Proof Of course, if $M \cap N = \{1\}$ , then $M^{G} \cap N^{G} = \{1\}$ as well. Suppose, then, that $M^{G} \cap N^{G} = \{1\}$ , and let $w \in M \cap N$ be given. If w is nontrivial, then $\langle w \rangle $ is isomorphic to precisely one of the following: $\mathbb {F}_{2}$ , $\mathbb {F}_{2}[\overline {G_{1}}]$ , $\mathbb {F}_{2}[\overline {G_{2}}]$ , $\mathbb {F}_{2}[\overline {G_{3}}]$ , $\Omega ^{-1}$ , or $\mathbb {F}_{2}[G]$ . In the first case, we have $w \in W^{G}$ , and so $w \in M^{G} \cap N^{G} = \{1\}$ ; this is a contraction. If either $\langle w \rangle \simeq \mathbb {F}_{2}[\overline {G_{1}}]$ , $\langle w\rangle \simeq \mathbb {F}_{2}[\overline {G_{3}}]$ , or $\langle w\rangle \simeq \Omega ^{-1}$ , then $w^{1+\sigma _{1}}$ is a nontrivial element in $W^{G}$ ; but this again leads to a contradiction, since then we again have $w^{1+\sigma _{1}} \in M^{G} \cap N^{G} = \{1\}$ . If $\langle w \rangle \simeq \mathbb {F}_{2}[\overline {G_{2}}]$ , then $w^{1+\sigma _{2}}$ is the nontrivial element in $W^{G}$ , which leads to a contradiction, and if $\langle w \rangle \simeq \mathbb {F}_{2}[G]$ , then the contradictory nontrivial element of $W^{G}$ is $w^{(1+\sigma _{1})(1+\sigma _{2})}$ .▪

Proof Suppose first that equation (3.1) holds. From this, we see that

$$ \begin{align*} \left([\gamma_{1}][\gamma_{2}][\gamma_{3}]\right)^{1+\sigma_{2}} &= [1][b][c],\\ \left([\gamma_{1}][\gamma_{2}][\gamma_{3}]\right)^{1+\sigma_{1}} &= [b][c][1]. \end{align*} $$

Hence, $[b][c] \in (\mathscr {B}+\mathscr {C})\cap \mathscr {D}$ .

For the other direction, suppose there exists $[\gamma ] \in J(K)$ so that the diagram for $\mathscr {D}$ holds with $[\gamma ]$ and $[f] = [b][c]$ . Since $[b] \in \mathscr {B}$ and $[c] \in \mathscr {C}$ , we also have elements $[\gamma _{L}],[\gamma _{R}] \in J(K)$ so that $[\gamma _{L}]$ and $[b]$ satisfy the diagram for $\mathscr {B}$ , and $[\gamma _{R}]$ and $[c]$ satisfy the diagram for $\mathscr {C}$ . From these relations, we find that equation (3.1) is satisfied with $[\gamma _{1}] = [\gamma _{L}]$ , $[\gamma _{2}] = [\gamma _{L}][\gamma ][\gamma _{R}]$ , and $[\gamma _{3}] = [\gamma _{R}]$ .▪

Proof That $B_{W}$ and $C_{W}$ are subspaces follows since equation (3.1) is linear. Now, we claim that, for each $[b] \in B_{W}$ , there exists a unique $[c] \in C_{W}$ for which the equations represented by equation (3.1) are solvable. Suppose instead we had some $[b] \in B_{W}$ so that there exist $[c],[\hat c] \in C_{W}$ which make equation (3.1) solvable; we will write $[\gamma _{1}],[\gamma _{2}],[\gamma _{3}]$ for the additional terms that solve the system with $[b]$ and $[c]$ , and we will write $[\gamma _{1}],[\widehat {\gamma _{2}}],[\widehat {\gamma _{3}}]$ for the additional terms that solve the system with $[b]$ and $[\hat c]$ . By multiplying the two systems, we are left with

and so we see that $[c][\hat c] \in \mathscr {V}$ . However, since $[c]$ and $[\hat c]$ are contained in a complement C of $\mathscr {V}$ within $\mathscr {C}$ , this implies $[c][\hat c] =[1]$ . Hence, $[c]=[\hat c]$ .

The same argument, of course, shows that, for a given $[c] \in C_{W}$ , there exists a unique $[b] \in B_{W}$ for which equation (3.1) is solvable. We define $\phi _{W}$ as the function which associates to each $[b] \in B_{W}$ its corresponding $[c] \in C_{W}$ . The fact that the equations represented by equation (3.1) are linear implies that $\phi _{W}$ is linear as well, and hence an isomorphism of $\mathbb {F}_{2}$ -spaces.▪

Proof Choose $\mathcal {A}$ to be an $\mathbb {F}_{2}$ -basis for $\mathscr {A}$ . By the definition of $\mathscr {A}$ , for each $[f] \in \mathcal {A}$ , there exists some $[\gamma _{f}] \in [K^{\times }]$ so that $[N_{K/F}(\gamma _{f})] = [f]$ . We define $M_{[f]} := \langle [\gamma _{f}]\rangle $ , and observe that $M_{[f]} \simeq \mathbb {F}_{2}[G]$ and $M_{[f]}^{G} = \langle [f]\rangle $ . Let $Y_{A} = \sum _{[f]\in \mathcal {A}}M_{[f]}.$ Observe that $Y_{A} = \bigoplus _{[f]\in \mathcal {A}}M_{[f]}$ by Lemma 2.1, and that $Y_{A}^{G} = \bigoplus _{[f] \in \mathcal {A}} \langle [f] \rangle = \langle \mathcal {A} \rangle = \mathscr {A}$ by construction.

Let $\mathcal {V}$ be an $\mathbb {F}_{2}$ -basis for a complement of $\mathscr {A}$ in $\mathscr {V}$ . By definition of $\mathscr {V}$ , for each $[f] \in \mathcal {V}$ , we can choose $[\gamma _{1,f}],[\gamma _{2,f}] \in [K^{\times }]$ so that, for $\{i,j\} = \{1,2\}$ , we have $[\gamma _{i,f}]^{1+\sigma _{i}} = [f]$ and $[\gamma _{i,f}]^{1+\sigma _{j}} = [1]$ . For each $[f] \in \mathcal {V}$ , we define $M_{[f]} := \langle [\gamma _{1,f}],[\gamma _{2,f}]\rangle $ . We claim that $M_{[f]} \simeq \Omega ^{1}$ and that $M_{[f]}^{G} = \langle [f]\rangle $ . By construction, the appropriate $\Omega ^{1}$ -relations are satisfied for $M_{[f]}$ , so we need only check that there are not additional relations. For this, observe that any nontrivial relation among $\{[f],[\gamma _{1,f}],[\gamma _{2,f}]\}$ must involve at least one of $[\gamma _{1,f}]$ or $[\gamma _{2,f}]$ since we know that $[f]$ is nontrivial. On the one hand, if we had a nontrivial relation involving $[\gamma _{1,f}]$ , then an application of $1+\sigma _{1}$ to this relation would tell us that $[f]=[1]$ ; on the other hand, a nontrivial relation involving $[\gamma _{2,f}]$ would tell us that $[f]=[1]$ after an application of $1+\sigma _{2}$ . Hence, our set is independent, and so $M_{[f]} \simeq \Omega ^{1}$ . This gives $M_{[f]}^{G} = \langle [f]\rangle $ as well. Let $Y_{V} = \sum _{[f]\in \mathcal {V}}M_{[f]}.$ Indeed, we have $Y_{V} = \bigoplus _{[f]\in \mathcal {V}}M_{[f]}$ by Lemma 2.1. We also have $Y_{V}^{G} = \bigoplus _{[f] \in \mathcal {V}} M_{[f]}^{G} =\bigoplus _{[f] \in \mathcal {V}} \langle [f] \rangle = \langle \mathcal {V} \rangle $ by construction.

