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5.1 Definitions and properties of projective modules

3 min read•august 7, 2024

Projective modules are a key concept in homological algebra, allowing us to "lift" along surjective homomorphisms. They're closely related to free modules, which have a basis. Understanding these modules helps us analyze algebraic structures and solve complex problems.

Projective modules have special properties like being direct summands of free modules and splitting . These characteristics make them powerful tools for studying module theory and developing advanced algebraic techniques.

Projective and Free Modules

Properties and Definitions

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is a module $P$ such that for every surjective $f: M \to N$ and every homomorphism $g: P \to N$ , there exists a homomorphism $h: P \to M$ such that $f \circ h = g$
is a module that has a basis, which means it is isomorphic to a direct sum of copies of the base ring $R$ $R$ (denoted as $R^{(I)}$ $R^{(I)}$ for some index set $I$ $I$ )
- Examples of free modules include $\mathbb{R}^n$ over $\mathbb{R}$ and $\mathbb{Z}^n$ over $\mathbb{Z}$
Projectivity is a property of modules that allows them to be "lifted" along surjective homomorphisms
- Every free module is projective, but not every projective module is free (e.g., the $\mathbb{Z}$ -module $\mathbb{Q}$ is projective but not free)

Dual Basis Lemma

Dual basis lemma states that if $M$ $M$ is a free module with basis $\{x_i\}_{i \in I}$ ${x_{i}}_{i \in I}$ , then there exists a unique family of linear maps $\{f_i: M \to R\}_{i \in I}$ ${f_{i} : M \to R}_{i \in I}$ such that $f_i(x_j) = \delta_{ij}$ $f_{i} (x_{j}) = δ_{ij}$ (Kronecker delta) for all $i, j \in I$ $i, j \in I$
- The family $\{f_i\}_{i \in I}$ is called the dual basis of $\{x_i\}_{i \in I}$
Dual basis lemma is useful for proving that every free module is projective and for constructing projective resolutions of modules

Direct Summands and Splitting

Direct Summands

is a submodule $N$ $N$ of a module $M$ $M$ such that there exists another submodule $N'$ $N^{'}$ of $M$ $M$ with $M = N \oplus N'$ $M = N \oplus N^{'}$ (direct sum)
- Examples of direct summands include $\mathbb{Z}$ as a direct summand of $\mathbb{Z} \oplus \mathbb{Z}$ and $\mathbb{Q}$ as a direct summand of $\mathbb{Q} \oplus \mathbb{Q}$
A module $M$ is projective if and only if it is a direct summand of a free module

Splitting Exact Sequences

Splitting exact sequence is a short exact sequence $0 \to N \to M \to P \to 0$ $0 \to N \to M \to P \to 0$ such that the middle term $M$ $M$ is isomorphic to the direct sum of $N$ $N$ and $P$ $P$ (i.e., $M \cong N \oplus P$ $M ≅ N \oplus P$ )
- The sequence is said to split if there exists a homomorphism $s: P \to M$ such that $f \circ s = id_P$ , where $f: M \to P$ is the surjective homomorphism in the sequence
A module $P$ is projective if and only if every short exact sequence $0 \to N \to M \to P \to 0$ splits

Lifting Property

is a characteristic of projective modules, stating that for every surjective homomorphism $f: M \to N$ $f : M \to N$ and every homomorphism $g: P \to N$ $g : P \to N$ , there exists a homomorphism $h: P \to M$ $h : P \to M$ such that $f \circ h = g$ $f \circ h = g$
- This property allows projective modules to be "lifted" along surjective homomorphisms
The lifting property is equivalent to the splitting of short exact sequences and the existence of a direct summand in a free module

