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In the mathematical field of group theory, an Artin transfer is a certain homomorphism from a group to the commutator quotient group of a subgroup of finite index. Originally, such mappings arose as group theoretic counterparts of class extension homomorphisms of abelian extensions of algebraic number fields by applying Artin's reciprocity maps to ideal class groups and analyzing the resulting homomorphisms between quotients of Galois groups. However, independently of number theoretic applications, the kernels and targets of Artin transfers have recently turned out to be compatible with parent-descendant relations between finite p-groups, which can be visualized in descendant trees. Therefore, Artin transfers provide a valuable tool for the classification of finite p-groups and for searching particular groups in descendant trees by looking for patterns defined by the kernels and targets of Artin transfers. These methods of pattern recognition are useful in purely group theoretic context, as well as for applications in algebraic number theory.

Transversals of a subgroup

Let ${\displaystyle G}$  be a group and ${\displaystyle H<G}$  be a subgroup of finite index ${\displaystyle n=(G:H)}$ .

Definitions. ^[1]

• A left transversal of ${\displaystyle H}$  in ${\displaystyle G}$  is an ordered system ${\displaystyle (g_{1},\ldots ,g_{n})}$  of representatives for the left cosets of ${\displaystyle H}$  in ${\displaystyle G}$  such that ${\displaystyle G={\dot {\cup }}_{i=1}^{n}\,g_{i}H}$  is a disjoint union.
• Similarly, a right transversal of ${\displaystyle H}$  in ${\displaystyle G}$  is an ordered system ${\displaystyle (d_{1},\ldots ,d_{n})}$  of representatives for the right cosets of ${\displaystyle H}$  in ${\displaystyle G}$  such that ${\displaystyle G={\dot {\cup }}_{i=1}^{n}\,Hd_{i}}$  is a disjoint union.

Remarks.

• For any transversal of ${\displaystyle H}$  in ${\displaystyle G}$ , there exists a unique subscript ${\displaystyle 1\leq i_{0}\leq n}$  such that ${\displaystyle g_{i_{0}}\in H}$ , resp. ${\displaystyle d_{i_{0}}\in H}$ . Of course, this element may be, but need not be, replaced by the neutral element ${\displaystyle 1}$ .
• If ${\displaystyle G}$  is non-abelian and ${\displaystyle H}$  is not a normal subgroup of ${\displaystyle G}$ , then we can only say that the inverse elements ${\displaystyle (g_{1}^{-1},\ldots ,g_{n}^{-1})}$  of a left transversal ${\displaystyle (g_{1},\ldots ,g_{n})}$  form a right transversal of ${\displaystyle H}$  in ${\displaystyle G}$ , since ${\displaystyle G={\dot {\cup }}_{i=1}^{n}\,g_{i}H}$  implies ${\displaystyle G=G^{-1}={\dot {\cup }}_{i=1}^{n}\,(g_{i}H)^{-1}={\dot {\cup }}_{i=1}^{n}\,H^{-1}g_{i}^{-1}={\dot {\cup }}_{i=1}^{n}\,Hg_{i}^{-1}}$ .
• However, if ${\displaystyle H\triangleleft G}$  is a normal subgroup of ${\displaystyle G}$ , then any left transversal is also a right transversal of ${\displaystyle H}$  in ${\displaystyle G}$ , since ${\displaystyle xH=Hx}$  for each ${\displaystyle x\in G}$ .

Permutation representation

Suppose ${\displaystyle (g_{1},\ldots ,g_{n})}$  is a left transversal of a subgroup ${\displaystyle H<G}$  of finite index ${\displaystyle n=(G:H)}$  in a group ${\displaystyle G}$ . A fixed element ${\displaystyle x\in G}$  gives rise to a unique permutation ${\displaystyle \pi _{x}\in S_{n}}$  of the left cosets of ${\displaystyle H}$  in ${\displaystyle G}$  such that ${\displaystyle xg_{i}\in g_{\pi _{x}(i)}H}$ , resp. ${\displaystyle h_{x}(i):=g_{\pi _{x}(i)}^{-1}xg_{i}\in H}$ , for each ${\displaystyle 1\leq i\leq n}$ .

Similarly, if ${\displaystyle (d_{1},\ldots ,d_{n})}$  is a right transversal of ${\displaystyle H}$  in ${\displaystyle G}$ , then a fixed element ${\displaystyle x\in G}$  gives rise to a unique permutation ${\displaystyle \rho _{x}\in S_{n}}$  of the right cosets of ${\displaystyle H}$  in ${\displaystyle G}$  such that ${\displaystyle d_{i}x\in Hd_{\rho _{x}(i)}}$ , resp. ${\displaystyle \eta _{x}(i):=d_{i}xd_{\rho _{x}(i)}^{-1}\in H}$ , for each ${\displaystyle 1\leq i\leq n}$ .

Definition. ^[1]

The mapping ${\displaystyle G\to S_{n},\ x\mapsto \pi _{x}}$ , resp. ${\displaystyle G\to S_{n},\ x\mapsto \rho _{x}}$ , is called the permutation representation of ${\displaystyle G}$  in ${\displaystyle S_{n}}$  with respect to ${\displaystyle (g_{1},\ldots ,g_{n})}$ , resp. ${\displaystyle (d_{1},\ldots ,d_{n})}$ .

Remark.

For the special right transversal ${\displaystyle (g_{1}^{-1},\ldots ,g_{n}^{-1})}$  associated to the left transversal ${\displaystyle (g_{1},\ldots ,g_{n})}$  we have ${\displaystyle \eta _{x}(i)=g_{i}^{-1}xg_{\rho _{x}(i)}}$  but on the other hand ${\displaystyle h_{x}(i)^{-1}=(g_{\pi _{x}(i)}^{-1}xg_{i})^{-1}=g_{i}^{-1}x^{-1}g_{\pi _{x}(i)}=g_{i}^{-1}x^{-1}g_{\rho _{x^{-1}}(i)}=\eta _{x^{-1}}(i)}$ , for each ${\displaystyle 1\leq i\leq n}$ . This relation simultaneously shows that, for any ${\displaystyle x\in G}$ , the permutation representations are connected by ${\displaystyle \rho _{x^{-1}}=\pi _{x}}$  and ${\displaystyle \eta _{x^{-1}}(i)=h_{x}(i)^{-1}}$ , for each ${\displaystyle 1\leq i\leq n}$ .

Artin transfer

Let ${\displaystyle G}$  be a group and ${\displaystyle H<G}$  be a subgroup of finite index ${\displaystyle n=(G:H)}$ . Assume that ${\displaystyle (g_{1},\ldots ,g_{n})}$ , resp. ${\displaystyle (d_{1},\ldots ,d_{n})}$ , is a left, resp. right, transversal of ${\displaystyle H}$  in ${\displaystyle G}$ .

Definition. ^[2]

Then the Artin transfer ${\displaystyle T_{G,H}:\ G\to H/H^{\prime }}$  from ${\displaystyle G}$  to the abelianization of ${\displaystyle H}$  with respect to ${\displaystyle (g_{1},\ldots ,g_{n})}$ , resp. ${\displaystyle (d_{1},\ldots ,d_{n})}$ , is defined by ${\displaystyle T_{G,H}^{(g)}(x):=\prod _{i=1}^{n}\,g_{\pi _{x}(i)}^{-1}xg_{i}\cdot H^{\prime }}$  or briefly ${\displaystyle T_{G,H}(x)=\prod _{i=1}^{n}\,h_{x}(i)\cdot H^{\prime }}$ , resp. ${\displaystyle T_{G,H}^{(d)}(x):=\prod _{i=1}^{n}\,d_{i}xd_{\rho _{x}(i)}^{-1}\cdot H^{\prime }}$  or briefly ${\displaystyle T_{G,H}(x)=\prod _{i=1}^{n}\,\eta _{x}(i)\cdot H^{\prime }}$ , for ${\displaystyle x\in G}$ .

Independence of the transversal

Assume that ${\displaystyle (\gamma _{1},\ldots ,\gamma _{n})}$  is another left transversal of ${\displaystyle H}$  in ${\displaystyle G}$  such that ${\displaystyle G={\dot {\cup }}_{i=1}^{n}\,\gamma _{i}H}$ . Then there exists a unique permutation ${\displaystyle \sigma \in S_{n}}$  such that ${\displaystyle g_{i}H=\gamma _{\sigma (i)}H}$ , for all ${\displaystyle 1\leq i\leq n}$ . Consequently, ${\displaystyle g_{i}^{-1}\gamma _{\sigma (i)}\in H}$ , resp. ${\displaystyle \gamma _{\sigma (i)}=g_{i}h_{i}}$  with ${\displaystyle h_{i}\in H}$ , for all ${\displaystyle 1\leq i\leq n}$ . For a fixed element ${\displaystyle x\in G}$ , there exists a unique permutation ${\displaystyle \lambda _{x}\in S_{n}}$  such that we have ${\displaystyle \gamma _{\lambda _{x}(\sigma (i))}H=x\gamma _{\sigma (i)}H=xg_{i}h_{i}H=xg_{i}H=g_{\pi _{x}(i)}H=g_{\pi _{x}(i)}h_{\pi _{x}(i)}H=\gamma _{\sigma (\pi _{x}(i))}H}$ , for all ${\displaystyle 1\leq i\leq n}$ . Therefore, the permutation representation of ${\displaystyle G}$  with respect to ${\displaystyle (\gamma _{1},\ldots ,\gamma _{n})}$  is given by ${\displaystyle \lambda _{x}=\sigma \circ \pi _{x}\circ \sigma ^{-1}\in S_{n}}$ , for ${\displaystyle x\in G}$ . Furthermore, for the connection between the elements ${\displaystyle k_{x}(i):=\gamma _{\lambda _{x}(i)}^{-1}x\gamma _{i}\in H}$  and ${\displaystyle h_{x}(i)=g_{\pi _{x}(i)}^{-1}xg_{i}\in H}$ , we obtain ${\displaystyle k_{x}(\sigma (i))=\gamma _{\lambda _{x}(\sigma (i))}^{-1}x\gamma _{\sigma (i)}=\gamma _{\sigma (\pi _{x}(i))}^{-1}xg_{i}h_{i}(g_{\pi _{x}(i)}h_{\pi _{x}(i)})^{-1}xg_{i}h_{i}=h_{\pi _{x}(i)}^{-1}g_{\pi _{x}(i)}^{-1}xg_{i}h_{i}=h_{\pi _{x}(i)}^{-1}h_{x}(i)h_{i}}$ , for all ${\displaystyle 1\leq i\leq n}$ . Finally, due to the commutativity of the quotient group ${\displaystyle H/H^{\prime }}$  and the fact that ${\displaystyle \sigma ,\pi _{x}}$  are permutations, the Artin transfer turns out to be independent of the left transversal: ${\displaystyle T_{G,H}^{(\gamma )}(x)=\prod _{i=1}^{n}\,k_{x}(\sigma (i))\cdot H^{\prime }=\prod _{i=1}^{n}\,h_{\pi _{x}(i)}^{-1}h_{x}(i)h_{i}\cdot H^{\prime }}$  ${\displaystyle =\prod _{i=1}^{n}\,h_{x}(i)\prod _{i=1}^{n}\,h_{\pi _{x}(i)}^{-1}\prod _{i=1}^{n}\,h_{i}\cdot H^{\prime }=\prod _{i=1}^{n}\,h_{x}(i)\cdot 1\cdot H^{\prime }=\prod _{i=1}^{n}\,h_{x}(i)\cdot H^{\prime }=T_{G,H}^{(g)}(x)}$ , as defined above.