Now, let B be a complement to $\mathscr {V}$ within $\mathscr {B}$ , and let C a complement to $\mathscr {V}$ within $\mathscr {C}$ . Let $B_{W}$ and $C_{W}$ be the subspaces defined in Lemma 3.2. Let $\mathcal {B}_{W}$ be an $\mathbb {F}_{2}$ -basis for $B_{W}$ . For each $[b] \in \mathcal {B}_{W}$ , we know that there exist $[\gamma _{1}],[\gamma _{2}],[\gamma _{3}] \in J(K)$ and $\phi _{W}([b]) =[c]\in C_{W}$ which solve equation (3.1). Let $M_{[b]} = \langle [b],[c],[\gamma _{1}],[\gamma _{2}],[\gamma _{3}]\rangle $ . We claim that $M_{[b]} \simeq \Omega ^{2}$ . Certainly, the appropriate $\Omega ^{2}$ relations hold by construction, so we simply need to ensure that there are no additional relations. The elements $[b]$ and $[c]$ are independent since $[b]$ and $[c]$ are each drawn from a complement to $\mathscr {V} = \mathscr {B} \cap \mathscr {C}$ in their respective spaces. Now, if we had a nontrivial $\mathbb {F}_{2}$ -dependence that involved any of $[\gamma _{1}]$ or $[\gamma _{2}]$ , then an application of $1+\sigma _{1}$ would force a nontrivial $\mathbb {F}_{2}$ -dependence on $[b]$ and $[c]$ , which we have just seen is not possible. Likewise, a nontrivial $\mathbb {F}_{2}$ -dependence that involves $[\gamma _{3}]$ would force a nontrivial $\mathbb {F}_{2}$ -dependence between $[b]$ and $[c]$ . Hence, the set is independent, and so $M_{[b]} \simeq \Omega ^{2}$ . Note this also forces $M_{[b]}^{G} = \langle [b],[c]\rangle = \langle [b],\phi _{W}([b])\rangle $ . Let $Y_{W} = \sum _{[b] \in \mathcal {B}_{W}} M_{[b]}.$ As before, we in fact have $Y_{W} = \bigoplus _{[b] \in \mathcal {B}_{W}} M_{[b]}$ , and furthermore

$$ \begin{align*}Y_{W}^{G} = \bigoplus_{[b] \in \mathcal{B}_{W}} M_{[b]}^{G} = \bigoplus_{[b]\in \mathcal{B}_{W}} \langle [b], \phi_{W}([b]) \rangle = B_{W} \oplus \phi_{W}(B_{W}) = B_{W} \oplus C_{W},\end{align*} $$

by Lemma 3.2.

Let $\mathcal {B}_{0}$ be a basis for a complement to $B_{W}$ within B. Since $B \subseteq \mathscr {B}$ , each $[f] \in \mathcal {B}_{0}$ has some $[\gamma _{f}] \in [K^{\times }]$ so that $[\gamma _{f}]^{1+\sigma _{1}} = [f]$ and $[\gamma _{f}]^{1+\sigma _{2}} = [1]$ . Since $[f] \neq [1]$ , we get $M_{[f]}:=\langle [\gamma _{f}]\rangle $ is isomorphic to $\mathbb {F}_{2}[\overline {G_{1}}]$ , and $M_{[f]}^{G} = \langle [f]\rangle $ . Let $Y_{B} = \sum _{[f] \in \mathcal {B}_{0}}M_{[f]}.$ Lemma 2.1 again gives $Y_{B} = \bigoplus _{[f] \in \mathcal {B}_{0}} M_{[f]}$ , and furthermore we have $Y_{B}^{G} = \bigoplus _{[f] \in \mathcal {B}_{0}} M_{[f]}^{G} = \bigoplus _{[f] \in \mathcal {B}_{0}} \langle [f] \rangle = \langle \mathcal {B}_{0}\rangle $ .

Let $\mathcal {C}_{0}$ be a basis for a complement to $C_{W}$ within C. Since $C \subseteq \mathscr {C}$ , for each $[f] \in \mathcal {C}_{0}$ , there exists some $[\gamma _{f}] \in [K^{\times }]$ so that $[\gamma _{f}]^{1+\sigma _{2}} = [f]$ and $[\gamma _{f}]^{1+\sigma _{1}} = [1]$ . Since $[f] \neq [1]$ , we get $M_{[f]}:=\langle [\gamma _{f}]\rangle $ is isomorphic to $\mathbb {F}_{2}[\overline {G_{2}}]$ , and $M_{[f]}^{G} = \langle [f]\rangle $ . Let $Y_{C} = \sum _{[f] \in \mathcal {C}_{0}}M_{[f]}.$ Once again, we have $Y_{C} = \bigoplus _{[f] \in \mathcal {C}_{0}} M_{[f]}$ by Lemma 2.1, and $Y_{C}^{G} = \bigoplus _{[f] \in \mathcal {C}_{0}} M_{[f]}^{G} = \bigoplus _{[f] \in \mathcal {C}_{0}} \langle [f] \rangle = \langle \mathcal {C}_{0}\rangle $ .

Let $\mathcal {D}_{0}$ be a basis for a complement to $(\mathscr {B}+\mathscr {C}) \cap \mathscr {D}$ within $\mathscr {D}$ . By the definition of $\mathscr {D}$ , for each $[f] \in \mathcal {D}_{0}$ , there exists some $[\gamma _{f}] \in [K^{\times }]$ so that $[\gamma _{f}]^{1+\sigma _{2}} = [\gamma _{f}]^{1+\sigma _{1}} = [f]$ . Since $[f] \neq [1]$ , we get $M_{[f]}:=\langle [\gamma _{f}]\rangle $ is isomorphic to $\mathbb {F}_{2}[\overline {G_{3}}]$ , and $M_{[f]}^{G} = \langle [f]\rangle $ . Let $Y_{D} = \sum _{[f] \in \mathcal {D}_{0}}M_{[f]}.$ Again, we get $Y_{D} = \bigoplus _{[f] \in \mathcal {D}_{0}} M_{[f]}$ , and $Y_{D}^{G} = \bigoplus _{[f] \in \mathcal {D}_{0}} M_{[f]}^{G} = \bigoplus _{[f] \in \mathcal {D}_{0}} \langle [f] \rangle = \langle \mathcal {D}_{0}\rangle $ .

Finally, define $\mathcal {F}_{0}$ to be a basis for a complement to $\mathscr {B}+\mathscr {C}+\mathscr {D}$ within $[F^{\times }]$ . For each $[f] \in \mathcal {F}_{0}$ , we define $M_{[f]} = \langle [f]\rangle $ , which is clearly isomorphic to $\mathbb {F}_{2}$ . We let $Y_{F} = \bigoplus _{[f] \in \mathcal {F}_{0}} M_{[f]}.$

We have already detailed the fixed parts of each submodule, and we will use this to show that the sum is direct. First, recall that $Y_{A}^{G} = \mathscr {A}$ and $Y_{V}^{G} = \langle \mathcal {V}\rangle $ , where $\mathcal {V}$ is chosen to be a complement to $\mathscr {A}$ in $\mathscr {V}$ . Then Lemma 2.1 gives $Y_{A}+Y_{V} = Y_{A}\oplus Y_{V}$ , and additionally we have $(Y_{A}\oplus Y_{V})^{G} = \mathscr {V}$ .

