Does Mapping Induced by Group Homomorphism Preserve Normal Subgroups?

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SUMMARY

The discussion centers on the preservation of normal subgroups under group homomorphisms, specifically examining the mapping induced by a homomorphism f: G -> G'. It establishes that if f(H) is a subset of H', then a natural homomorphism f*: (G/H) -> (G'/H') can be defined. The participant demonstrated that f(H) is a normal subgroup of f(G) and attempted to construct the homomorphism but encountered issues with the mapping to the correct target group. The conversation emphasizes the importance of the normality conditions of H and H' in the context of algebraic topology.

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Homework Statement


Let G and G' be groups. Let H and H' be normal subgroups of G and G' respectively. Let
f:G->G' be a group homomorphism.

Show that if f(H) is a subset of H', then there exists a natural homomorphism f*:(G/H)->(G'/H'). (Hint: This fact is used constatntly in algebraic topology.)


Homework Equations


If X is a normal subgroup of a group Y, then the factor group Y/X can be formed where the group operation is coset multiplication.


The Attempt at a Solution


Using the assumptions that H is normal in G, I showed that f(H) is a normal subgroup of f(G).

I formed the factor group f(G)/f(H) and defined a function f*:(G/H)->(f(G)/f(H)) by
f*(aH) = (f(a))(f(H)) which turns out to be a homomorphism.

This seems like a "natural" thing to do, so I think I'm on the right track. The problem is that my function f* is not mapping to the right place: I don't think that f(G)/f(H) is a subset of G'/H'.

I also noticed that in proving the above, I did not make use of the hypotheses that H' is normal in G' or that f(H) is a subset of H'. Can these assumptions be used to show that
f(H) = H'?

Any hints would be greatly appreciated.
Sam
 
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Admittedly, I haven't put anything down on paper here, but does a problem arise if you define your function as f*(aH) = f(a)H' ?
 
Well, you are on the right track. Try drawing a diagram. We have 3 maps: f:G->G', and the two natural projection maps G->G/H and G'->G'/H'. Try to make the diagram commute.
 

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