It remains to show that the Artin transfer with respect to a right transversal coincides with the Artin transfer with respect to a left transversal. For this purpose, we select the special right transversal ${\displaystyle (g_{1}^{-1},\ldots ,g_{n}^{-1})}$  associated to the left transversal ${\displaystyle (g_{1},\ldots ,g_{n})}$ . Using the commutativity of ${\displaystyle H/H^{\prime }}$ , we consider the expression ${\displaystyle T_{G,H}^{(g^{-1})}(x)=\prod _{i=1}^{n}\,g_{i}^{-1}xg_{\rho _{x}(i)}\cdot H^{\prime }=\prod _{i=1}^{n}\,\eta _{x}(i)\cdot H^{\prime }=\prod _{i=1}^{n}\,h_{x^{-1}}(i)^{-1}\cdot H^{\prime }=(\prod _{i=1}^{n}\,h_{x^{-1}}(i)\cdot H^{\prime })^{-1}}$  ${\displaystyle =(T_{G,H}^{(g)}(x^{-1}))^{-1}=T_{G,H}^{(g)}(x)}$ . The last step is justified by the fact that the Artin transfer is a homomorphism. This will be shown in the following section.

Homomorphisms

Let ${\displaystyle x,y\in G}$  be two elements with transfer images ${\displaystyle T_{G,H}(x)=\prod _{i=1}^{n}\,g_{\pi _{x}(i)}^{-1}xg_{i}\cdot H^{\prime }}$  and ${\displaystyle T_{G,H}(y)=\prod _{j=1}^{n}\,g_{\pi _{y}(j)}^{-1}yg_{j}\cdot H^{\prime }}$ . Since ${\displaystyle H/H^{\prime }}$  is abelian and ${\displaystyle \pi _{y}}$  is a permutation, we can change the order of the factors in the following product: ${\displaystyle T_{G,H}(x)\cdot T_{G,H}(y)=\prod _{i=1}^{n}\,g_{\pi _{x}(i)}^{-1}xg_{i}H^{\prime }\cdot \prod _{j=1}^{n}\,g_{\pi _{y}(j)}^{-1}yg_{j}\cdot H^{\prime }=\prod _{j=1}^{n}\,g_{\pi _{x}(\pi _{y}(j))}^{-1}xg_{\pi _{y}(j)}H^{\prime }\cdot \prod _{j=1}^{n}\,g_{\pi _{y}(j)}^{-1}yg_{j}\cdot H^{\prime }}$  ${\displaystyle =\prod _{j=1}^{n}\,g_{\pi _{x}(\pi _{y}(j))}^{-1}xg_{\pi _{y}(j)}g_{\pi _{y}(j)}^{-1}yg_{j}\cdot H^{\prime }=\prod _{j=1}^{n}\,g_{(\pi _{x}\circ \pi _{y})(j))}^{-1}xyg_{j}\cdot H^{\prime }=T_{G,H}(xy)}$ . This relation simultaneously shows that the Artin transfer ${\displaystyle T_{G,H}}$  and the permutation representation ${\displaystyle G\to S_{n},\ x\mapsto \pi _{x}}$  are homomorphisms, since ${\displaystyle \pi _{xy}=\pi _{x}\circ \pi _{y}}$ .

Composition

Let ${\displaystyle G}$  be a group with nested subgroups ${\displaystyle K\leq H\leq G}$  such that the index ${\displaystyle (G:K)=(G:H)\cdot (H:K)=n\cdot m}$  is finite. Then the Artin transfer ${\displaystyle T_{G,K}}$  is the compositum of the induced transfer ${\displaystyle {\tilde {T}}_{H,K}:\ H/H^{\prime }\to K/K^{\prime }}$ and the Artin transfer ${\displaystyle T_{G,H}}$ , that is, ${\displaystyle T_{G,K}={\tilde {T}}_{H,K}\circ T_{G,H}}$ . This can be seen in the following manner.

If ${\displaystyle (g_{1},\ldots ,g_{n})}$  is a left transversal of ${\displaystyle H}$  in ${\displaystyle G}$  and ${\displaystyle (h_{1},\ldots ,h_{m})}$  is a left transversal of ${\displaystyle K}$  in ${\displaystyle H}$ , that is ${\displaystyle G={\dot {\cup }}_{i=1}^{n}\,g_{i}H}$  and ${\displaystyle H={\dot {\cup }}_{j=1}^{m}\,h_{j}K}$ , then ${\displaystyle G={\dot {\cup }}_{i=1}^{n}\,{\dot {\cup }}_{j=1}^{m}\,g_{i}h_{j}K}$  is a disjoint left coset decomposition of ${\displaystyle G}$  with respect to ${\displaystyle K}$ . Given two elements ${\displaystyle x\in G}$  and ${\displaystyle y\in H}$ , there exist unique permutations ${\displaystyle \pi _{x}\in S_{n}}$ , and ${\displaystyle \sigma _{y}\in S_{m}}$ , such that ${\displaystyle h_{x}(i):=g_{\pi _{x}(i)}^{-1}xg_{i}\in H}$ , for each ${\displaystyle 1\leq i\leq n}$ , and ${\displaystyle k_{y}(j):=h_{\sigma _{y}(j)}^{-1}yh_{j}\in K}$ , for each ${\displaystyle 1\leq j\leq m}$ . Then ${\displaystyle T_{G,H}(x)=\prod _{i=1}^{n}\,h_{x}(i)\cdot H^{\prime }}$ , and ${\displaystyle {\tilde {T}}_{H,K}(y\cdot H^{\prime })=T_{H,K}(y)=\prod _{j=1}^{m}\,k_{y}(j)\cdot K^{\prime }}$ . For each pair of subscripts ${\displaystyle 1\leq i\leq n}$  and ${\displaystyle 1\leq j\leq m}$ , we have ${\displaystyle xg_{i}h_{j}=g_{\pi _{x}(i)}g_{\pi _{x}(i)}^{-1}xg_{i}h_{j}=g_{\pi _{x}(i)}h_{x}(i)h_{j}=g_{\pi _{x}(i)}h_{\sigma _{y_{i}}(j)}k_{y_{i}}(j)}$ , resp. ${\displaystyle h_{\sigma _{y_{i}}(j)}^{-1}g_{\pi _{x}(i)}^{-1}xg_{i}h_{j}=k_{y_{i}}(j)}$ , where ${\displaystyle y_{i}:=h_{x}(i)}$ . Therefore, the image of ${\displaystyle x}$  under the Artin transfer ${\displaystyle T_{G,K}}$  is given by ${\displaystyle T_{G,K}(x)=\prod _{i=1}^{n}\,\prod _{j=1}^{m}\,k_{y_{i}}(j)\cdot K^{\prime }=\prod _{i=1}^{n}\,\prod _{j=1}^{m}\,h_{\sigma _{y_{i}}(j)}^{-1}g_{\pi _{x}(i)}^{-1}xg_{i}h_{j}\cdot K^{\prime }}$  ${\displaystyle =\prod _{i=1}^{n}\,\prod _{j=1}^{m}\,h_{\sigma _{y_{i}}(j)}^{-1}h_{x}(i)h_{j}\cdot K^{\prime }=\prod _{i=1}^{n}\,\prod _{j=1}^{m}\,h_{\sigma _{y_{i}}(j)}^{-1}y_{i}h_{j}\cdot K^{\prime }}$  ${\displaystyle =\prod _{i=1}^{n}\,{\tilde {T}}_{H,K}(y_{i}\cdot H^{\prime })={\tilde {T}}_{H,K}(\prod _{i=1}^{n}\,y_{i}\cdot H^{\prime })={\tilde {T}}_{H,K}(\prod _{i=1}^{n}\,h_{x}(i)\cdot H^{\prime })={\tilde {T}}_{H,K}(T_{G,H}(x))}$ .

Cycle decomposition

Let ${\displaystyle (g_{1},\ldots ,g_{n})}$  be a left transversal of a subgroup ${\displaystyle H<G}$  of finite index ${\displaystyle n=(G:H)}$  in a group ${\displaystyle G}$ . Suppose the element ${\displaystyle x\in G}$  gives rise to the permutation ${\displaystyle \pi _{x}\in S_{n}}$  of the left cosets of ${\displaystyle H}$  in ${\displaystyle G}$  such that ${\displaystyle xg_{i}H=g_{\pi _{x}(i)}H}$ , resp. ${\displaystyle g_{\pi _{x}(i)}^{-1}xg_{i}=:h_{x}(i)\in H}$ , for each ${\displaystyle 1\leq i\leq n}$ .

If ${\displaystyle \pi _{x}}$  has the decomposition ${\displaystyle \pi _{x}=\prod _{j=1}^{t}\,\zeta _{j}}$  into pairwise disjoint cycles ${\displaystyle \zeta _{j}\in S_{n}}$  of lengths ${\displaystyle f_{j}\geq 1}$  , which is unique up to the ordering of the cycles, more explicitly, if ${\displaystyle (g_{j}H,g_{\zeta _{j}(j)}H,g_{\zeta _{j}^{2}(j)}H,\ldots ,g_{\zeta _{j}^{f_{j}-1}(j)}H)=(g_{j}H,xg_{j}H,x^{2}g_{j}H,\ldots ,x^{f_{j}-1}g_{j}H)}$ , for ${\displaystyle 1\leq j\leq t}$ , and ${\displaystyle \sum _{j=1}^{t}\,f_{j}=n}$ , then the image of ${\displaystyle x}$  under the Artin transfer ${\displaystyle T_{G,H}}$  is given by ${\displaystyle T_{G,H}(x)=\prod _{j=1}^{t}\,g_{j}^{-1}x^{f_{j}}g_{j}\cdot H^{\prime }}$ .