Next, since $Y_{W}^{G} = B_{W}\oplus C_{W}$ —where $B_{W}$ and $C_{W}$ are complements to $\mathscr {V}$ in their respective spaces—Lemma 2.1 gives $(Y_{A} \oplus Y_{V})+Y_{W} = Y_{A} \oplus Y_{V} \oplus Y_{W}$ , and indeed $(Y_{A}\oplus Y_{V} \oplus Y_{W})^{G} = \mathscr {V} \oplus B_{W} \oplus C_{W}$ .

Next, we know that $\mathscr {B} = \mathscr {V} \oplus B_{W} \oplus \langle \mathcal {B}_{0}\rangle $ , and since $Y_{B}^{G} = \langle \mathcal {B}_{0}\rangle $ , this means that $Y_{A}\oplus Y_{V} \oplus Y_{W} + Y_{B} = Y_{A}\oplus Y_{V} \oplus Y_{W} \oplus Y_{B}$ , and $(Y_{A}\oplus Y_{V} \oplus Y_{W} \oplus Y_{B})^{G} = \mathscr {B} \oplus C_{W}$ . Using the facts that $\mathscr {B} \cap \mathscr {C} = \mathscr {V}$ , that $Y_{C}^{G} = \langle \mathcal {C}_{0}\rangle $ , and that $\mathscr {C} = \mathscr {V} \oplus C_{W} \oplus \langle \mathcal {C}_{0} \rangle $ , Lemma 2.1 gives $Y_{A}\oplus Y_{V} \oplus Y_{W} \oplus Y_{B} + Y_{C}= Y_{A} \oplus Y_{V} \oplus Y_{W} \oplus Y_{B} \oplus Y_{C}$ , and $(Y_{A} \oplus Y_{V} \oplus Y_{W} \oplus Y_{B} \oplus Y_{C})^{G} = \mathscr {B}+\mathscr {C}$ .

For the next term, since $Y_{D}^{G} = \langle \mathcal {D}_{0} \rangle $ , where $\mathcal {D}_{0}$ is a complement to $(\mathscr {B}+\mathscr {C})\cap \mathscr {D}$ , Lemma 2.1 gives us $Y_{A}\oplus Y_{V} \oplus Y_{W} \oplus Y_{B} \oplus Y_{C} + Y_{D} = Y_{A} \oplus Y_{V} \oplus Y_{W} \oplus Y_{B} \oplus Y_{C} \oplus Y_{D}$ , and indeed $(Y_{A} \oplus Y_{V} \oplus Y_{W} \oplus Y_{B} \oplus Y_{C} \oplus Y_{D})^{G} = \mathscr {B}+\mathscr {C}+\mathscr {D}$ .

Finally, since $Y_{F}^{G} = \langle \mathcal {F}_{0}\rangle $ , where $\mathcal {F}_{0}$ is a complement to $\mathscr {B}+\mathscr {C}+\mathscr {D}$ in $[F^{\times }]$ , one final application of Lemma 2.1 gives $\widehat {J}^{G} = [F^{\times }]$ and

$$ \begin{align*}\widehat{J} = Y_{A} \oplus Y_{V} \oplus Y_{W} \oplus Y_{B} \oplus Y_{C} \oplus Y_{D} \oplus Y_{F}.\\[-38pt] \end{align*} $$

▪

Proof Suppose first that $[f] \in \mathscr {A}$ . Since $\mathcal {A}$ is a basis for $\mathscr {A}$ , we have $[f] = \prod _{i=1}^{n} [f_{i}]$ for appropriately chosen $[f_{i}] \in \mathcal {A}$ . By construction, there exist $[k_{i}] \in J(K)$ so that $[N_{K/F}(k_{i})]=[f_{i}]$ , and so we get $k = \prod _{i=1}^{n} [k_{i}]$ has $[N_{K/F}(k)] = [f]$ . Hence, the diagram corresponding to $\mathscr {A}$ is solvable for $[f]$ with terms drawn from $\widehat {J}$ .

Now, suppose that $[f] \in \mathscr {B}$ . Since we know $\mathscr {B} = \mathscr {V} \oplus B_{W} \oplus \langle \mathcal {B}_{0}\rangle $ , we can write $[f] = \prod _{i=1}^{n} [f_{i}] \prod _{j=1}^{m} [\widehat {f_{j}}] \prod _{k=1}^{\ell } [\widetilde {f_{k}}]$ , where $f_{i} \in \mathcal {A} \cup \mathcal {V}$ , $\widehat {f_{j}} \in \mathcal {B}_{W}$ , and $\widetilde {f_{k}} \in \mathcal {B}_{0}$ are appropriately chosen. Based on the construction of the terms from $Y_{A}$ , $Y_{V}$ , $Y_{W}$ , and $Y_{B}$ , we have elements $[\gamma _{i}],[\widehat {\gamma _{j}}],[\widetilde {\gamma _{k}}] \in \widehat {J}$ that solve the diagram corresponding to $\mathscr {B}$ . Hence, if we let $[\gamma ] = \prod _{i=1}^{n} [\gamma _{i}] \prod _{j=1}^{m} [\widehat {\gamma _{j}}] \prod _{k=1}^{\ell } [\widetilde {\gamma _{k}}]$ , then the diagram corresponding to $\mathscr {B}$ is solved with $[\gamma ]$ and $[f]$ . An analogous argument settles the case where $[f] \in \mathscr {C}$ .

We have left to settle the statement for $\mathscr {M}=\mathscr {D}$ . This will take a bit more work. Since $\mathcal {D}_{0}$ is a basis for a complement to $(\mathscr {B}+\mathscr {C})\cap \mathscr {D}$ within $\mathscr {D}$ , we can write $[f] = [\hat f] \prod _{i=1}^{n}[f_{i}]$ , where $[\hat f] \in (\mathscr {B}+\mathscr {C})\cap \mathscr {D}$ , and with $[f_{i}] \in \mathcal {D}_{0}$ appropriately chosen. By construction of $Y_{D}$ , for each i, we have an element $[\gamma _{i}]$ so that the diagram for $\mathscr {D}$ is solved with $[\gamma _{i}]$ and $[f_{i}]$ . Furthermore, since $[\hat f] \in (\mathscr {B}+\mathscr {C}) \cap \mathscr {D}$ , Lemma 3.1 tells us that $[\hat f] = [b][c]$ has the property that equation (3.1) is solvable for $[b]$ and $[c]$ :

Since B is a complement to $\mathscr {V}$ in $\mathscr {B}$ and C is a complement to $\mathscr {V}$ in $\mathscr {C}$ , we can write $[b] = [v_{1}][b_{W}]$ and $[c] = [v_{2}][c_{W}]$ for $[v_{1}],[v_{2}] \in \mathscr {V}$ and $[b_{W}] \in B$ and $[c_{W}] \in C$ . For $i \in \{1,2\}$ , the construction of $Y_{A}$ and $Y_{V}$ give $[\widetilde {\gamma _{L,i}}],[\widetilde {\gamma _{R,i}}] \in \widehat {J}$ that accompany $[v_{i}]$ in solving the diagram for $\mathscr {V}$ . Note in particular this means that the diagram corresponding to $\mathscr {D}$ is solved for $[\widetilde {\gamma _{L,i}}][\widetilde {\gamma _{R,i}}]$ and $[v_{i}]$ . We have left to deal with the $[b_{W}]$ and $[c_{W}]$ terms.

