In the mathematical field of group theory, the transfer defines, given a group G and a subgroup H of finite index, a group homomorphism from G to the abelianization of H. It can be used in conjunction with the Sylow theorems to obtain certain numerical results on the existence of finite simple groups.
The transfer was defined by and rediscovered by .
The construction of the map proceeds as follows:[1] Let [''G'':''H''] = n and select coset representatives, say
x1,...,xn,
G=cup xiH.
yxi=xjhi
| n | |
| style\prod | |
| i=1 |
hi
It is straightforward to show that, though the individual hi depends on the choice of coset representatives, the value of the transfer does not. It is also straightforward to show that the mapping defined this way is a homomorphism.
If G is cyclic then the transfer takes any element y of G to y[''G'':''H''].
A simple case is that seen in the Gauss lemma on quadratic residues, which in effect computes the transfer for the multiplicative group of non-zero residue classes modulo a prime number p, with respect to the subgroup . One advantage of looking at it that way is the ease with which the correct generalisation can be found, for example for cubic residues in the case that p - 1 is divisible by three.
This homomorphism may be set in the context of group homology. In general, given any subgroup H of G and any G-module A, there is a corestriction map of homology groups
Cor:Hn(H,A)\toHn(G,A)
i:H\toG
Res:Hn(G,A)\toHn(H,A)
A=Z
Res:H1(G,Z)\toH1(H,Z)
H1(G,Z)
G/G'
G'
G\xrightarrow{\pi}G/G'\xrightarrow{Res
\pi
The name transfer translates the German Verlagerung, which was coined by Helmut Hasse.
If G is finitely generated, the commutator subgroup G′ of G has finite index in G and H=G′, then the corresponding transfer map is trivial. In other words, the map sends G to 0 in the abelianization of G′. This is important in proving the principal ideal theorem in class field theory.[3] See the Emil Artin-John Tate Class Field Theory notes.