The reason for this fact is that we obtain another left transversal of ${\displaystyle H}$  in ${\displaystyle G}$  by putting ${\displaystyle \gamma _{j,k}:=x^{k}g_{j}}$  for ${\displaystyle 0\leq k\leq f_{j}-1}$  and ${\displaystyle 1\leq j\leq t}$ , since ${\displaystyle G={\dot {\cup }}_{j=1}^{t}\,{\dot {\cup }}_{k=0}^{f_{j}-1}\,x^{k}g_{j}H}$ . Let us fix a value of ${\displaystyle 1\leq j\leq t}$ . For ${\displaystyle 0\leq k\leq f_{j}-2}$ , we have ${\displaystyle x\gamma _{j,k}=xx^{k}g_{j}=x^{k+1}g_{j}=\gamma _{j,k+1}=\gamma _{j,k+1}\cdot 1}$ , resp. ${\displaystyle h_{x}(j,k)=1}$ . However, for ${\displaystyle k=f_{j}-1}$ , we obtain ${\displaystyle x\gamma _{j,f_{j}-1}=xx^{f_{j}-1}g_{j}=x^{f_{j}}g_{j}\in g_{j}H}$ , resp. ${\displaystyle g_{j}^{-1}x^{f_{j}}g_{j}=h_{x}(j,f_{j}-1)\in H}$ . Consequently, ${\displaystyle T_{G,H}(x)=\prod _{j=1}^{t}\,\prod _{k=0}^{f_{j}-1}\,h_{x}(j,k)\cdot H^{\prime }=\prod _{j=1}^{t}\,(\prod _{k=0}^{f_{j}-2}\,1)\cdot h_{x}(j,f_{j}-1)\cdot H^{\prime }=\prod _{j=1}^{t}\,g_{j}^{-1}x^{f_{j}}g_{j}\cdot H^{\prime }}$ .

Normal subgroup

Let ${\displaystyle H\triangleleft G}$  be a normal subgroup of finite index ${\displaystyle n=(G:H)}$  in a group ${\displaystyle G}$ . Then we have ${\displaystyle xH=Hx}$ , for all ${\displaystyle x\in G}$ , and there exists the quotient group ${\displaystyle G/H}$  of order ${\displaystyle n}$ . For an element ${\displaystyle x\in G}$ , we let ${\displaystyle f:=\mathrm {ord} (xH)}$  denote the order of the coset ${\displaystyle xH}$  in ${\displaystyle G/H}$ . Then, ${\displaystyle \langle xH\rangle }$  is a cyclic subgroup of order ${\displaystyle f}$  of ${\displaystyle G/H}$ , and a (left) transversal ${\displaystyle (g_{1},\ldots ,g_{t})}$  of the subgroup ${\displaystyle \langle x,H\rangle }$  in ${\displaystyle G}$ , where ${\displaystyle t=n/f}$  and ${\displaystyle G={\dot {\cup }}_{j=1}^{t}\,g_{j}\langle x,H\rangle }$ , can be extended to a (left) transversal ${\displaystyle G={\dot {\cup }}_{j=1}^{t}\,{\dot {\cup }}_{k=0}^{f}\,g_{j}x^{k}H}$  of ${\displaystyle H}$  in ${\displaystyle G}$ . Hence, the formula for the image of ${\displaystyle x}$  under the Artin transfer ${\displaystyle T_{G,H}}$  in the previous section takes the particular shape ${\displaystyle T_{G,H}(x)=\prod _{j=1}^{t}\,g_{j}^{-1}x^{f}g_{j}\cdot H^{\prime }}$  with exponent ${\displaystyle f}$  independent of ${\displaystyle j}$ .

In particular, the inner transfer of an element ${\displaystyle x\in H}$  of order ${\displaystyle f=1}$  is given as a symbolic power ${\displaystyle T_{G,H}(x)=\prod _{j=1}^{t}\,g_{j}^{-1}xg_{j}\cdot H^{\prime }=\prod _{j=1}^{t}\,x^{g_{j}}\cdot H^{\prime }=x^{\sum _{j=1}^{t}\,g_{j}}\cdot H^{\prime }}$  with the trace element ${\displaystyle \mathrm {Tr} _{G}(H)=\sum _{j=1}^{t}\,g_{j}\in \mathbb {Z} \lbrack G\rbrack }$  of ${\displaystyle H}$  in ${\displaystyle G}$  as symbolic exponent. The other extreme is the outer transfer of an element ${\displaystyle x\in G\setminus H}$  which generates ${\displaystyle G}$  modulo ${\displaystyle H}$ , that is ${\displaystyle G=\langle x,H\rangle }$  and ${\displaystyle f=n}$ , is simply an ${\displaystyle n}$ th power ${\displaystyle T_{G,H}(x)=\prod _{j=1}^{1}\,1^{-1}\cdot x^{n}\cdot 1\cdot H^{\prime }=x^{n}\cdot H^{\prime }}$ .

Transfer kernels and targets

Let ${\displaystyle G}$  be a group with finite abelianization ${\displaystyle G/G^{\prime }}$ . Suppose that ${\displaystyle (H_{i})_{i\in I}}$  denotes the family of all subgroups ${\displaystyle H_{i}\triangleleft G}$  which contain the commutator subgroup ${\displaystyle G^{\prime }}$  and are therefore necessarily normal, enumerated by means of the finite index set ${\displaystyle I}$ . For each ${\displaystyle i\in I}$ , let ${\displaystyle T_{i}:=T_{G,H_{i}}}$  be the Artin transfer from ${\displaystyle G}$  to the abelianization ${\displaystyle H_{i}/H_{i}^{\prime }}$ .

Definition. ^[3]

The family of normal subgroups ${\displaystyle \varkappa _{H}(G)=(\ker(T_{i}))_{i\in I}}$  is called the transfer kernel type (TKT) of ${\displaystyle G}$  with respect to ${\displaystyle (H_{i})_{i\in I}}$ , and the family of abelianizations (resp. their abelian type invariants) ${\displaystyle \tau _{H}(G)=(H_{i}/H_{i}^{\prime })_{i\in I}}$  is called the transfer target type (TTT) of ${\displaystyle G}$  with respect to ${\displaystyle (H_{i})_{i\in I}}$ . Both families are also called multiplets whereas a single component will be referred to as a singulet.

Important examples for these concepts are provided in the following two sections.

Abelianization of type (p,p)

Let ${\displaystyle G}$  be a p-group with abelianization ${\displaystyle G/G^{\prime }}$  of elementary abelian type ${\displaystyle (p,p)}$ . Then ${\displaystyle G}$  has ${\displaystyle p+1}$  maximal subgroups ${\displaystyle H_{i}<G}$  ${\displaystyle (1\leq i\leq p+1)}$  of index ${\displaystyle (G:H_{i})=p}$ . For each ${\displaystyle 1\leq i\leq p+1}$ , let ${\displaystyle T_{i}:\,G\to H_{i}/H_{i}^{\prime }}$  be the Artin transfer homomorphism from ${\displaystyle G}$  to the abelianization of ${\displaystyle H_{i}}$ .

Definition.

The family of normal subgroups ${\displaystyle \varkappa _{H}(G)=(\ker(T_{i}))_{1\leq i\leq p+1}}$  is called the transfer kernel type (TKT) of ${\displaystyle G}$  with respect to ${\displaystyle H_{1},\ldots ,H_{p+1}}$ .

Remarks.

• For brevity, the TKT is identified with the multiplet ${\displaystyle (\varkappa (i))_{1\leq i\leq p+1}}$ , whose integer components are given by ${\displaystyle \varkappa (i)={\begin{cases}0&{\text{ if }}\ker(T_{i})=G,\\j&{\text{ if }}\ker(T_{i})=H_{j}{\text{ for some }}1\leq j\leq p+1.\end{cases}}}$  Here, we take into consideration that each transfer kernel ${\displaystyle \ker(T_{i})}$  must contain the commutator subgroup ${\displaystyle G^{\prime }}$  of ${\displaystyle G}$ , since the transfer target ${\displaystyle H_{i}/H_{i}^{\prime }}$  is abelian. However, the minimal case ${\displaystyle \ker(T_{i})=G^{\prime }}$  cannot occur.
• A renumeration of the maximal subgroups ${\displaystyle K_{i}=H_{\pi (i)}}$  and of the transfers ${\displaystyle V_{i}=T_{\pi (i)}}$  by means of a permutation ${\displaystyle \pi \in S_{p+1}}$  gives rise to a new TKT ${\displaystyle \lambda _{K}(G)=(\ker(V_{i}))_{1\leq i\leq p+1}}$  with respect to ${\displaystyle K_{1},\ldots ,K_{p+1}}$ , identified with ${\displaystyle (\lambda (i))_{1\leq i\leq p+1}}$ , where ${\displaystyle \lambda (i)={\begin{cases}0&{\text{ if }}\ker(V_{i})=G,\\j&{\text{ if }}\ker(V_{i})=K_{j}{\text{ for some }}1\leq j\leq p+1.\end{cases}}}$  It is adequate to view the TKTs ${\displaystyle \lambda _{K}(G)\sim \varkappa _{H}(G)}$  as equivalent. Since we have ${\displaystyle K_{\lambda (i)}=\ker(V_{i})=\ker(T_{\pi (i)})=H_{\varkappa (\pi (i))}=K_{{\tilde {\pi }}^{-1}(\varkappa (\pi (i)))}}$ , the relation between ${\displaystyle \lambda }$  and ${\displaystyle \varkappa }$  is given by ${\displaystyle \lambda ={\tilde {\pi }}^{-1}\circ \varkappa \circ \pi }$ . Therefore, ${\displaystyle \lambda }$  is another representative of the orbit ${\displaystyle \varkappa ^{S_{p+1}}}$  of ${\displaystyle \varkappa }$  under the operation ${\displaystyle (\pi ,\mu )\mapsto {\tilde {\pi }}^{-1}\circ \mu \circ \pi }$  of the symmetric group ${\displaystyle S_{p+1}}$  on the set of all mappings from ${\displaystyle \lbrace 1,\ldots ,p+1\rbrace }$  to ${\displaystyle \lbrace 0,\ldots ,p+1\rbrace }$ , where the extension ${\displaystyle {\tilde {\pi }}\in S_{p+2}}$  of the permutation ${\displaystyle \pi \in S_{p+1}}$  is defined by ${\displaystyle {\tilde {\pi }}(0)=0}$ , and formally ${\displaystyle H_{0}=G}$ , ${\displaystyle K_{0}=G}$ .

Definition.

The orbit ${\displaystyle \varkappa (G)=\varkappa ^{S_{p+1}}}$  of any representative ${\displaystyle \varkappa }$  is an invariant of the p-group ${\displaystyle G}$  and is called its transfer kernel type, briefly TKT.

Abelianization of type (p²,p)

Let ${\displaystyle G}$  be a p-group with abelianization ${\displaystyle G/G^{\prime }}$  of non-elementary abelian type ${\displaystyle (p^{2},p)}$ . Then ${\displaystyle G}$  possesses ${\displaystyle p+1}$  maximal subgroups ${\displaystyle H_{i}<G}$  ${\displaystyle (1\leq i\leq p+1)}$  of index ${\displaystyle (G:H_{i})=p}$ , and ${\displaystyle p+1}$  subgroups ${\displaystyle U_{i}<G}$  ${\displaystyle (1\leq i\leq p+1)}$  of index ${\displaystyle (G:U_{i})=p^{2}}$ .

Assumption.