From our previous equations, we get

This means that $[b_{W}] \in B_{W}$ , and, by Lemma 3.2, we have $\phi _{W}([b_{W}]) = c_{W} \in C_{W}$ . Hence, $[b_{W}] = \prod _{j=1}^{m} [b_{j}]$ for $[b_{j}]$ appropriately chosen from $\mathcal {B}_{W}$ . By the construction of $Y_{W}$ , we have elements $[\gamma _{1,j}],[\gamma _{2,j}],[\gamma _{3,j}] \in \widehat {J}$ which solve equation (3.1) for $[b_{j}]$ and $\phi _{W}([b_{j}])$ . Hence, $\prod _{j=1}^{m} [\gamma _{1,j}]$ , $\prod _{j=1}^{m}[\gamma _{2,j}]$ , and $\prod _{j=1}^{m} [\gamma _{3,j}]$ solve equation (3.1) for $[b_{W}]$ and $\prod _{j=1}^{m} \phi _{W}([b_{j}]) = \phi _{W}(\prod _{j=1}^{m} [b_{j}]) = [c_{W}]$ . In particular, the equation corresponding to $\mathscr {D}$ is solved by $\prod _{j=1}^{m} [\gamma _{1,j}][\gamma _{2,j}][\gamma _{3,j}]$ and $[b_{W}][c_{W}]$ .

In all, our original element $[f] \in \mathscr {D}$ has now been expressed as $[f] = [\hat f]\prod _{i=1}^{n}[f_{i}] = [b][c] \prod _{i=1}^{n} [f_{i}] = [v_{1}][b_{W}][v_{2}][c_{W}]\prod _{i=1}^{n}[f_{i}]$ , where each of $[v_{1}],[v_{2}],[b_{W}][c_{W}],$ and $\prod _{i=1}^{n}[f_{i}]$ have some corresponding element $[\gamma ] \in \widehat {J}$ which solves the diagram corresponding to $\mathscr {D}$ .▪

Proof We consider the first statement first. Observe that we already know that $\hat \sigma _{2}^{2}$ acts trivially on $\sqrt {a_{1}}$ and $\sqrt {a_{2}}$ , so we only need to determine the action of $\hat \sigma _{2}^{2}$ on $\sqrt {\gamma }$ . For this, note that

$$ \begin{align*}\sqrt{\gamma}^{\hat\sigma_{2}^{2}-1} = \left(\sqrt{\gamma}^{\hat \sigma_{2}+1}\right)^{\hat \sigma_{2}-1} = \left(\pm\sqrt{\gamma^{\sigma_{2}+1}}\right)^{\hat \sigma_{2}-1}.\end{align*} $$

Since $[\gamma ] \in J(K)^{G}$ , we have that $[\gamma ]^{\sigma _{2}+1} = [N_{K/K_{1}}(\gamma )]=[1]$ . Hence, we have $N_{K/K_{1}}(\gamma ) \in K_{1}^{\times } \cap K^{\times 2}$ , and, by Kummer theory, this means that $N_{K/K_{1}}(\gamma ) = a_{2}^{\varepsilon }k_{1}^{2}$ for some $\varepsilon \in \{0,1\}$ and $k_{1} \in K_{1}^{\times }$ . Note that $\varepsilon = 0$ if and only if $N_{K/K_{1}}(\gamma ) \in K_{1}^{\times 2}$ , which is equivalent to $[N_{K/K_{1}}(\gamma )]_{1} = [1]_{1}$ . Hence, our previous calculation continues

$$ \begin{align*}\sqrt{\gamma}^{\hat\sigma_{2}^{2}-1} = \left(\pm \sqrt{a_{2}}^{\varepsilon}k_{1}\right)^{\hat \sigma_{2}-1} = \left(\pm \sqrt{a_{2}}^{\varepsilon}k_{1}\right)^{\sigma_{2}-1} = (-1)^{\varepsilon}.\end{align*} $$

This gives the desired result.

Similar calculations give the other two results.▪

Proof Observe first that since $[N_{K/F}(\gamma )] = [1]$ , Kummer theory tells us that $[N_{K/F}(\gamma )]_{F} \in \{[1]_{F},[a_{1}]_{F},[a_{2}]_{F},[a_{1}a_{2}]_{F}\}$ . So let us write $N_{K/F}(\gamma ) = f^{2} a_{1}^{\varepsilon _{1}}a_{2}^{\varepsilon _{2}}$ . The result then follows from the following calculations:

$$ \begin{align*} [N_{K/K_{1}}(N_{K/K_{1}}(\gamma))]_{1} &= [N_{K/K_{1}}(\gamma)^{2}]_{1} = [1]_{1},\\ [N_{K/K_{2}}(N_{K/K_{1}}(\gamma))]_{2} &= [N_{K/F}(\gamma)]_{2} = [f^{2}a_{1}^{\varepsilon_{1}}a_{2}^{\varepsilon_{2}}]_{2} = [a_{1}]_{2}^{\varepsilon_{1}},\\ [N_{K/K_{3}}(N_{K/K_{1}}(\gamma))]_{3} &= [N_{K/F}(\gamma)]_{3} = [f^{2}a_{1}^{\varepsilon_{1}}a_{2}^{\varepsilon_{2}}]_{3} = [a_{1}]_{3}^{\varepsilon_{1}+\varepsilon_{2}},\\ [N_{K/K_{1}}(N_{K/K_{2}}(\gamma))]_{1} &= [N_{K/F}(\gamma)]_{1} = [f^{2}a_{1}^{\varepsilon_{1}}a_{2}^{\varepsilon_{2}}]_{1} = [a_{2}]_{1}^{\varepsilon_{2}},\\ [N_{K/K_{2}}(N_{K/K_{2}}(\gamma))]_{2} &= [N_{K/K_{2}}(\gamma)^{2}]_{2} = [1]_{2},\\ [N_{K/K_{3}}(N_{K/K_{2}}(\gamma))]_{3} &= [N_{K/F}(\gamma)]_{3} = [f^{2}a_{1}^{\varepsilon_{1}}a_{2}^{\varepsilon_{2}}]_{3} = [a_{1}]_{3}^{\varepsilon_{1}+\varepsilon_{2}}.\\[-36pt] \end{align*} $$

▪

Proof We proceed by cases. If $\langle [\gamma ]\rangle \simeq \mathbb {F}_{2}[\overline {G_{1}}]$ , then we have $[\gamma ]^{1+\sigma _{2}} = [1]$ , so that $[N_{K/F}(\gamma )] = [1]$ . Since $\langle [\gamma ]\rangle ^{G} = \langle [\gamma ]^{1+\sigma _{1}}\rangle $ , in this case, our objective is to show that $T([\gamma ]^{1+\sigma _{1}}) = (1,1,1)$ . But since $[\gamma ]^{1+\sigma _{1}} = [N_{K/K_{2}}(\gamma )]$ , the previous lemma tells us that if we have $T([\gamma ]^{1+\sigma _{1}}) \neq (1,1,1)$ , then we have $(1,1,1) \neq T([N_{K/K_{1}}(\gamma )]) = T([\gamma ]^{1+\sigma _{2}}) = T([1])$ as well, a contradiction. The same argument gives the result for $i=2$ .