Key Lemmas

Schanuel's Lemma

states that if $0 \to K \to P \to M \to 0$ $0 \to K \to P \to M \to 0$ and $0 \to K' \to P' \to M \to 0$ $0 \to K^{'} \to P^{'} \to M \to 0$ are two short exact sequences with $P$ $P$ and $P'$ $P^{'}$ projective modules, then $K \oplus P' \cong K' \oplus P$ $K \oplus P^{'} ≅ K^{'} \oplus P$
- This lemma is useful for comparing the kernels of two projective resolutions of the same module
Schanuel's lemma can be used to prove that the projective dimension of a module is well-defined (i.e., independent of the choice of projective resolution)
- The projective dimension of a module $M$ is the smallest non-negative integer $n$ such that there exists a projective resolution of $M$ of length $n$ , or $\infty$ if no such finite resolution exists

Key Terms to Review (20)

Baer's Criterion: Baer's Criterion is a fundamental result in module theory that provides a characterization of projective modules. It states that a module is projective if and only if every homomorphism from it to an injective module can be lifted through any epimorphism onto that injective module. This concept is closely tied to the properties of projective and injective modules, resolutions, and the overall structure of modules in algebra.

Direct sum of free modules: The direct sum of free modules is a construction in module theory that allows for the combination of multiple free modules into a single module that retains the structure and properties of the original modules. In this context, if you have a collection of free modules, their direct sum consists of tuples where each entry belongs to one of the free modules, and operations on these tuples are defined component-wise. This concept is crucial in understanding projective modules since projective modules can be characterized as direct summands of free modules.

Direct Summand: A direct summand is a submodule of a module such that the original module can be expressed as a direct sum of this submodule and another complementary submodule. This concept highlights the ability to break down modules into simpler components, facilitating the understanding of their structure and properties, particularly in the context of projective modules, where direct summands play a crucial role in their definition and characterization.

Exact Sequences: An exact sequence is a sequence of algebraic structures and morphisms between them where the image of one morphism equals the kernel of the next. This concept is crucial in understanding the relationships between different algebraic objects, like modules or groups, and helps to reveal the underlying structure of these objects, facilitating deeper exploration into properties like projectiveness and injectiveness.

Flat Module: A flat module is a type of module over a ring that preserves the exactness of sequences when tensored with any other module. This means that if you have an exact sequence of modules, tensoring it with a flat module will keep it exact. Flat modules are essential in understanding projective modules, resolutions, and have numerous applications in both algebra and topology.

Free Module: A free module is a module that has a basis, meaning it is isomorphic to a direct sum of copies of a ring. This characteristic allows for the elements of the free module to be expressed uniquely as finite linear combinations of basis elements with coefficients from the ring. Free modules are fundamental in understanding projective modules since every free module is also projective, illustrating the connection between their structural properties.

H. cartan: H. Cartan refers to Henri Cartan, a prominent mathematician known for his work in algebraic topology and homological algebra. He contributed significantly to the understanding of projective and injective modules, establishing foundational concepts that help in the classification and analysis of modules over rings. His theories on the extension and lifting properties of these modules are crucial for connecting various aspects of homological algebra.

Homomorphism: A homomorphism is a structure-preserving map between two algebraic structures, such as groups, rings, or modules. It allows for the translation of operations from one structure to another while maintaining their respective properties. This concept is crucial in understanding relationships between different mathematical objects and plays a significant role in various areas, including the study of projective modules and chain complexes.

Injective Module: An injective module is a type of module that has the property that any homomorphism from a submodule can be extended to the entire module. This means that if you have a short exact sequence where one of the modules is injective, it allows for certain extensions and lifting properties that are crucial in homological algebra. The concept connects deeply with projective modules and plays a significant role in constructing projective and injective resolutions, understanding exact sequences, and utilizing the Ext functor effectively.

Isomorphism: An isomorphism is a mapping between two mathematical structures that establishes a one-to-one correspondence, preserving the operations and relations of the structures. It shows that two structures are fundamentally the same in terms of their properties, even if they may appear different at first glance. This concept connects deeply with how we understand relationships in category theory and other mathematical frameworks.