Suppose that ${\displaystyle H_{p+1}=\prod _{j=1}^{p+1}\,U_{j}}$  is the distinguished maximal subgroup which is the product of all subgroups of index ${\displaystyle p^{2}}$ , and ${\displaystyle U_{p+1}=\cap _{j=1}^{p+1}\,H_{j}}$  is the distinguished subgroup of index ${\displaystyle p^{2}}$  which is the intersection of all maximal subgroups, that is the Frattini subgroup ${\displaystyle \Phi (G)}$  of ${\displaystyle G}$ .

First layer

For each ${\displaystyle 1\leq i\leq p+1}$ , let ${\displaystyle T_{1,i}:\,G\to H_{i}/H_{i}^{\prime }}$  be the Artin transfer homomorphism from ${\displaystyle G}$  to the abelianization of ${\displaystyle H_{i}}$ .

Definition.

The family ${\displaystyle \varkappa _{1,H,U}(G)=(\ker(T_{1,i}))_{1\leq i\leq p+1}}$  is called the first layer transfer kernel type of ${\displaystyle G}$  with respect to ${\displaystyle H_{1},\ldots ,H_{p+1}}$  and ${\displaystyle U_{1},\ldots ,U_{p+1}}$ , and is identified with ${\displaystyle (\varkappa _{1}(i))_{1\leq i\leq p+1}}$ , where ${\displaystyle \varkappa _{1}(i)={\begin{cases}0&{\text{ if }}\ker(T_{1,i})=H_{p+1},\\j&{\text{ if }}\ker(T_{1,i})=U_{j}{\text{ for some }}1\leq j\leq p+1.\end{cases}}}$ 

Remark.

Here, we observe that each first layer transfer kernel is of exponent ${\displaystyle p}$  with respect to ${\displaystyle G^{\prime }}$  and consequently cannot coincide with ${\displaystyle H_{j}}$  for any ${\displaystyle 1\leq j\leq p}$ , since ${\displaystyle H_{j}/G^{\prime }}$  is cyclic of order ${\displaystyle p^{2}}$ , whereas ${\displaystyle H_{p+1}/G^{\prime }}$  is bicyclic of type ${\displaystyle (p,p)}$ .

Second layer

For each ${\displaystyle 1\leq i\leq p+1}$ , let ${\displaystyle T_{2,i}:\,G\to U_{i}/U_{i}^{\prime }}$  be the Artin transfer homomorphism from ${\displaystyle G}$  to the abelianization of ${\displaystyle U_{i}}$ .

Definition.

The family ${\displaystyle \varkappa _{2,U,H}(G)=(\ker(T_{2,i}))_{1\leq i\leq p+1}}$  is called the second layer transfer kernel type of ${\displaystyle G}$  with respect to ${\displaystyle U_{1},\ldots ,U_{p+1}}$  and ${\displaystyle H_{1},\ldots ,H_{p+1}}$ , and is identified with ${\displaystyle (\varkappa _{2}(i))_{1\leq i\leq p+1}}$ , where ${\displaystyle \varkappa _{2}(i)={\begin{cases}0&{\text{ if }}\ker(T_{2,i})=G,\\j&{\text{ if }}\ker(T_{2,i})=H_{j}{\text{ for some }}1\leq j\leq p+1.\end{cases}}}$ 

Transfer kernel type

Combining the information on the two layers, we obtain the (complete) transfer kernel type ${\displaystyle \varkappa _{H,U}(G)=(\varkappa _{1,H,U}(G);\varkappa _{2,U,H}(G))}$  of the p-group ${\displaystyle G}$  with respect to ${\displaystyle H_{1},\ldots ,H_{p+1}}$  and ${\displaystyle U_{1},\ldots ,U_{p+1}}$ .

Remark.

The distinguished subgroups ${\displaystyle H_{p+1}}$  and ${\displaystyle U_{p+1}=\Phi (G)}$  are unique invariants of ${\displaystyle G}$  and should not be renumerated. However, independent renumerations of the remaining maximal subgroups ${\displaystyle K_{i}=H_{\tau (i)}}$  ${\displaystyle (1\leq i\leq p)}$  and the transfers ${\displaystyle V_{1,i}=T_{1,\tau (i)}}$  by means of a permutation ${\displaystyle \tau \in S_{p}}$ , and of the remaining subgroups ${\displaystyle W_{i}=U_{\sigma (i)}}$  ${\displaystyle (1\leq i\leq p)}$  of index ${\displaystyle p^{2}}$  and the transfers ${\displaystyle V_{2,i}=T_{2,\sigma (i)}}$  by means of a permutation ${\displaystyle \sigma \in S_{p}}$ , give rise to new TKTs ${\displaystyle \lambda _{1,K,W}(G)=(\ker(V_{1,i}))_{1\leq i\leq p+1}}$  with respect to ${\displaystyle K_{1},\ldots ,K_{p+1}}$  and ${\displaystyle W_{1},\ldots ,W_{p+1}}$ , identified with ${\displaystyle (\lambda _{1}(i))_{1\leq i\leq p+1}}$ , where ${\displaystyle \lambda _{1}(i)={\begin{cases}0&{\text{ if }}\ker(V_{1,i})=K_{p+1},\\j&{\text{ if }}\ker(V_{1,i})=W_{j}{\text{ for some }}1\leq j\leq p+1,\end{cases}}}$  and ${\displaystyle \lambda _{2,W,K}(G)=(\ker(V_{2,i}))_{1\leq i\leq p+1}}$  with respect to ${\displaystyle W_{1},\ldots ,W_{p+1}}$  and ${\displaystyle K_{1},\ldots ,K_{p+1}}$ , identified with ${\displaystyle (\lambda _{2}(i))_{1\leq i\leq p+1}}$ , where ${\displaystyle \lambda _{2}(i)={\begin{cases}0&{\text{ if }}\ker(V_{2,i})=G,\\j&{\text{ if }}\ker(V_{2,i})=K_{j}{\text{ for some }}1\leq j\leq p+1.\end{cases}}}$  It is adequate to view the TKTs ${\displaystyle \lambda _{1,K,W}(G)\sim \varkappa _{1,H,U}(G)}$  and ${\displaystyle \lambda _{2,W,K}(G)\sim \varkappa _{2,U,H}(G)}$  as equivalent. Since we have ${\displaystyle W_{\lambda _{1}(i)}=\ker(V_{1,i})=\ker(T_{1,{\hat {\tau }}(i)})=U_{\varkappa _{1}({\hat {\tau }}(i))}=W_{{\tilde {\sigma }}^{-1}(\varkappa _{1}({\hat {\tau }}(i)))}}$ , resp. ${\displaystyle K_{\lambda _{2}(i)}=\ker(V_{2,i})=\ker(T_{2,{\hat {\sigma }}(i)})=H_{\varkappa _{2}({\hat {\sigma }}(i))}=K_{{\tilde {\tau }}^{-1}(\varkappa _{2}({\hat {\sigma }}(i)))}}$ , the relations between ${\displaystyle \lambda _{1}}$  and ${\displaystyle \varkappa _{1}}$ , resp. ${\displaystyle \lambda _{2}}$  and ${\displaystyle \varkappa _{2}}$ , are given by ${\displaystyle \lambda _{1}={\tilde {\sigma }}^{-1}\circ \varkappa _{1}\circ {\hat {\tau }}}$ , resp. ${\displaystyle \lambda _{2}={\tilde {\tau }}^{-1}\circ \varkappa _{2}\circ {\hat {\sigma }}}$ . Therefore, ${\displaystyle \lambda =(\lambda _{1},\lambda _{2})}$  is another representative of the orbit ${\displaystyle \varkappa ^{S_{p}\times S_{p}}}$  of ${\displaystyle \varkappa =(\varkappa _{1},\varkappa _{2})}$  under the operation ${\displaystyle ((\sigma ,\tau ),(\mu _{1},\mu _{2}))\mapsto ({\tilde {\sigma }}^{-1}\circ \mu _{1}\circ {\hat {\tau }},{\tilde {\tau }}^{-1}\circ \mu _{2}\circ {\hat {\sigma }})}$  of the product of two symmetric groups ${\displaystyle S_{p}\times S_{p}}$  on the set of all pairs of mappings from ${\displaystyle \lbrace 1,\ldots ,p+1\rbrace }$  to ${\displaystyle \lbrace 0,\ldots ,p+1\rbrace }$ , where the extensions ${\displaystyle {\hat {\pi }}\in S_{p+1}}$  and ${\displaystyle {\tilde {\pi }}\in S_{p+2}}$  of a permutation ${\displaystyle \pi \in S_{p}}$  are defined by ${\displaystyle {\hat {\pi }}(p+1)={\tilde {\pi }}(p+1)=p+1}$  and ${\displaystyle {\tilde {\pi }}(0)=0}$ , and formally ${\displaystyle H_{0}=K_{0}=G}$ , ${\displaystyle K_{p+1}=H_{p+1}}$ , ${\displaystyle U_{0}=W_{0}=H_{p+1}}$ , and ${\displaystyle W_{p+1}=U_{p+1}=\Phi (G)}$ .

Definition.

The orbit ${\displaystyle \varkappa (G)=\varkappa ^{S_{p}\times S_{p}}}$  of any representative ${\displaystyle \varkappa =(\varkappa _{1},\varkappa _{2})}$  is an invariant of the p-group ${\displaystyle G}$  and is called its transfer kernel type, briefly TKT.

 

Figure 1: Factoring through the abelianization.

Inheritance from quotients

The common feature of all parent-descendant relations between finite p-groups is that the parent ${\displaystyle \pi (G)}$  is a quotient ${\displaystyle G/N}$  of the descendant ${\displaystyle G}$  by a suitable normal subgroup ${\displaystyle N\triangleleft G}$ . Thus, an equivalent definition can be given by selecting an epimorphism ${\displaystyle \varphi }$  from ${\displaystyle G}$  onto a group ${\displaystyle {\tilde {G}}}$  whose kernel ${\displaystyle \ker(\varphi )}$  plays the role of the normal subgroup ${\displaystyle N\triangleleft G}$ . In the following sections, this point of view will be taken, generally for arbitrary groups.

Passing through the abelianization

If ${\displaystyle \varphi :\ G\to A}$  is a homomorphism from a group ${\displaystyle G}$  to an abelian group ${\displaystyle A}$ , then there exists a unique homomorphism ${\displaystyle {\tilde {\varphi }}:\ G/G^{\prime }\to A}$  such that ${\displaystyle \varphi ={\tilde {\varphi }}\circ \omega }$ , where ${\displaystyle \omega :\ G\to G/G^{\prime }}$  denotes the canonical projection. The kernel of ${\displaystyle {\tilde {\varphi }}}$  is given by ${\displaystyle \ker({\tilde {\varphi }})=\ker(\varphi )/G^{\prime }}$ . The situation is visualized in Figure 1.