For $i=3$ , a variation on this argument works: we know we have $[N_{K/K_{1}}(\gamma )] = [N_{K/K_{2}}(\gamma )]$ , and yet the lemma above provides no nontrivial case in which $T([N_{K/K_{1}}(\gamma )]) = T([N_{K/K_{2}}(\gamma )])$ .▪

Proof Our approach will be to argue that the appearance of these elements in the image of T guarantees the solvability of certain embedding problems, from which we deduce the solvability of certain equations involving norms.

We first handle the case where $\mathrm {im}(T)$ contains $\{(1,a_{1},a_{1}),(1,1,a_{1})\}$ . Since $T([x]) = (1,a_{1},a_{1})$ , we know from Lemma 4.1 that in $K(\sqrt {x})/F$ the generators $\sigma _{1},\sigma _{2} \in \mathrm {Gal}(K/F)$ extend to elements $\hat \sigma _{1},\hat \sigma _{2} \in \mathrm {Gal}(K(\sqrt {x})/F)$ which satisfy the relations

$$ \begin{align*}\hat\sigma_{2}^{2} = \hat \sigma_{1}^{4} = (\hat\sigma_{1}\hat\sigma_{2})^{4} = \text{id}.\end{align*} $$

Hence, $\mathrm {Gal}(K(\sqrt {x})/F)\twoheadrightarrow \mathrm {Gal}(K/F)$ solves the embedding problem $\mathbb {Z}/4\mathbb {Z}\oplus \mathbb {Z}/2\mathbb {Z} \twoheadrightarrow \mathbb {Z}/2\mathbb {Z}\oplus \mathbb {Z}/2\mathbb {Z}$ , and in particular $K_{1}/F$ embeds in a cyclic extension of degree $4$ . By [Reference Albert2, Theorem 3], we have $-1\in N_{K_{1}/F}(K_{1}^{\times })$ ; since we have $-a_{1} = (\sqrt {a_{1}})^{1+\sigma _{1}}=N_{K_{1}/F}(\sqrt {a_{1}})$ , it therefore follows that $a_{1} \in N_{K_{1}/F}(K_{1}^{\times })$ , say $a_{1} = N_{K_{1}/F}(k_{1})$ for $k_{1} \in K_{1}^{\times }$ .

On the other hand, since $T([y]) = (1,1,a_{1})$ , we know from Lemma 4.1 that the generators $\sigma _{1},\sigma _{2} \in \mathrm {Gal}(K/F)$ extend to elements $\tilde \sigma _{1},\tilde \sigma _{2} \in \mathrm {Gal}(K(\sqrt {y})/F)$ that satisfy

$$ \begin{align*}\tilde\sigma_{2}^{2}=\tilde\sigma_{1}^{2} = (\tilde\sigma_{1}\tilde\sigma_{2})^{4} = \text{id}.\end{align*} $$

From this, we see that $\mathrm {Gal}(K(\sqrt {y})/F) \twoheadrightarrow \mathrm {Gal}(K/F)$ solves the embedding problem $D_{4} \twoheadrightarrow \mathbb {Z}/2\mathbb {Z}\oplus \mathbb {Z}/2\mathbb {Z}$ , where the kernel of the latter surjection is $\langle (\tilde \sigma _{1}\tilde \sigma _{2})^{2}\rangle $ . By a well-known result for the solvability of such embedding problems (see, e.g., [Reference Jensen and Yui16, Proposition III.3.3]), we therefore have $a_{1} \in N_{K_{2}/F}(K_{2}^{\times })$ , say $a_{1} = N_{K_{2}/F}(k_{2})$ for $k_{2} \in K_{2}^{\times }$ .

By [Reference Wadsworth30, Lemma 2.14], there exists some $\gamma \in K^{\times }$ and $f \in F^{\times }$ so that $N_{K/K_{1}}(\gamma ) = fk_{1}$ and $N_{K/K_{2}}(\gamma ) = fk_{2}$ . In particular, we have $[N_{K/F}(\gamma )]_{F} = [f^{2}a_{1}]_{F} = [a_{1}]_{F}$ . An application of Lemma 4.4 finishes this case.

The second case is effectively identical to the first. For the last case, note that the images we are given provide two $D_{4}$ -extensions over $K/F$ , one in which $\sigma _{1}$ extends to an element of order $4$ , and another where $\sigma _{2}$ extends to an element of order $4$ . In the former case, we then get $a_{1}a_{2} \in N_{K_{2}/F}(K_{2}^{\times })$ , and in the latter, we get $a_{1}a_{2} \in N_{K_{1}/F}(K_{1}^{\times })$ . From here, the proof proceeds as before.▪

Proof We proceed by cases based on $\dim (\mathrm {im}(T))$ . First, if $\dim (\mathrm {im}(T)) = 1$ , then let $[x] \in J(K)^{G}$ be given so that $T([x]) \neq (1,1,1)$ . Then $X:=\langle [x]\rangle $ has the desired properties.

Now, suppose that $\dim (\mathrm {im}(T)) = 2$ . By Lemma 4.6, we know that if $\mathrm {im}(T)$ is any of

$$ \begin{align*} \langle (1,a_{1},a_{1}),(1,1,a_{1})\rangle &= \{(1,w,z):w \in (K_{2}^{\times}\cap K^{\times 2})/K_{2}^{\times 2},z \in (K_{3}^{\times} \cap K^{\times 2})/K_{3}^{\times 2}\},\\ \langle (1,1,a_{1}),(a_{2},1,a_{1})\rangle &= \{(w,1,z):w \in (K_{1}^{\times}\cap K^{\times 2})/K_{1}^{\times 2},z \in (K_{3}^{\times} \cap K^{\times 2})/K_{3}^{\times 2}\}\text{, or}\\ \langle (1,a_{1},1),(a_{1},1,1)\rangle &= \{(w,z,1):w \in (K_{1}^{\times}\cap K^{\times 2})/K_{1}^{\times 2},z \in (K_{2}^{\times} \cap K^{\times 2})/K_{2}^{\times 2}\}, \end{align*} $$

then we can find some $[\gamma ] \in J(K)$ with $[N_{K/F}(\gamma )]=[1]$ so that $\left \langle T\left ([N_{K/K_{1}}(\gamma )]\right ),T\left ([N_{K/K_{2}}(\gamma )]\right )\right \rangle = \mathrm {im}(T)$ . It is easy to see that $X:=\langle [\gamma ]\rangle \simeq \Omega ^{-1}$ , and since the nontrivial fixed elements in this module have nontrivial images under T, we get $X^{G} \cap [F^{\times }] = \{[1]\}$ .

On the other hand, if $\dim (\mathrm {im}(T)) = 2$ but $\mathrm {im}(T)$ is none of the three subspaces above, then let $[x_{1}],[x_{2}] \in J(K)^{G}$ be given so that $\{T([x_{1}]),T([x_{2}])\}$ forms a basis for $\mathrm {im}(T)$ ; we then set $X:=\langle [x_{1}],[x_{2}]\rangle \simeq \mathbb {F}_{2}\oplus \mathbb {F}_{2}$ , with $X \cap [F^{\times }] = \{[1]\}$ .

