prime order. And it is clear that $K_i,1/H_i$ is abelian as it is a subgroup of $H_i+1/H_i$. We then repeat this process generating $K_i,j+1$ as an MNS in $K_i,j$ containing $H_i$. This process terminates eventually as $|H_i|leq|K_i,j+1|<|K_i,j|$ for each $j$. We repeat this procedure till termination for each $i$ and so we have generated a "prime series" of $G$.
Edit to answer comment (because it was too long to be a comment): Well, suppose $K$ is a field extension of $F$ (a field of characteristic $0$) such that $Gal(K:F)$ is solvable. We know, then (by the above answer) that $Gal(K:F)$ has a sequence of subgroups, each a normal subgroup of the following term such that the order of each quotient is a prime. Suppose $H_i$ and $H_i+1$ are two adjacent subgroups in the "prime series". By the fundamental theorem of Galois theory, there exist fields between $F$ and $K$, $F_i$ and $F_i+1$ that correspond to $H_i$ and $H_i+1$ such that one is a field extension of prime degree over the other. The condition that $H_i$ be a normal subgroup of $H_i+1$ implies that $F_i$ is a splitting field over $F_i+1$. Those are all the facts one can extract rather immediately from the setup of the problem.
It turns out that under the right conditions on $F$, (i.e., $F$ having the 'right' roots of unity) any pair of extensions of $F$, $B$ and $C$, such that $[B:C]$ is prime and $B$ is a splitting field over $C$ immediately gives us that $B$ is a radical extension over $C$- this is the core of the proof. Now (again, by the fundamental theorem of Galois theory) each normal subgroup of $Gal(K:F)$ in its "prime series" corresponds to a splitting field between $F$ and $K$- in particular, $Gal(K:F)$ corresponds to $F$, the "smallest field" and the trivial group corresponds to $K$, the "largest field". Since each field is a radical/ root extension over a "smaller" field in the series of intermediate fields and $F$ corresponds to the smallest field and $K$ to the largest, $K$ is a radical extension over $F$ (as if $A$ is a radical extension over $B$ and $B$ is a radical extension over $C$, $A$ is a radical extension over $C$ as well).
So the core idea is to fill in the space between $K$ and $F$ with intermediate fields, $L_0,L_1,...,L_n$, such that $L_0=F$, $L_n=K$, and to use the conditions on $Gal(K:F)$ to show that each $L_i+1$ is a radical extension of $L_i$- this is enough to prove $K$ is a radical extension over $F$
(this is just the basic idea- I have obviously skimmed over many of the details and intricacies of the proof)
answered Mar 30 at 9:14
Cardioid_Ass_22Cardioid_Ass_22
47815
edited Mar 30 at 12:00
answered Mar 30 at 9:14
Cardioid_Ass_22Cardioid_Ass_22
47815
answered Mar 30 at 9:14
Cardioid_Ass_22Cardioid_Ass_22
47815
answered Mar 30 at 9:14
Cardioid_Ass_22Cardioid_Ass_22
47815
47815
$begingroup$
Thanks for you answer. However, as told above, I really loose the core reasoning of "abelian quotients" imply "roots with radical". I cannot see any book really touching the meat of that using a bit of intuition.
$endgroup$
– riccardoventrella
Mar 30 at 11:25
$begingroup$
@riccardoventrella I have tried to address your concerns in an edit to my answer. I hope that gives you a better understanding of the connection between solvable groups and radical extensions. If you want a more comprehensive explanation, I can send you a document that works through the all salient details of (a version of) the standard proof.
$endgroup$
– Cardioid_Ass_22
Mar 30 at 11:57
$begingroup$
Thanks, your answer now encompass the radical extensions quite well, I will look through it carefully, but starts having more sense. Thanks for your time and efforts.
$endgroup$
– riccardoventrella
Mar 30 at 13:31
add a comment |
$begingroup$
Thanks for you answer. However, as told above, I really loose the core reasoning of "abelian quotients" imply "roots with radical". I cannot see any book really touching the meat of that using a bit of intuition.
$endgroup$
– riccardoventrella
Mar 30 at 11:25
$begingroup$
@riccardoventrella I have tried to address your concerns in an edit to my answer. I hope that gives you a better understanding of the connection between solvable groups and radical extensions. If you want a more comprehensive explanation, I can send you a document that works through the all salient details of (a version of) the standard proof.
$endgroup$
– Cardioid_Ass_22
Mar 30 at 11:57
$begingroup$
Thanks, your answer now encompass the radical extensions quite well, I will look through it carefully, but starts having more sense. Thanks for your time and efforts.
$endgroup$
– riccardoventrella
Mar 30 at 13:31
$begingroup$
Thanks for you answer. However, as told above, I really loose the core reasoning of "abelian quotients" imply "roots with radical". I cannot see any book really touching the meat of that using a bit of intuition.
$endgroup$
– riccardoventrella
Mar 30 at 11:25
$begingroup$
Thanks for you answer. However, as told above, I really loose the core reasoning of "abelian quotients" imply "roots with radical". I cannot see any book really touching the meat of that using a bit of intuition.
$endgroup$
– riccardoventrella
Mar 30 at 11:25
$begingroup$
@riccardoventrella I have tried to address your concerns in an edit to my answer. I hope that gives you a better understanding of the connection between solvable groups and radical extensions. If you want a more comprehensive explanation, I can send you a document that works through the all salient details of (a version of) the standard proof.
$endgroup$
– Cardioid_Ass_22
Mar 30 at 11:57
$begingroup$
@riccardoventrella I have tried to address your concerns in an edit to my answer. I hope that gives you a better understanding of the connection between solvable groups and radical extensions. If you want a more comprehensive explanation, I can send you a document that works through the all salient details of (a version of) the standard proof.
$endgroup$
– Cardioid_Ass_22
Mar 30 at 11:57
$begingroup$
Thanks, your answer now encompass the radical extensions quite well, I will look through it carefully, but starts having more sense. Thanks for your time and efforts.
$endgroup$
– riccardoventrella
Mar 30 at 13:31
$begingroup$
Thanks, your answer now encompass the radical extensions quite well, I will look through it carefully, but starts having more sense. Thanks for your time and efforts.
$endgroup$
– riccardoventrella
Mar 30 at 13:31
add a comment |
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One can refine a chain with finite Abelian quotients to a chain with finite prime order quotients, since each finite non-trivial Abelian group has a quotient of prime index.
$endgroup$
– Lord Shark the Unknown
Mar 30 at 8:19
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Thank LordShark, may you do an example please? For example, the Klein four group is solvable and the index of e in it is 4. So it's not prime, as far as I can see. Where am I wrong?
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– riccardoventrella
Mar 30 at 8:21
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$V_4$ has a subgroup of order $2$, necessarily normal.
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– Lord Shark the Unknown
Mar 30 at 8:23
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That is a very odd definition...What Dixon's Galois Theory? I've never heard of it and I googled it and didn't find anything...What I know is that a finite group is solvable iff it has a subnormal series from the trivial group to the whole one such that each quotient is cyclic of order dome prime. Read Lord's comment. But this is hardly used as a definition, which is usually way more general.
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– DonAntonio
Mar 30 at 8:26
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Welcome to Math.SE! Please use MathJax. For some basic information about writing math at this site see e.g. basic help on mathjax notation, mathjax tutorial and quick reference, main meta site math tutorial and equation editing how-to.
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– GNUSupporter 8964民主女神 地下教會
Mar 30 at 10:47