The uniqueness of ${\displaystyle {\tilde {\varphi }}}$  is a consequence of the condition ${\displaystyle \varphi ={\tilde {\varphi }}\circ \omega }$ , which implies that ${\displaystyle {\tilde {\varphi }}}$  must be defined by ${\displaystyle {\tilde {\varphi }}(xG^{\prime })={\tilde {\varphi }}(\omega (x))=({\tilde {\varphi }}\circ \omega )(x)=\varphi (x)}$ , for any ${\displaystyle x\in G}$ . The relation ${\displaystyle {\tilde {\varphi }}(xG^{\prime }\cdot yG^{\prime })={\tilde {\varphi }}((xy)G^{\prime })=\varphi (xy)=\varphi (x)\cdot \varphi (y)={\tilde {\varphi }}(xG^{\prime })\cdot {\tilde {\varphi }}(xG^{\prime })}$ , for ${\displaystyle x,y\in G}$ , shows that ${\displaystyle {\tilde {\varphi }}}$  is a homomorphism. For the commutator of ${\displaystyle x,y\in G}$ , we have ${\displaystyle \varphi (\lbrack x,y\rbrack )=\lbrack \varphi (x),\varphi (y)\rbrack =1}$ , since ${\displaystyle A}$  is abelian. Thus, the commutator subgroup ${\displaystyle G^{\prime }}$  of ${\displaystyle G}$  is contained in the kernel ${\displaystyle \ker(\varphi )}$ , and this finally shows that the definition of ${\displaystyle {\tilde {\varphi }}}$  is independent of the coset representative, ${\displaystyle xG^{\prime }=yG^{\prime }}$  ${\displaystyle \Rightarrow }$  ${\displaystyle x^{-1}y\in G^{\prime }\leq \ker(\varphi )}$  ${\displaystyle \Rightarrow }$  ${\displaystyle {\tilde {\varphi }}(xG^{\prime })^{-1}\cdot {\tilde {\varphi }}(yG^{\prime })={\tilde {\varphi }}(x^{-1}yG^{\prime })=\varphi (x^{-1}y)=1}$  ${\displaystyle \Rightarrow }$  ${\displaystyle {\tilde {\varphi }}(xG^{\prime })={\tilde {\varphi }}(yG^{\prime })}$ .

 

Figure 2: Epimorphisms and derived quotients.

TTT singulets

Let ${\displaystyle G}$  and ${\displaystyle {\tilde {G}}}$  be groups such that ${\displaystyle {\tilde {G}}=\varphi (G)}$  is the image of ${\displaystyle G}$  under an epimorphism ${\displaystyle \varphi :\ G\to {\tilde {G}}}$  and ${\displaystyle {\tilde {H}}=\varphi (H)}$  is the image of a subgroup ${\displaystyle H\leq G}$ .

The commutator subgroup of ${\displaystyle {\tilde {H}}}$  is the image of the commutator subgroup of ${\displaystyle H}$ , that is ${\displaystyle {\tilde {H}}^{\prime }=\varphi (H^{\prime })}$ . If ${\displaystyle \ker(\varphi )\leq H}$ , then ${\displaystyle {\tilde {H}}\simeq H/\ker(\varphi )}$ , ${\displaystyle \varphi }$  induces a unique epimorphism ${\displaystyle {\tilde {\varphi }}:\ H/H^{\prime }\to {\tilde {H}}/{\tilde {H}}^{\prime }}$ , and thus ${\displaystyle {\tilde {H}}/{\tilde {H}}^{\prime }}$  is epimorphic image of ${\displaystyle H/H^{\prime }}$ , that is a quotient of ${\displaystyle H/H^{\prime }}$ . Moreover, if even ${\displaystyle \ker(\varphi )\leq H^{\prime }}$ , then ${\displaystyle {\tilde {H}}^{\prime }\simeq H^{\prime }/\ker(\varphi )}$ , the map ${\displaystyle {\tilde {\varphi }}}$  is an isomorphism, and ${\displaystyle {\tilde {H}}/{\tilde {H}}^{\prime }\simeq H/H^{\prime }}$ . See Figure 2 for a visualization of this scenario.

The statements can be seen in the following manner. The image of the commutator subgroup is ${\displaystyle \varphi (H^{\prime })=\varphi (\lbrack H,H\rbrack )=\varphi (\langle \lbrack u,v\rbrack \mid u,v\in H\rangle )=\langle \lbrack \varphi (u),\varphi (v)\rbrack \mid u,v\in H\rangle =\lbrack \varphi (H),\varphi (H)\rbrack )=\varphi (H)^{\prime }={\tilde {H}}^{\prime }}$ . If ${\displaystyle \ker(\varphi )\leq H}$ , then ${\displaystyle \varphi }$  can be restricted to an epimorphism ${\displaystyle \varphi \vert _{H}:\ H\to {\tilde {H}}}$ , whence ${\displaystyle {\tilde {H}}=\varphi (H)\simeq H/\ker(\varphi )}$ . According to the previous section, the composite epimorphism ${\displaystyle (\omega _{\tilde {H}}\circ \varphi \vert _{H}):\ H\to {\tilde {H}}/{\tilde {H}}^{\prime }}$  from ${\displaystyle H}$  onto the abelian group ${\displaystyle {\tilde {H}}/{\tilde {H}}^{\prime }}$  factors through ${\displaystyle H/H^{\prime }}$  by means of a uniquely determined epimorphism ${\displaystyle {\tilde {\varphi }}:\ H/H^{\prime }\to {\tilde {H}}/{\tilde {H}}^{\prime }}$  such that ${\displaystyle {\tilde {\varphi }}\circ \omega _{H}=\omega _{\tilde {H}}\circ \varphi \vert _{H}}$ . Consequently, we have ${\displaystyle {\tilde {H}}/{\tilde {H}}^{\prime }\simeq (H/H^{\prime })/\ker({\tilde {\varphi }})}$ . Furthermore, the kernel of ${\displaystyle {\tilde {\varphi }}}$  is given explicitly by ${\displaystyle \ker({\tilde {\varphi }})=\ker(\omega _{\tilde {H}}\circ \varphi \vert _{H})/H^{\prime }=(H^{\prime }\cdot \ker(\varphi ))/H^{\prime }}$ . Finally, if ${\displaystyle \ker(\varphi )\leq H^{\prime }}$ , then ${\displaystyle {\tilde {H}}^{\prime }=\varphi (H^{\prime })\simeq H^{\prime }/\ker(\varphi )}$  and ${\displaystyle {\tilde {\varphi }}}$  is an isomorphism, since ${\displaystyle \ker({\tilde {\varphi }})=H^{\prime }/H^{\prime }=1}$ .

Definition. ^[4]

Due to the results in the present section, it makes sense to define a partial order on the set of abelian type invariants by putting ${\displaystyle {\tilde {H}}/{\tilde {H}}^{\prime }\preceq H/H^{\prime }}$ , when ${\displaystyle {\tilde {H}}/{\tilde {H}}^{\prime }\simeq (H/H^{\prime })/\ker({\tilde {\varphi }})}$ , and ${\displaystyle {\tilde {H}}/{\tilde {H}}^{\prime }=H/H^{\prime }}$ , when ${\displaystyle {\tilde {H}}/{\tilde {H}}^{\prime }\simeq H/H^{\prime }}$ .

 

Figure 3: Epimorphisms and Artin transfers.

TKT singulets

Suppose that ${\displaystyle G}$  and ${\displaystyle {\tilde {G}}}$  are groups, ${\displaystyle {\tilde {G}}=\varphi (G)}$  is the image of ${\displaystyle G}$  under an epimorphism ${\displaystyle \varphi :\ G\to {\tilde {G}}}$ , and ${\displaystyle {\tilde {H}}=\varphi (H)}$  is the image of a subgroup ${\displaystyle H\leq G}$  of finite index ${\displaystyle n=(G:H)}$ . Let ${\displaystyle T_{G,H}}$  be the Artin transfer from ${\displaystyle G}$  to ${\displaystyle H/H^{\prime }}$  and ${\displaystyle T_{{\tilde {G}},{\tilde {H}}}}$  be the Artin transfer from ${\displaystyle {\tilde {G}}}$  to ${\displaystyle {\tilde {H}}/{\tilde {H}}^{\prime }}$ .

If ${\displaystyle \ker(\varphi )\leq H}$ , then the image ${\displaystyle (\varphi (g_{1}),\ldots ,\varphi (g_{n}))}$  of a left transversal ${\displaystyle (g_{1},\ldots ,g_{n})}$  of ${\displaystyle H}$  in ${\displaystyle G}$  is a left transversal of ${\displaystyle {\tilde {H}}}$  in ${\displaystyle {\tilde {G}}}$ , and the inclusion ${\displaystyle \varphi (\ker(T_{G,H}))\leq \ker(T_{{\tilde {G}},{\tilde {H}}})}$  holds. Moreover, if even ${\displaystyle \ker(\varphi )\leq H^{\prime }}$ , then the equation ${\displaystyle \varphi (\ker(T_{G,H}))=\ker(T_{{\tilde {G}},{\tilde {H}}})}$  holds. See Figure 3 for a visualization of this scenario.

The truth of these statements can be justified in the following way. Let ${\displaystyle (g_{1},\ldots ,g_{n})}$  be a left transversal of ${\displaystyle H}$  in ${\displaystyle G}$ . Then ${\displaystyle G={\dot {\cup }}_{i=1}^{n}\,g_{i}H}$  is a disjoint union but ${\displaystyle \varphi (G)={\dot {\cup }}_{i=1}^{n}\,\varphi (g_{i})\varphi (H)}$  is not necessarily disjoint. For ${\displaystyle 1\leq j,k\leq n}$ , we have ${\displaystyle \varphi (g_{j})\varphi (H)=\varphi (g_{k})\varphi (H)}$ ${\displaystyle \Leftrightarrow }$  ${\displaystyle \varphi (H)=\varphi (g_{j})^{-1}\varphi (g_{k})\varphi (H)=\varphi (g_{j}^{-1}g_{k})\varphi (H)}$  ${\displaystyle \Leftrightarrow }$  ${\displaystyle \varphi (g_{j}^{-1}g_{k})=\varphi (h)}$  for some element ${\displaystyle h\in H}$  ${\displaystyle \Leftrightarrow }$  ${\displaystyle \varphi (h^{-1}g_{j}^{-1}g_{k})=1}$  ${\displaystyle \Leftrightarrow }$  ${\displaystyle h^{-1}g_{j}^{-1}g_{k}=:k\in \ker(\varphi )}$ . However, if the condition ${\displaystyle \ker(\varphi )\leq H}$  is satisfied, then we are able to conclude that ${\displaystyle g_{j}^{-1}g_{k}=hk\in H}$ , and thus ${\displaystyle j=k}$ .

