SUMMARY
The tensor product \(\mathbb{Z}_{10} \otimes_{\mathbb{Z}} \mathbb{Z}_{12}\) is isomorphic to \(\mathbb{Z}_{2}\). This conclusion is reached by demonstrating that for any non-zero integers \(m\) in \(\mathbb{Z}_{10}\) and \(n\) in \(\mathbb{Z}_{12}\), the product \(m \otimes n\) results in zero when \(m\) is even. The proof utilizes properties of \(\mathbb{Z}\)-modules and the behavior of morphisms, confirming that \(1 \otimes 10 = 0\) and \(m \otimes 1 = 0\) for even \(m\).
PREREQUISITES
- Understanding of tensor products in the context of \(\mathbb{Z}\)-modules
- Familiarity with the structure of abelian groups
- Knowledge of basic algebraic concepts from Vakil's Algebraic Geometry
- Ability to manipulate modular arithmetic in \(\mathbb{Z}_{n}\)
NEXT STEPS
- Study the properties of tensor products of \(\mathbb{Z}\)-modules
- Explore the relationship between abelian groups and \(\mathbb{Z}\)-modules
- Learn about morphisms in the context of module theory
- Investigate examples of tensor products yielding zero results
USEFUL FOR
Mathematics students, algebraists, and anyone studying module theory and tensor products, particularly those interested in the properties of \(\mathbb{Z}\)-modules and their applications in algebra.