Now, suppose that $\dim (\mathrm {im}(T)) = 3$ . First, consider the case where $T([N_{K/K_{1}}(K^{\times })]\cap [N_{K/K_{2}}(K^{\times })]) \neq \{(1,1,1)\}$ , and let $[x]$ be given so that $[N_{K/K_{1}}(\gamma _{2})] = [x] = [N_{K/K_{2}}(\gamma _{1})]$ for some $[\gamma _{1}],[\gamma _{2}] \in J(K)$ and with $T([x]) \neq (1,1,1)$ . (Note that since $[x]$ is in the image of $N_{K/K_{1}}$ and $N_{K/K_{2}}$ , it is automatically in $J(K)^{G}$ ; hence, it makes sense to evaluate its image under T.) Lemma 4.4 tells us that $T([x]) = (1,1,a_{1})$ , and furthermore that $T([N_{K/K_{1}}(\gamma _{1})]) = (1,a_{1},a_{1})$ and $T([N_{K/K_{2}}(\gamma _{2})]) = (a_{2},1,a_{1})$ . We claim that $X:=\langle [\gamma _{1}],[\gamma _{2}]\rangle \simeq \Omega ^{-2}$ ; certainly, the appropriate relations hold, so we only need to check that the module is five-dimensional. Note that $\{[N_{K/K_{1}}(\gamma _{1})],[x],[N_{K/K_{2}}(\gamma _{2})]\}$ must be independent since their images under T are independent, and hence any nontrivial dependence must involve $[\gamma _{1}]$ or $[\gamma _{2}]$ . However, an application of $1+\sigma _{1}$ (or $1+\sigma _{2}$ ) to such a relation creates a nontrivial relation among $\{[N_{K/K_{1}}(\gamma _{1})],[x],[N_{K/K_{2}}(\gamma _{2})]\}$ , contrary to their independence. Since we have $X \simeq \Omega ^{-2}$ , we get $X^{G} = \langle [N_{K/K_{1}}(\gamma _{1})],[x],[N_{K/K_{2}}(\gamma _{2})]\rangle $ , whence $X^{G} \cap [F^{\times }] = \{[1]\}$ .

Alternatively, suppose that $\dim (\mathrm {im}(T)) = 3$ , but $T([N_{K/K_{1}}(K^{\times }) \cap [N_{K/K_{2}}(K^{\times })]) = \{(1,1,1)\}$ . Lemma 4.6 gives us elements $[\gamma _{1}],[\gamma _{2}] \in J(K)$ so that

$$ \begin{align*} T([N_{K/K_{1}}(\gamma_{1})])&=(1,a_{1},a_{1}),\\ T([N_{K/K_{2}}(\gamma_{1})])&=(1,1,a_{1}) = T([N_{K/K_{1}}(\gamma_{2})]),\\ T([N_{K/K_{2}}(\gamma_{2})])&=(a_{2},1,a_{1}). \end{align*} $$

We define $X = \langle [\gamma _{1}],[\gamma _{2}]\rangle $ . One sees that $\langle [\gamma _{1}]\rangle \simeq \langle [\gamma _{2}]\rangle \simeq \Omega ^{-1}$ in the same manner as above (these modules satisfy the appropriate relations by definition, and one can argue they generate a module of the appropriate dimension by leveraging the independence of the image of their fixed components under T). We claim that $X \simeq \Omega ^{-1}\oplus \Omega ^{-1}$ ; for the sake of contradiction, then, assume instead that $\langle [\gamma _{1}]\rangle \cap \langle [\gamma _{2}]\rangle \neq \{[1]\}$ . By Lemma 2.1, this implies that there is some $[x]\neq [1]$ with $[x] \in \langle [\gamma _{1}]\rangle ^{G} \cap \langle [\gamma _{2}]\rangle ^{G} $ . Considering images under T and using Lemma 4.4, we must have $[N_{K/K_{2}}(\gamma _{1})] = [x] = [N_{K/K_{1}}(\gamma _{2})]$ , contrary to the assumption in this case that $T([N_{K/K_{1}}(K^{\times })] \cap [N_{K/K_{2}}(K^{\times })]) = \{(1,1,1)\}$ . Hence, we get $X \simeq \Omega ^{-1} \oplus \Omega ^{-1}$ .

Finally, we check that $\dim (X^{G} \cap [F^{\times }]) = 1$ with $X^{G} \cap (\mathscr {B}+\mathscr {C}+\mathscr {D}) = \{[1]\}$ . The former follows from the rank-nullity theorem applied to the function T; in fact, we see that $X^{G} \cap [F^{\times }] = \{[1],[N_{K/K_{2}}(\gamma _{1})][N_{K/K_{1}}(\gamma _{2})]\}$ . For the latter, suppose instead that $[N_{K/K_{2}}(\gamma _{1})][N_{K/K_{1}}(\gamma _{2})] \in \mathscr {B}+\mathscr {C}+\mathscr {D}$ . Then we get $[N_{K/K_{2}}(\gamma _{1})][N_{K/K_{1}}(\gamma _{2})] = [f_{\mathscr {B}}][f_{\mathscr {C}}][f_{\mathscr {D}}]$ for some $[f_{\mathscr {B}}]\in \mathscr {B},[f_{\mathscr {C}]}\in \mathscr {C}$ and $[f_{\mathscr {D}}]\in \mathscr {D}$ ; in particular, this means we have elements $[\gamma _{\mathscr {B}}],[\gamma _{\mathscr {C}}],[\gamma _{\mathscr {D}}] \in J(K)$ which solve the relevant diagrams from Figure 4. One can then check that

$$ \begin{align*} N_{K/K_{1}}([\gamma_{2}][\gamma_{\mathscr{C}}]) &= [N_{K/K_{1}}(\gamma_{2})][f_{\mathscr{C}}] = [N_{K/K_{2}}(\gamma_{1})][f_{\mathscr{B}}][f_{\mathscr{D}}] \\&= N_{K/K_{2}}([\gamma_{1}][\gamma_{\mathscr{B}}][\gamma_{\mathscr{D}}]). \end{align*} $$

This element is conspicuously an element in $[N_{K/K_{1}}(K^{\times })] \cap [N_{K/K_{2}}(K^{\times })]$ , and since $\ker (T) = [F^{\times }]$ , we get that $T([N_{K/K_{2}}(\gamma _{1})][f_{\mathscr {B}}][f_{\mathscr {D}}]) = T([N_{K/K_{2}}(\gamma _{1})]) \neq \{(1,1,1)\}$ . This runs contrary to the overriding assumption in this case, that $T([N_{K/K_{1}}(K^{\times })] \cap [N_{K/K_{2}}(K^{\times })]) = \{(1,1,1)\}$ .▪

Proof We prove the result when $\ell = 3$ , $m = 1$ , and $n=2$ ; the other results follow by the symmetry of the fields $K_{1},K_{2}$ , and $K_{3}$ .