Let ${\displaystyle {\tilde {\varphi }}:\ H/H^{\prime }\to {\tilde {H}}/{\tilde {H}}^{\prime }}$  be the epimorphism obtained in the manner indicated in the previous section. For the image of ${\displaystyle x\in G}$  under the Artin transfer, we have ${\displaystyle {\tilde {\varphi }}(T_{G,H}(x))={\tilde {\varphi }}(\prod _{i=1}^{n}\,g_{\pi _{x}(i)}^{-1}xg_{i}\cdot H^{\prime })=\prod _{i=1}^{n}\,\varphi (g_{\pi _{x}(i)})^{-1}\varphi (x)\varphi (g_{i}))\cdot \varphi (H^{\prime })=}$ . Since ${\displaystyle \varphi (H^{\prime })=\varphi (H)^{\prime }={\tilde {H}}^{\prime }}$ , the right hand side equals ${\displaystyle T_{{\tilde {G}},{\tilde {H}}}(\varphi (x))}$ , provided that ${\displaystyle (\varphi (g_{1}),\ldots ,\varphi (g_{n}))}$  is a left transversal of ${\displaystyle {\tilde {H}}}$  in ${\displaystyle {\tilde {G}}}$ , which is correct, when ${\displaystyle \ker(\varphi )\leq H}$ . This shows that the diagram in Figure 3 is commutative, that is ${\displaystyle {\tilde {\varphi }}\circ T_{G,H}=T_{{\tilde {G}},{\tilde {H}}}\circ \varphi }$ . Consequently, we obtain the inclusion ${\displaystyle \varphi (\ker(T_{G,H}))\leq \ker(T_{{\tilde {G}},{\tilde {H}}})}$ , if ${\displaystyle \ker(\varphi )\leq H}$ . Finally, if ${\displaystyle \ker(\varphi )\leq H^{\prime }}$ , then the previous section has shown that ${\displaystyle {\tilde {\varphi }}}$  is an isomorphism. Using the inverse isomorphism, we get ${\displaystyle T_{G,H}={\tilde {\varphi }}^{-1}\circ T_{{\tilde {G}},{\tilde {H}}}\circ \varphi }$ , which proves the equation ${\displaystyle \varphi (\ker(T_{G,H}))=\ker(T_{{\tilde {G}},{\tilde {H}}})}$ .

Definition. ^[4]

In view of the results in the present section, we are able to define a partial order of transfer kernels by setting ${\displaystyle \ker(T_{G,H})\preceq \ker(T_{{\tilde {G}},{\tilde {H}}})}$ , when ${\displaystyle \varphi (\ker(T_{G,H}))\leq \ker(T_{{\tilde {G}},{\tilde {H}}})}$ , and ${\displaystyle \ker(T_{G,H})=\ker(T_{{\tilde {G}},{\tilde {H}}})}$ , when ${\displaystyle \varphi (\ker(T_{G,H}))=\ker(T_{{\tilde {G}},{\tilde {H}}})}$ .

TTT and TKT multiplets

Suppose ${\displaystyle G}$  and ${\displaystyle {\tilde {G}}}$  are groups, ${\displaystyle {\tilde {G}}=\varphi (G)}$  is the image of ${\displaystyle G}$  under an epimorphism ${\displaystyle \varphi :\ G\to {\tilde {G}}}$ , and both groups have isomorphic finite abelianizations ${\displaystyle G/G^{\prime }\simeq {\tilde {G}}/{\tilde {G}}^{\prime }}$ . Let ${\displaystyle (H_{i})_{i\in I}}$  denote the family of all subgroups ${\displaystyle H_{i}\triangleleft G}$  which contain the commutator subgroup ${\displaystyle G^{\prime }}$  (and thus are necessarily normal), enumerated by means of the finite index set ${\displaystyle I}$ , and let ${\displaystyle {\tilde {H_{i}}}=\varphi (H_{i})}$  be the image of ${\displaystyle H_{i}}$  under ${\displaystyle \varphi }$ , for each ${\displaystyle i\in I}$ . Assume that, for each ${\displaystyle i\in I}$ , ${\displaystyle T_{i}:=T_{G,H_{i}}}$  denotes the Artin transfer from ${\displaystyle G}$  to the abelianization ${\displaystyle H_{i}/H_{i}^{\prime }}$ , and ${\displaystyle {\tilde {T}}_{i}:=T_{{\tilde {G}},{\tilde {H}}_{i}}}$  denotes the Artin transfer from ${\displaystyle {\tilde {G}}}$  to the abelianization ${\displaystyle {\tilde {H}}_{i}/{\tilde {H}}_{i}^{\prime }}$ . Finally, let ${\displaystyle J\subseteq I}$  be any non-empty subset of ${\displaystyle I}$ .

Then it is convenient to define ${\displaystyle \varkappa _{H}(G)=(\ker(T_{j}))_{j\in J}}$ , called the (partial) transfer kernel type (TKT) of ${\displaystyle G}$  with respect to ${\displaystyle (H_{j})_{j\in J}}$ , and ${\displaystyle \tau _{H}(G)=(H_{j}/H_{j}^{\prime })_{j\in J}}$ , called the (partial) transfer target type (TTT) of ${\displaystyle G}$  with respect to ${\displaystyle (H_{j})_{j\in J}}$ .

Due to the rules for singulets, established in the preceding two sections, these multiplets of TTTs and TKTs obey the following fundamental inheritance laws:

1. If ${\displaystyle \ker(\varphi )\leq \cap _{j\in J}\,H_{j}}$ , then ${\displaystyle \tau _{\tilde {H}}({\tilde {G}})\preceq \tau _{H}(G)}$ , in the sense that ${\displaystyle {\tilde {H}}_{j}/{\tilde {H}}_{j}^{\prime }\preceq H_{j}/H_{j}^{\prime }}$ , for each ${\displaystyle j\in J}$ , and ${\displaystyle \varkappa _{H}(G)\preceq \varkappa _{\tilde {H}}({\tilde {G}})}$ , in the sense that ${\displaystyle \ker(T_{j})\preceq \ker({\tilde {T}}_{j})}$ , for each ${\displaystyle j\in J}$ .
2. If ${\displaystyle \ker(\varphi )\leq \cap _{j\in J}\,H_{j}^{\prime }}$ , then ${\displaystyle \tau _{\tilde {H}}({\tilde {G}})=\tau _{H}(G)}$ , in the sense that ${\displaystyle {\tilde {H}}_{j}/{\tilde {H}}_{j}^{\prime }=H_{j}/H_{j}^{\prime }}$ , for each ${\displaystyle j\in J}$ , and ${\displaystyle \varkappa _{H}(G)=\varkappa _{\tilde {H}}({\tilde {G}})}$ , in the sense that ${\displaystyle \ker(T_{j})=\ker({\tilde {T}}_{j})}$ , for each ${\displaystyle j\in J}$ .

Stabilization criteria

In this section, the results concerning the inheritance of TTTs and TKTs from quotients in the previous section are applied to the simplest case, which is characterized by the following

Assumption.

The parent ${\displaystyle \pi (G)}$  of a group ${\displaystyle G}$  is the quotient ${\displaystyle \pi (G)=G/N}$  of ${\displaystyle G}$  by the last non-trivial term ${\displaystyle N=\gamma _{c}(G)\triangleleft G}$  of the lower central series of ${\displaystyle G}$ , where ${\displaystyle c}$  denotes the nilpotency class of ${\displaystyle G}$ . The corresponding epimorphism ${\displaystyle \pi }$  from ${\displaystyle G}$  onto ${\displaystyle \pi (G)=G/\gamma _{c}(G)}$  is the canonical projection, whose kernel is given by ${\displaystyle \ker(\pi )=\gamma _{c}(G)}$ .

Under this assumption, the kernels and targets of Artin transfers turn out to be compatible with parent-descendant relations between finite p-groups.

Compatibility criterion.

Let ${\displaystyle p}$  be a prime number. Suppose that ${\displaystyle G}$  is a non-abelian finite p-group of nilpotency class ${\displaystyle c=\mathrm {cl} (G)\geq 2}$ . Then the TTT and the TKT of ${\displaystyle G}$  and of its parent ${\displaystyle \pi (G)}$  are comparable in the sense that ${\displaystyle \tau (\pi (G))\preceq \tau (G)}$  and ${\displaystyle \varkappa (G)\leq \varkappa (\pi (G))}$ .

The simple reason for this fact is that, for any subgroup ${\displaystyle G^{\prime }\leq H\leq G}$ , we have ${\displaystyle \ker(\pi )=\gamma _{c}(G)\leq \gamma _{2}(G)=G^{\prime }\leq H}$ , since ${\displaystyle c\geq 2}$ .

For the remaining part of this section, the investigated groups are supposed to be finite metabelian p-groups ${\displaystyle G}$  with elementary abelianization ${\displaystyle G/G^{\prime }}$  of rank ${\displaystyle 2}$ , that is of type ${\displaystyle (p,p)}$ .

Partial stabilization for maximal class.

A metabelian p-group ${\displaystyle G}$  of coclass ${\displaystyle \mathrm {cc} (G)=1}$  and of nilpotency class ${\displaystyle c=\mathrm {cl} (G)\geq 3}$  shares the last ${\displaystyle p}$  components of the TTT ${\displaystyle \tau (G)}$  and of the TKT ${\displaystyle \varkappa (G)}$  with its parent ${\displaystyle \pi (G)}$ . More explicitly, for odd primes ${\displaystyle p\geq 3}$ , we have ${\displaystyle \tau (G)_{i}=(p,p)}$  and ${\displaystyle \varkappa (G)_{i}=0}$  for ${\displaystyle 2\leq i\leq p+1}$ .

This criterion is due to the fact that ${\displaystyle c\geq 3}$  implies ${\displaystyle \ker(\pi )=\gamma _{c}(G)\leq \gamma _{3}(G)=H_{i}^{\prime }}$ , ^[5] for the last ${\displaystyle p}$  maximal subgroups ${\displaystyle H_{2},\ldots ,H_{p+1}}$  of ${\displaystyle G}$ .

Total stabilization for maximal class and positive defect.

A metabelian p-group ${\displaystyle G}$  of coclass ${\displaystyle \mathrm {cc} (G)=1}$  and of nilpotency class ${\displaystyle c=m-1=\mathrm {cl} (G)\geq 4}$ , that is, with index of nilpotency ${\displaystyle m\geq 5}$ , shares all ${\displaystyle p+1}$  components of the TTT ${\displaystyle \tau (G)}$  and of the TKT ${\displaystyle \varkappa (G)}$  with its parent ${\displaystyle \pi (G)}$ , provided it has positive defect of commutativity ${\displaystyle k=k(G)\geq 1}$ .^[3] Note that ${\displaystyle k\geq 1}$  implies ${\displaystyle p\geq 3}$ , and we have ${\displaystyle \varkappa (G)_{i}=0}$  for all ${\displaystyle 1\leq i\leq p+1}$ .

This statement can be seen by observing that the conditions ${\displaystyle m\geq 5}$  and ${\displaystyle k\geq 1}$  imply ${\displaystyle \ker(\pi )=\gamma _{m-1}(G)\leq \gamma _{m-k}(G)\leq H_{i}^{\prime }}$ , ^[5] for all the ${\displaystyle p+1}$  maximal subgroups ${\displaystyle H_{1},\ldots ,H_{p+1}}$  of ${\displaystyle G}$ .