Lifting Property: The lifting property is a concept in homological algebra that describes a specific condition regarding the ability to lift morphisms through a projective module. It states that if there is a morphism from a projective module to another module, any morphism from the image of this projective module can be lifted back to the original module. This property is crucial in understanding how projective modules behave in relation to other modules and their resolutions.

M. Auslander: M. Auslander is a prominent mathematician known for his contributions to homological algebra, particularly in the study of projective modules and their properties. His work has provided significant insights into the structure and classification of modules over rings, especially focusing on the interplay between projective modules and other module types like injective and flat modules.

Module category: A module category is a mathematical structure that consists of objects called modules and morphisms between them, structured in a way that allows for the study of linear algebraic concepts in the context of categories. This concept helps in understanding how projective modules fit into larger categories and their relationships with other types of modules. By focusing on modules over a fixed ring, one can analyze properties like exactness, projectivity, and injectivity, which are essential for understanding module theory and homological algebra.

Module homomorphisms: Module homomorphisms are structure-preserving maps between two modules over a ring that maintain the operations of addition and scalar multiplication. These mappings play a crucial role in understanding the relationships between modules, particularly in terms of their properties like injectivity, surjectivity, and isomorphism. Recognizing module homomorphisms allows one to analyze how different modules can interact and relate to each other under the context of projective modules.

Modules over local rings: Modules over local rings are algebraic structures that generalize vector spaces, where the scalars come from a local ring, which is a commutative ring with a unique maximal ideal. These modules play a significant role in homological algebra, especially in understanding projective modules, as they allow for the exploration of properties such as projectivity and flatness in a more nuanced context. The unique maximal ideal of a local ring provides a framework for considering localization and studying how modules behave under various morphisms.

Projective Cover Theorem: The Projective Cover Theorem states that every module has a projective cover, which is a surjective morphism from a projective module onto the given module, with the property that any other morphism from a projective module to the given module factors through this morphism. This theorem connects the concept of projective modules with the existence of minimal projective objects that can 'cover' or represent other modules, forming a crucial link in the study of homological algebra.

Projective Module: A projective module is a type of module that satisfies a lifting property with respect to homomorphisms, meaning that for any surjective homomorphism, any module homomorphism from the projective module can be lifted to the original module. This concept is crucial for understanding direct sums and the behavior of modules under exact sequences, particularly how projective modules can be used to construct resolutions and relate to the Ext functor.

Representable functor: A representable functor is a type of functor that can be expressed as the hom-functor from a fixed object in a category to any object in that category. This concept is pivotal because it connects abstract categorical properties to concrete objects, allowing one to analyze and understand the structure of categories through the lenses of homomorphisms and morphisms. The connection to projective modules arises when considering how representable functors can relate to the structure and properties of modules over rings, especially through the lens of projectivity and flatness.

Schanuel's Lemma: Schanuel's Lemma is a fundamental result in homological algebra that describes a condition for the projectivity of modules. Specifically, it states that if you have a commutative diagram involving a surjective morphism and two modules, then certain properties of projective modules can be deduced, particularly relating to lifting and extension properties. This lemma is crucial for understanding the structure of projective modules and their relationships with other module types, especially in the context of exact sequences.

Split Exactness: Split exactness refers to a situation in a sequence of modules where a short exact sequence splits, meaning that the middle module can be expressed as a direct sum of its kernel and image. This concept is crucial when discussing projective modules because it implies that every short exact sequence involving a projective module is split, which indicates that projective modules behave like direct summands in a sense. Understanding split exactness helps to clarify how projective modules interact with homomorphisms and provides insight into their structural properties.

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Practice QuizGlossary

Practice Quiz Glossary

5.1 Definitions and properties of projective modules

Projective and Free Modules

Properties and Definitions

Top images from around the web for Properties and Definitions

Top images from around the web for Properties and Definitions

Dual Basis Lemma

Direct Summands and Splitting

Direct Summands

Splitting Exact Sequences

Lifting Property

Key Lemmas

Schanuel's Lemma

Key Terms to Review (20)

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