First, we argue that if $f \in F^{\times }$ has $[f] \in [N_{K/K_{3}}(K^{\times })]$ , then

(5.1) $$ \begin{align}\frac{f}{a_{1}^{\varepsilon}} = N_{K/K_{3}}(\tilde k)\end{align} $$

for some $\tilde k \in K^{\times }$ and $\varepsilon \in \{0,1\}$ . To see this, note that $f = k^{1+\sigma _{1} \sigma _{1}} \hat k^{2}$ for some $k,\hat k \in K$ . Solving for $\hat k^{2}$ and using the fact that $F \subseteq K_{3}$ , we then have $\hat k^{2} \in K_{3}$ . However, this means $\hat k^{2} \in K^{\times 2} \cap K_{3}^{\times }$ , so by Kummer theory, we get $\hat k^{2}=k_{3}^{2} a_{1}^{\varepsilon }$ , where $k_{3} \in K_{3}^{\times }$ and $\varepsilon \in \{0,1\}$ . Naturally, we have $k_{3}^{2} = N_{K/K_{3}}(k_{3})$ , so that our original expression becomes

$$ \begin{align*}f = k^{1+\sigma_{1}\sigma_{2}}\hat k^{2} = k^{1+\sigma_{1}\sigma_{2}} k_{3}^{2}a_{1}^{\varepsilon} = N_{K/K_{3}}(kk_{3}) a_{1}^{\varepsilon}.\end{align*} $$

Setting $\tilde k = k k_{3}$ and dividing through by $a_{1}^{\varepsilon }$ gives equation (5.1).

Now, we argue that

(5.2) $$ \begin{align}F^{\times} \cap N_{K/K_{3}}(K^{\times}) \subseteq N_{K_{1}/F}(K_{1}^{\times}) \cdot N_{K_{2}/F}(K_{2}^{\times}).\end{align} $$

For this, suppose that we have elements $g \in F^{\times }$ and $k \in K^{\times }$ so that $g = N_{K/K_{3}}(k)$ . Now, $k = f_{1} +f_{2}\sqrt {a_{1}}+f_{3}\sqrt {a_{2}}+f_{4}\sqrt {a_{1}a_{2}}$ for some $f_{1},f_{2},f_{3},f_{4} \in F^{\times }$ , and so by assumption we get

$$ \begin{align*}g = N_{K/K_{3}}(k) = (f_{1}^{2}-a_{1}f_{2}^{2}-a_{2}f_{3}^{2}+a_{1}a_{2}f_{4}^{2}) + \sqrt{a_{1}a_{2}}(2f_{1}f_{4}-2f_{2}f_{3}).\end{align*} $$

However, since $g \in F^{\times }$ , we must have $f_{1}f_{4} = f_{2}f_{3}$ . Our goal is to write g as an element of $N_{K_{1}/F}(K_{1}^{\times })\cdot N_{K_{2}/F}(K_{2}^{\times })$ , which means we would like to find $h_{1},h_{2},h_{3},h_{4} \in F$ so that $h_{1} +h_{2} \sqrt {a_{1}} \in K_{1}$ and $h_{3}+h_{4}\sqrt {a_{2}} \in K_{2}$ yield

$$ \begin{align*}g = N_{K_{1}/F}(h_{1}+h_{2}\sqrt{a_{1}}) \cdot N_{K_{2}/F}(h_{3}+h_{4}\sqrt{a_{2}}) = (h_{1}^{2}-h_{2}^{2}a_{1})(h_{3}^{2}-h_{4}^{2} a_{2}).\end{align*} $$

In other words, we need to solve

$$ \begin{align*}f_{1}^{2}-a_{1}f_{2}^{2}-a_{2}f_{3}^{2}+a_{1}a_{2}f_{4}^{2} = (h_{1}^{2}-h_{2}^{2}a_{1})(h_{3}^{2}-h_{4}^{2} a_{2}).\end{align*} $$

We proceed by cases. First, suppose that $f_{1}=0$ . Hence, we must have either $f_{2} = 0$ or $f_{3} = 0$ . Note if $f_{2} = 0$ , then our expression for g becomes

$$ \begin{align*}g = -a_{2}f_{3}^{2}+a_{1}a_{2}f_{4}^{2} = (f_{3}^{2}-f_{4}^{2}a_{1})(0^{2}-1^{2} a_{2}).\end{align*} $$

A similar computation settles the case where $f_{3} = 0$ . So now suppose that $f_{1} \neq 0$ , and observe that since $f_{4} = \frac {f_{2}f_{3}}{f_{1}}$ , we have

$$ \begin{align*}f_{1}^{2}-f_{2}^{2} a_{1} - f_{3}^{2} a_{2}+f_{4}^{2} a_{1}a_{2} = \left(f_{1}^{2}-f_{2}^{2} a_{1}\right)\left(1^{2}-\frac{f_{3}^{2}}{f_{1}^{2}}a_{2}\right).\end{align*} $$

With both (5.1) and (5.2) in hand, we can prove the lemma. If we apply (5.2) to $\frac {f}{a_{1}^{\varepsilon }}$ from (5.1), then we see that

$$ \begin{align*}\frac{f}{a_{1}^{\varepsilon}} \in N_{K_{1}/F}(K_{1}^{\times}) \cdot N_{K_{2}/F}(K_{2}^{\times}).\end{align*} $$

However, since $[a_{1}]=[1]$ , we get the desired result.▪

Proof Let $\widehat {J}\, $ be the module from Theorem 3.3, and let X be the module from Theorem 4.8.

If we are not in the case where $\dim (\mathrm {im}(T)) = 3$ and $T([N_{K/K_{1}}(K^{\times })] \cap [N_{K/K_{2}}(K^{\times })]) = \{(1,1,1)\}$ , then define $\widetilde {J} = \widehat {J}$ . Otherwise, note that, in the final case of Theorem 4.8, we have a unique $[x_{0}] \in X^{G} \cap [F^{\times }]$ , and that $[x_{0}] \not \in \mathscr {B}+\mathscr {C}+\mathscr {D}$ . Now, in the construction of $\widehat {J}$ , the summand $Y_{F}$ is chosen as the span of $\mathcal {F}_{0}$ , where $\mathcal {F}_{0}$ is an arbitrary basis for a complement of $\mathscr {B}+\mathscr {C}+\mathscr {D}$ within $[F^{\times }]$ (see the definition of $\mathcal {F}_{0}$ in Theorem 3.3). Since $[x_{0}] \in [F^{\times }] \setminus (\mathscr {B}+\mathscr {C}+\mathscr {D})$ , we can assume that $[x_{0}] \in \mathcal {F}_{0}$ . In this case, we define $\tilde Y_{F} = \sum _{[f] \in \mathcal {F}_{0}\setminus \{[x_{0}]\}} \langle [f]\rangle = \bigoplus _{[f] \in \mathcal {F}_{0}\setminus \{[x_{0}]\}} \langle [f] \rangle $ , and set

$$ \begin{align*}\widetilde{J} = Y_{A}+Y_{V}+Y_{W}+Y_{B}+Y_{C}+Y_{D}+\tilde Y_{F} = Y_{A}\oplus Y_{V} \oplus Y_{W} \oplus Y_{B}\oplus Y_{C}\oplus Y_{D}\oplus \tilde Y_{F}.\end{align*} $$

(That is, the module $\widetilde {J}$ is just the result of removing the summand $\langle [x_{0}]\rangle $ from $\widehat {J}$ .)

In either case, we will show that $J(K) = \widetilde {J} \oplus X$ . Of course, we have $\widetilde {J} + X \subseteq J(K)$ ; furthermore, our construction of $\widetilde {J}$ gives $X^{G} \cap \widetilde {J} = \{[1]\}$ , so that $\widetilde {J} + X = \widetilde {J} \oplus X$ . Hence, we only need to verify that $J(K) \subseteq \widetilde {J} + X$ . We do this by examining the possible isomorphism classes for $\langle [\gamma ]\rangle $ , where $[\gamma ] \in J(K)$ .