Partial stabilization for non-maximal class.

Let ${\displaystyle p=3}$  be fixed. A metabelian 3-group ${\displaystyle G}$  with abelianization ${\displaystyle G/G^{\prime }\simeq (3,3)}$ , coclass ${\displaystyle \mathrm {cc} (G)\geq 2}$  and nilpotency class ${\displaystyle c=\mathrm {cl} (G)\geq 4}$  shares the last two (among the four) components of the TTT ${\displaystyle \tau (G)}$  and of the TKT ${\displaystyle \varkappa (G)}$  with its parent ${\displaystyle \pi (G)}$ .

This criterion is justified by the following consideration. If ${\displaystyle c\geq 4}$ , then ${\displaystyle \ker(\pi )=\gamma _{c}(G)\leq \gamma _{4}(G)\leq H_{i}^{\prime }}$  ^[5] for the last two maximal subgroups ${\displaystyle H_{3},H_{4}}$  of ${\displaystyle G}$ .

These three criteria show that Artin transfers provide a marvelous tool for classifying finite p-groups.

In the following section, it will be shown how these ideas can be applied for searching particular groups in descendant trees by looking for patterns defined by the kernels and targets of Artin transfers. These strategies of pattern recognition are useful in pure group theory and in algebraic number theory.

In the mathematical field of algebraic number theory, the concept principalization has its origin in D. Hilbert's 1897 conjecture that all ideals of an algebraic number field, which can always be generated by two algebraic numbers, become principal ideals, generated by a single algebraic number, when they are transferred to the maximal abelian unramified extension field, which was later called the Hilbert class field, of the given base field. More than thirty years later, Ph. Furtwängler succeeded in proving this principal ideal theorem in 1930, after it had been translated from number theory to group theory by E. Artin in 1929, who made use of his general reciprocity law to establish the reformulation. Since this long desired proof was achieved by means of metabelian groups of derived length two, several investigators tried to exploit the theory of such groups further to obtain additional information on the principalization in intermediate fields between the base field and its Hilbert class field.

Extension of classes

Let ${\displaystyle K}$  be an algebraic number field, called the base field, and let ${\displaystyle L\vert K}$  be a field extension of finite degree.

Definition.

The embedding monomorphism of fractional ideals ${\displaystyle \iota _{L\vert K}:\ {\mathcal {I}}_{K}\to {\mathcal {I}}_{L},\ {\mathfrak {a}}\mapsto {\mathfrak {a}}{\mathcal {O}}_{L}}$ , where ${\displaystyle {\mathcal {O}}_{L}}$  denotes the ring of integers of ${\displaystyle L}$ , induces the extension homomorphism of ideal classes ${\displaystyle j_{L\vert K}:\ {\mathcal {I}}_{K}/{\mathcal {P}}_{K}\to {\mathcal {I}}_{L}/{\mathcal {P}}_{L},\ {\mathfrak {a}}{\mathcal {P}}_{K}\mapsto ({\mathfrak {a}}{\mathcal {O}}_{L}){\mathcal {P}}_{L}}$ , where ${\displaystyle {\mathcal {P}}_{K}}$  and ${\displaystyle {\mathcal {P}}_{L}}$  denote the subgroups of principal ideals.

If there exists a non-principal ideal ${\displaystyle {\mathfrak {a}}\in {\mathcal {I}}_{K}}$ , with non trivial class ${\displaystyle {\mathfrak {a}}{\mathcal {P}}_{K}\neq {\mathcal {P}}_{K}}$ , whose extension ideal in ${\displaystyle L}$  is principal, ${\displaystyle {\mathfrak {a}}{\mathcal {O}}_{L}=A{\mathcal {O}}_{L}}$ for some number ${\displaystyle A\in L}$ , and hence belongs to the trivial class ${\displaystyle ({\mathfrak {a}}{\mathcal {O}}_{L}){\mathcal {P}}_{L}={\mathcal {P}}_{L}}$ , then we speak about principalization or capitulation in ${\displaystyle L\vert K}$ . In this case, the ideal ${\displaystyle {\mathfrak {a}}}$  and its class ${\displaystyle {\mathfrak {a}}{\mathcal {P}}_{K}}$  are said to principalize or capitulate in ${\displaystyle L}$ . This phenomenon is described most conveniently by the principalization kernel or capitulation kernel, that is the kernel ${\displaystyle \ker(j_{L\vert K})}$  of the class extension homomorphism.

Remark.

When ${\displaystyle F}$  is a Galois extension of ${\displaystyle K}$  with automorphism group ${\displaystyle G=\mathrm {Gal} (F\vert K)}$  such that ${\displaystyle K\leq L\leq F}$  is an intermediate field with relative group ${\displaystyle H=\mathrm {Gal} (F\vert L)\leq G}$ , more precise statements about the homomorphisms ${\displaystyle \iota _{L\vert K}}$  and ${\displaystyle j_{L\vert K}}$  are possible by using group theory. According to Hilbert's theory ^[6] on the decomposition of a prime ideal ${\displaystyle {\mathfrak {p}}\in \mathbb {P} _{K}}$  in the extension ${\displaystyle L\vert K}$ , viewed as a subextension of ${\displaystyle F\vert K}$ , we have ${\displaystyle {\mathfrak {p}}{\mathcal {O}}_{L}=\prod _{i=1}^{g}\,{\mathfrak {q}}_{i}}$ , where the ${\displaystyle {\mathfrak {q}}_{i}=\prod _{\varrho \in H\tau _{i}D}\,\varrho ({\mathfrak {P}})\in \mathbb {P} _{L}}$ , with ${\displaystyle 1\leq i\leq g}$ , are the prime ideals lying over ${\displaystyle {\mathfrak {p}}}$  in ${\displaystyle L}$ , expressed by a fixed prime ideal ${\displaystyle {\mathfrak {P}}\in \mathbb {P} _{F}}$  dividing ${\displaystyle {\mathfrak {p}}}$  in ${\displaystyle F}$  and a double coset decomposition ${\displaystyle G={\dot {\cup }}_{i=1}^{g}\,H\tau _{i}D}$  of ${\displaystyle G}$  modulo ${\displaystyle H}$  and modulo the decomposition group (stabilizer) ${\displaystyle D=\lbrace \sigma \in G\mid \sigma ({\mathfrak {P}})={\mathfrak {P}}\rbrace }$  of ${\displaystyle {\mathfrak {P}}}$  in ${\displaystyle G}$ , with a complete system of representatives ${\displaystyle (\tau _{1},\ldots ,\tau _{g})}$ . The order of the decomposition group ${\displaystyle D}$  is the inertia degree ${\displaystyle f({\mathfrak {P}}\vert {\mathfrak {p}})}$  of ${\displaystyle {\mathfrak {P}}}$  over ${\displaystyle K}$ .

Consequently, the ideal embedding is given by ${\displaystyle \iota _{L\vert K}({\mathfrak {p}})={\mathfrak {p}}{\mathcal {O}}_{L}=\prod _{i=1}^{g}\,{\mathfrak {q}}_{i}}$ , and the class extension by ${\displaystyle j_{L\vert K}({\mathfrak {p}}{\mathcal {P}}_{K})=\prod _{i=1}^{g}\,{\mathfrak {q}}_{i}{\mathcal {P}}_{L}}$ .

Artin's reciprocity law

Let ${\displaystyle F\vert K}$  be a Galois extension of algebraic number fields with automorphism group ${\displaystyle G=\mathrm {Gal} (F\vert K)}$ . Suppose that ${\displaystyle {\mathfrak {p}}\in \mathbb {P} _{K}}$  is a prime ideal of ${\displaystyle K}$  which does not divide the relative discriminant ${\displaystyle {\mathfrak {d}}={\mathfrak {d}}(F\vert K)}$ , and is therefore unramified in ${\displaystyle F}$ , and let ${\displaystyle {\mathfrak {P}}\in \mathbb {P} _{F}}$  be a prime ideal of ${\displaystyle F}$  lying over ${\displaystyle {\mathfrak {p}}}$ .

Then, there exists a unique automorphism ${\displaystyle \sigma \in G}$  such that ${\displaystyle A^{\mathrm {Norm} _{K\vert \mathbb {Q} }({\mathfrak {p}})}\equiv \sigma (A){\pmod {\mathfrak {P}}}}$ , for all algebraic integers ${\displaystyle A\in {\mathcal {O}}_{F}}$ , which is called the Frobenius automorphism ${\displaystyle \left\lbrack {\frac {F\vert K}{\mathfrak {P}}}\right\rbrack :=\sigma }$  of ${\displaystyle {\mathfrak {P}}}$  and generates the cyclic decomposition group ${\displaystyle D_{\mathfrak {P}}=\langle \sigma \rangle }$  of ${\displaystyle {\mathfrak {P}}}$ . Any other prime ideal of ${\displaystyle F}$  dividing ${\displaystyle {\mathfrak {p}}}$  is of the form ${\displaystyle \tau ({\mathfrak {P}})}$  with some ${\displaystyle \tau \in G}$ . Its Frobenius automorphism is given by ${\displaystyle \left\lbrack {\frac {F\vert K}{\tau ({\mathfrak {P}})}}\right\rbrack =\tau \left\lbrack {\frac {F\vert K}{\mathfrak {P}}}\right\rbrack \tau ^{-1}}$ , since ${\displaystyle \tau (A)^{\mathrm {Norm} _{K\vert \mathbb {Q} }({\mathfrak {p}})}\equiv (\tau \sigma \tau ^{-1})(\tau (A)){\pmod {\tau ({\mathfrak {P}})}}}$ , for all ${\displaystyle A\in {\mathcal {O}}_{F}}$ , and thus its decomposition group ${\displaystyle D_{\tau ({\mathfrak {P}})}=\tau D_{\mathfrak {P}}\tau ^{-1}}$  is conjugate to ${\displaystyle D_{\mathfrak {P}}}$ . In this general situation, the Artin symbol is a mapping ${\displaystyle {\mathfrak {p}}\mapsto \left({\frac {F\vert K}{\mathfrak {p}}}\right):=\lbrace \tau \left\lbrack {\frac {F\vert K}{\mathfrak {P}}}\right\rbrack \tau ^{-1}\mid \tau \in G\rbrace }$  which associates an entire conjugacy class of automorphisms to any unramified prime ideal ${\displaystyle {\mathfrak {p}}\not \vert {\mathfrak {d}}}$ , and we have ${\displaystyle \left({\frac {F\vert K}{\mathfrak {p}}}\right)=1}$  if and only if ${\displaystyle {\mathfrak {p}}}$  splits completely in ${\displaystyle F}$ .

