Proving Uniqueness of Products in Finite Rings

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SUMMARY

The discussion centers on proving that for any unit \( a \) in a finite ring \( R \) with \( q \) units, the equation \( a^q = 1 \) holds true. The user initially seeks a solution without relying on group theory or Lagrange's theorem. A participant clarifies that since the set of units forms a group, Lagrange's theorem can be applied to conclude the proof. The user also explores an alternative approach by defining a set \( T \) of products involving a unit \( a \) and demonstrates that if \( T \) is equal to the original set of units, then \( a^n = 1 \) follows.

PREREQUISITES
  • Understanding of finite rings and their properties
  • Familiarity with units in ring theory
  • Basic knowledge of group theory concepts
  • Experience with mathematical proofs and logical reasoning
NEXT STEPS
  • Study the properties of finite rings and their units
  • Learn about Lagrange's theorem and its applications in ring theory
  • Explore alternative proofs of group properties without group theory
  • Investigate the uniqueness of elements in finite sets and their implications
USEFUL FOR

Mathematics students, particularly those studying abstract algebra, educators teaching ring theory, and researchers interested in the properties of finite rings and units.

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Homework Statement


Let q be the number of units in finite ring R. Show that for all a in R, if a is a unit in R then a^q = 1.

Is there a way to solve this without using group theory? All I can seem to find information on is when a and m are relatively prime then a^{\phi (m)} = 1 (mod \, m), which I'd like to prove using the problem I can't solve.

Homework Equations





The Attempt at a Solution



I really haven't been able to get anywhere on this. Are there certain patterns that finite rings always follow, that I can exploit?


Thanks
 
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If q is the number of invertibles in the ring R, then it means that the order of V is q. Where V would be the group of invertibles in that ring. That is we know that V( the set of all invertibles in a ring is a group in itself). Now it is clear that if a is invertible(unit) then it belongs to V. So, by lagrange theorem we have the desired result that a^q=1. where 1 is the unity of the ring R.
 
Thank you for your help.

I'm trying to solve this without using groups or Lagrange's theorem (we didn't learn any of that in class).

I made progress but I still am a little hung up at one (probably extremely trivial) detail.

Let S be the set of units {x_1,...,x_n} and let a be a unit of the ring. T = {ax_1,...,ax_n} are all different and therefore T = S, which implies the products (call it z) are the same. a^n*z = z implies a^n = 1.

I am not sure how to prove that all members of T = {ax_1,...,ax_n} are all unique, although I think it's pretty intuitive..
 

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