First, suppose that $\langle [\gamma ]\rangle \simeq \mathbb {F}_{2}$ , so that $[\gamma ] \in J(K)^{G}$ . If $[\gamma ] \in [F^{\times }]$ , then since $[F^{\times }] = \widehat {J}^{G} \subseteq \widetilde {J}^{G} \oplus X^{G}$ , we have $[\gamma ] \in \widetilde {J}+X$ . Otherwise, we have $T([\gamma ]) \neq (1,1,1)$ , in which case by Theorem 4.8 there exists some $[x] \in X^{G}$ with $T([\gamma ]) = T([x])$ . We then have $[\gamma ][x] \in [F^{\times }]$ , and from the previous case, this gives $[\gamma ][x] \in \widetilde {J}+X$ . Since $[x] \in \widetilde {J}+X$ , we get $[\gamma ] \in \widetilde {J}+X$ .

Now, suppose that $\langle [\gamma ] \rangle \simeq \mathbb {F}_{2}[\overline {G_{1}}]$ . Corollary 4.5 tells us that $[\gamma ]^{1+\sigma _{1}} \in [F^{\times }]$ , and so $[\gamma ]^{1+\sigma _{1}} \in \mathscr {B}$ . Corollary 3.4 tells us that there exists some $[\tilde \gamma ] \in \widehat {J}$ so that $[\tilde \gamma ]^{1+\sigma _{2}} = [1]$ and $[\tilde \gamma ]^{1+\sigma _{1}} = [\gamma ]^{1+\sigma _{1}}$ ; in fact, since $\widehat {J}$ and $\widetilde {J}$ differ by only a trivial summand, we can assume $[\tilde \gamma ] \in \widetilde {J}$ as well. However, then, we get $[\gamma ][\tilde \gamma ] \in J(K)^{G}$ , so by the previous case we have $[\gamma ][\tilde \gamma ] \in \widetilde {J}+X$ . Since $[\tilde \gamma ] \in \widetilde {J}+X$ already, this gives $[\gamma ] \in \widetilde {J}+X$ .

The cases where $\langle [\gamma ] \rangle $ is isomorphic to either $\mathbb {F}_{2}[\overline {G_{2}}]$ or $\mathbb {F}_{2}[\overline {G_{3}}]$ follow the same argument as the case $\mathbb {F}_{2}[\overline {G_{1}}]$ above.

Now, suppose that $\langle [\gamma ]\rangle \simeq \Omega ^{-1}$ , and first consider the case where $T(\langle [\gamma ]\rangle ^{G}) = \{(1,1,1)\}$ . By Corollary 4.2 and Lemma 5.1, we have $[N_{K/K_{1}}(\gamma )] \in [N_{K/K_{1}}(K^{\times })] \cap [F^{\times }] = [N_{K_{2}/F}(K_{2}^{\times })][N_{K_{3}/F}(K_{3}^{\times })]$ , say $[N_{K/K_{1}}(\gamma )] = [f_{1,2}][f_{1,3}]$ , where for $i \in \{2,3\}$ we have $[f_{1,i}] = [N_{K_{i}/F}(k_{i})]$ for some $k_{i} \in K_{i}^{\times }$ . This means that $[f_{1,2}] \in \mathscr {C}$ and $[f_{1,3}] \in \mathscr {D}$ , so by Corollary 3.4 there exists $[\gamma _{1,i}] \in \widehat {J}$ with $[\gamma _{1,i}]$ and $[f_{1,i}]$ providing a solution to the appropriate diagram; since $\widehat {J}$ and $\widetilde {J}$ differ only by a trivial summand, we can assume that $[\gamma _{1,i}] \in \widetilde {J}$ for $i \in \{2,3\}$ . (See Figure 5 for a graphical description of these relationships.)

Figure 5: Decomposing $[N_{K/K_{1}}(\gamma )]$ in terms of solutions to the diagrams for $\mathscr {C}$ and $\mathscr {D}$ .

Consider the element $[\tilde \gamma ] = [\gamma ][\gamma _{1,2}][\gamma _{1,3}]$ . One sees that $[\tilde \gamma ]^{1+\sigma _{2}} = [1]$ , and that $[\tilde \gamma ]^{1+\sigma _{1}} = [N_{K/K_{2}}(\gamma )][f_{1,3}]$ . Hence, $\langle [\tilde \gamma ] \rangle $ is isomorphic to either $\{[1]\}$ or $\mathbb {F}_{2}$ or $\mathbb {F}_{2}[\overline {G_{1}}]$ . Our previous cases, therefore, allow us to conclude $[\tilde \gamma ] \in \widetilde {J}+X$ . Since $[\gamma _{1,2}],[\gamma _{1,3}] \in \widetilde {J}$ , we have $[\gamma ] \in \widetilde {J}+X$ .

If $T(\langle [\gamma ]\rangle ^{G}) \neq \{(1,1,1)\}$ , then Lemma 4.4 gives us that precisely one of the following holds:

• • $T([N_{K/K_{1}}(\gamma )]) = (1,a_{1},a_{1})$ and $T([N_{K/K_{2}}(\gamma )]) = (1,1,a_{1})$ ; or

• • $T([N_{K/K_{1}}(\gamma )]) = (1,1,a_{1})$ and $T([N_{K/K_{2}}(\gamma )]) = (a_{2},1,a_{1})$ ; or

• • $T([N_{K/K_{1}}(\gamma )]) = (1,a_{1},1)$ and $T([N_{K/K_{2}}(\gamma )]) = (a_{2},1,1)$ .

In any of these cases, our construction for X (see the second case in Theorem 4.8) gives an element $[x] \in X$ so that $T([N_{K/K_{1}}(\gamma )]) = T([N_{K/K_{1}}(x)])$ and $T([N_{K/K_{2}}(\gamma )]) =T([N_{K/K_{2}}(x)])$ . Hence, the images of $[\gamma ][x]$ under $1+\sigma _{1}$ and $1+\sigma _{2}$ both lie in $[F^{\times }]$ , and so $\langle [\gamma ][x] \rangle $ falls into one of the previous cases. (For example, if $([\gamma ][x])^{1+\sigma _{1}}$ and $([\gamma ][x])^{1+\sigma _{2}}$ are independent, then $\langle [\gamma ][x]\rangle \simeq \Omega ^{-1}$ and $T(\langle [\gamma ][x]\rangle ^{G})=\{(1,1,1)\}$ . This is precisely the previous case.) We therefore get $[\gamma ][x] \in \widetilde {J}+X$ , whence $[\gamma ] \in \widetilde {J}+X$ .

The final case to consider is when $\langle [\gamma ]\rangle \simeq \mathbb {F}_{2}[G]$ . In this case, note that $[N_{K/F}(\gamma )] \in \mathscr {A}$ , and Corollary 3.4 gives us some element $[\tilde \gamma ] \in \widehat {J}$ (which we may assume is in $\widetilde {J}$ since $\widetilde {J}$ and $\widehat {J}$ differ only by a trivial summand) so that $[N_{K/F}(\tilde \gamma )] = [N_{K/F}(\gamma )]$ . From this, we get that $\langle [\gamma ][\tilde \gamma ]\rangle $ is not free, and so is one of the previous isomorphism types. As usual, this gives us $[\gamma ] \in \widetilde {J}+X$ .▪