Now let ${\displaystyle F\vert K}$  be an abelian extension, that is, the Galois group ${\displaystyle G=\mathrm {Gal} (F\vert K)}$  is an abelian group. Then, all conjugate decomposition groups of prime ideals of ${\displaystyle F}$  lying over ${\displaystyle {\mathfrak {p}}}$  coincide ${\displaystyle D_{\tau ({\mathfrak {P}})}=:D_{\mathfrak {p}}}$ , for any ${\displaystyle \tau \in G}$ , and the Artin symbol ${\displaystyle \left({\frac {F\vert K}{\mathfrak {p}}}\right)=\left\lbrack {\frac {F\vert K}{\mathfrak {P}}}\right\rbrack }$  becomes equal to the Frobenius automorphism of any ${\displaystyle {\mathfrak {P}}\mid {\mathfrak {p}}}$ , since ${\displaystyle A^{\mathrm {Norm} _{K\vert \mathbb {Q} }({\mathfrak {p}})}\equiv \left({\frac {F\vert K}{\mathfrak {p}}}\right)(A){\pmod {\mathfrak {p}}}}$ , for all ${\displaystyle A\in {\mathcal {O}}_{F}}$ .

By class field theory, ^[7] the abelian extension ${\displaystyle F\vert K}$  uniquely corresponds to an intermediate group ${\displaystyle {\mathcal {S}}_{K,{\mathfrak {f}}}\leq {\mathcal {H}}\leq {\mathcal {P}}_{K}({\mathfrak {f}})}$  between the ray modulo ${\displaystyle {\mathfrak {f}}}$  and the group of principal ideals coprime to ${\displaystyle {\mathfrak {f}}}$  of ${\displaystyle K}$ , where ${\displaystyle {\mathfrak {f}}={\mathfrak {f}}(F\vert K)}$  denotes the relative conductor. (Note that ${\displaystyle {\mathfrak {p}}\mid {\mathfrak {f}}}$  if and only if ${\displaystyle {\mathfrak {p}}\mid {\mathfrak {d}}}$ , but ${\displaystyle {\mathfrak {f}}}$  is minimal with this property.) The Artin symbol ${\displaystyle \mathbb {P} _{K}({\mathfrak {f}})\to G,\ {\mathfrak {p}}\mapsto \left({\frac {F\vert K}{\mathfrak {p}}}\right)}$ , which associates the Frobenius automorphism of ${\displaystyle {\mathfrak {p}}}$  to each prime ideal ${\displaystyle {\mathfrak {p}}}$  of ${\displaystyle K}$  which is unramified in ${\displaystyle F}$ , can be extended to the Artin isomorphism (or Artin map) ${\displaystyle {\mathcal {I}}_{K}({\mathfrak {f}})/{\mathcal {H}}\to G=\mathrm {Gal} (F\vert K),\ {\mathfrak {p}}{\mathcal {H}}\mapsto \left({\frac {F\vert K}{\mathfrak {p}}}\right)}$  of the generalized ideal class group ${\displaystyle {\mathcal {I}}_{K}({\mathfrak {f}})/{\mathcal {H}}}$  to the Galois group ${\displaystyle G}$ , which maps the class ${\displaystyle {\mathfrak {p}}{\mathcal {H}}}$  of ${\displaystyle {\mathfrak {p}}}$  to the Artin symbol ${\displaystyle \left({\frac {F\vert K}{\mathfrak {p}}}\right)}$  of ${\displaystyle {\mathfrak {p}}}$ . This explicit isomorphism is called the Artin reciprocity law or general reciprocity law. ^[8]

 

Figure 1: Commutative diagram connecting the class extension with the Artin transfer.

Commutative diagram

E. Artin's translation of the general principalization problem for a number field extension ${\displaystyle L\vert K}$  from number theory to group theory is based on the following scenario. Let ${\displaystyle F\vert K}$  be a Galois extension of algebraic number fields with automorphism group ${\displaystyle G=\mathrm {Gal} (F\vert K)}$ . Suppose that ${\displaystyle {\mathfrak {p}}\in \mathbb {P} _{K}}$  is a prime ideal of ${\displaystyle K}$  which does not divide the relative discriminant ${\displaystyle {\mathfrak {d}}={\mathfrak {d}}(F\vert K)}$ , and is therefore unramified in ${\displaystyle F}$ , and let ${\displaystyle {\mathfrak {P}}\in \mathbb {P} _{F}}$  be a prime ideal of ${\displaystyle F}$  lying over ${\displaystyle {\mathfrak {p}}}$ . Assume that ${\displaystyle K\leq L\leq F}$  is an intermediate field with relative group ${\displaystyle H=\mathrm {Gal} (F\vert L)\leq G}$  and let ${\displaystyle K^{\prime }\vert K}$ , resp. ${\displaystyle L^{\prime }\vert L}$ , be the maximal abelian subextension of ${\displaystyle K}$ , resp. ${\displaystyle L}$ , within ${\displaystyle F}$ . Then, the corresponding relative groups are the commutator subgroups ${\displaystyle G^{\prime }=\mathrm {Gal} (F\vert K^{\prime })\leq G}$ , resp. ${\displaystyle H^{\prime }=\mathrm {Gal} (F\vert L^{\prime })\leq H}$ .

By class field theory, there exist intermediate groups ${\displaystyle {\mathcal {S}}_{K,{\mathfrak {d}}}\leq {\mathcal {H}}_{K}\leq {\mathcal {P}}_{K}({\mathfrak {d}})}$  and ${\displaystyle {\mathcal {S}}_{L,{\mathfrak {d}}}\leq {\mathcal {H}}_{L}\leq {\mathcal {P}}_{L}({\mathfrak {d}})}$  such that the Artin maps establish isomorphisms ${\displaystyle \left({\frac {K^{\prime }\vert K}{\ldots }}\right):\,{\mathcal {I}}_{K}({\mathfrak {d}})/{\mathcal {H}}_{K}\to \mathrm {Gal} (K^{\prime }\vert K)\simeq G/G^{\prime }}$  and ${\displaystyle \left({\frac {L^{\prime }\vert L}{\ldots }}\right):\,{\mathcal {I}}_{L}({\mathfrak {d}})/{\mathcal {H}}_{L}\to \mathrm {Gal} (L^{\prime }\vert L)\simeq H/H^{\prime }}$ .

The class extension homomorphism ${\displaystyle j_{L\vert K}}$  and the Artin transfer, more precisely, the induced transfer ${\displaystyle {\tilde {T}}_{G,H}}$ , are connected by the commutative diagram in Figure 1 via these Artin isomorphisms, that is, we have equality of two composita ${\displaystyle {\tilde {T}}_{G,H}\circ \left({\frac {K^{\prime }\vert K}{\ldots }}\right)=\left({\frac {L^{\prime }\vert L}{\ldots }}\right)\circ j_{L\vert K}}$ . ^[9] The justification for this statement consists in analyzing the two paths of composite mappings. ^[7] On the one hand, the class extension homomorphism ${\displaystyle j_{L\vert K}}$  maps the generalized ideal class ${\displaystyle {\mathfrak {p}}{\mathcal {H}}_{K}}$  of the base field ${\displaystyle K}$  to the extension class ${\displaystyle j_{L\vert K}({\mathfrak {p}}{\mathcal {H}}_{K})=({\mathfrak {p}}{\mathcal {O}}_{L}){\mathcal {H}}_{L}=\prod _{i=1}^{g}\,{\mathfrak {q}}_{i}{\mathcal {H}}_{L}}$  in the field ${\displaystyle L}$ , and the Artin isomorphism ${\displaystyle \left({\frac {L^{\prime }\vert L}{\ldots }}\right)}$  of the field ${\displaystyle L}$  maps this product of classes of prime ideals to the product of conjugates of Frobenius automorphisms ${\displaystyle \prod _{i=1}^{g}\,\left({\frac {L^{\prime }\vert L}{\tau _{i}({\mathfrak {q}}_{i})}}\right)\cdot H^{\prime }=\prod _{i=1}^{g}\,\left({\frac {F\vert L}{\tau _{i}({\mathfrak {P}})}}\right)\cdot H^{\prime }=\prod _{i=1}^{g}\,\tau _{i}\left({\frac {F\vert K}{\mathfrak {P}}}\right)^{f_{i}}\tau _{i}^{-1}\cdot H^{\prime }}$ . Here, the double coset decomposition and its representatives were used, in perfect analogy to the last but one section. On the other hand, the Artin isomorphism ${\displaystyle \left({\frac {K^{\prime }\vert K}{\ldots }}\right)}$  of the base field ${\displaystyle K}$  maps the generalized ideal class ${\displaystyle {\mathfrak {p}}{\mathcal {H}}_{K}}$  to the Frobenius automorphism ${\displaystyle \left({\frac {K^{\prime }\vert K}{\mathfrak {p}}}\right)}$ , and the induced Artin transfer maps the symbol ${\displaystyle \left({\frac {K^{\prime }\vert K}{\mathfrak {p}}}\right)\equiv \left({\frac {F\vert K}{\mathfrak {P}}}\right){\pmod {G^{\prime }}}}$  to the product ${\displaystyle {\tilde {T}}_{G,H}(\left({\frac {F\vert K}{\mathfrak {P}}}\right)\cdot G^{\prime })=\prod _{i=1}^{g}\,\tau _{i}\left({\frac {F\vert K}{\mathfrak {P}}}\right)^{f_{i}}\tau _{i}^{-1}\cdot H^{\prime }}$ . ^[2]

References

1. Huppert, B. (1979). Endliche Gruppen I. Grundlehren der mathematischen Wissenschaften, Vol. 134, Springer-Verlag Berlin Heidelberg New York.
2. Artin, E. (1929). "Idealklassen in Oberkörpern und allgemeines Reziprozitätsgesetz". Abh. Math. Sem. Univ. Hamburg. 7: 46–51.
3. Mayer, D. C. (2013). "The distribution of second p-class groups on coclass graphs". J. Théor. Nombres Bordeaux. 25 (2): 401–456.
4. Bush, M. R., Mayer, D. C. (2014). "3-class field towers of exact length 3". J. Number Theory (preprint: arXiv:1312.0251 [math.NT]).
5. Mayer, D. C. (2012). "The second p-class group of a number field". Int. J. Number Theory. 8 (2): 471–505.
6. Hilbert, D. (1897). "Die Theorie der algebraischen Zahlkörper". Jahresber. Deutsch. Math. Verein. 4: 175–546.
7. Hasse, H. (1930). "Bericht über neuere Untersuchungen und Probleme aus der Theorie der algebraischen Zahlkörper. Teil II: Reziprozitätsgesetz". Jahresber. Deutsch. Math. Verein., Ergänzungsband. 6: 1–204.
8. Artin, E. (1927). "Beweis des allgemeinen Reziprozitätsgesetzes". Abh. Math. Sem. Univ. Hamburg. 5: 353–363.
9. Miyake, K. (1989). "Algebraic investigations of Hilbert's Theorem 94, the principal ideal theorem and the capitulation problem". Expo. Math. 7: 289–346.

Category: Group theory Category: Class field theory