An Abelian Group That Isn't Free Or Divisible, Doesn't Satisfy The Maximal Or Minimal Condition, And For Which There Is No N > 0 N>0 N > 0 With N G = { 0 } NG=\{0\}\; N G = { 0 } ?

Introduction

In the realm of group theory, abelian groups have been extensively studied due to their simplicity and elegance. However, as we delve deeper into the structure of these groups, we often encounter counterexamples that challenge our understanding and force us to reevaluate our assumptions. In this article, we will explore an abelian group that does not satisfy the maximal or minimal condition, nor is it free or divisible. Furthermore, we will examine the properties of this group and demonstrate that there exists no positive integer $n$ such that $nG = \{0\}$.

Preliminaries

Before we dive into the main discussion, let's establish some basic definitions and notations. An abelian group is a group that satisfies the commutative property, i.e., for any two elements $a$ and $b$ in the group, $ab = ba$. A free abelian group is an abelian group that has a basis, i.e., a set of elements such that every element in the group can be expressed uniquely as a finite linear combination of elements from the basis. A divisible abelian group is an abelian group that has the property that for any element $a$ in the group and any positive integer $n$, there exists an element $b$ in the group such that $nb = a$. The maximal condition states that every non-empty set of subgroups of the group has a maximal element, while the minimal condition states that every non-empty set of subgroups of the group has a minimal element.

The Counterexample

The abelian group we will consider is the group of integers under addition, denoted by $\mathbb{Z}$. While $\mathbb{Z}$ is an abelian group, it does not satisfy the maximal or minimal condition. To see this, consider the set of subgroups of $\mathbb{Z}$, which includes the trivial subgroup $\{0\}$ and the subgroup $\mathbb{Z}$ itself. Since there is no maximal element in this set, $\mathbb{Z}$ does not satisfy the maximal condition. Similarly, since there is no minimal element in this set, $\mathbb{Z}$ does not satisfy the minimal condition.

Free and Divisible Properties

Next, we will examine whether $\mathbb{Z}$ is a free or divisible abelian group. A free abelian group has a basis, i.e., a set of elements such that every element in the group can be expressed uniquely as a finite linear combination of elements from the basis. However, $\mathbb{Z}$ does not have a basis, since every non-zero element in $\mathbb{Z}$ can be expressed as a multiple of any other non-zero element. Therefore, $\mathbb{Z}$ is not a free abelian group.

A divisible abelian group has the property that for any element $a$ in the group and any positive integer $n$, there exists an element $b$ in the group such that $nb = a$. However, this property does not hold for $\mathbb{Z}$, since for any non-zero element $a$ in $\mathbb{Z}$ and any positive integer $n$, there does not exist an element $b$ in $\mathbb{Z}$ such that $nb = a$. Therefore, $\mathbb{Z}$ is not a divisible abelian group.

The Property $nG = \{0\}$

Finally, we will examine whether there exists a positive integer $n$ such that $nG = \{0\}$, where $G$ is the group $\mathbb{Z}$. Suppose, for the sake of contradiction, that such an integer $n$ exists. Then, for any element $a$ in $\mathbb{Z}$, we have $na = 0$, which implies that $a = 0$. Therefore, the only element in $\mathbb{Z}$ is $0$, which is a contradiction. Hence, there does not exist a positive integer $n$ such that $nG = \{0\}$.

Conclusion

In this article, we have explored an abelian group that does not satisfy the maximal or minimal condition, nor is it free or divisible. Furthermore, we have demonstrated that there exists no positive integer $n$ such that $nG = \{0\}$. This counterexample highlights the importance of considering various properties of abelian groups and the need to be cautious when making assumptions about their structure.

Future Directions

The study of abelian groups is a rich and vibrant area of mathematics, with many open problems and unsolved questions. Some potential directions for future research include:

• Characterizing abelian groups that satisfy the maximal or minimal condition: Can we find a characterization of abelian groups that satisfy the maximal or minimal condition? What properties do these groups have in common?
• Studying the structure of free and divisible abelian groups: What can we say about the structure of free and divisible abelian groups? Are there any interesting properties or subgroups that these groups possess?
• Investigating the property $nG = \{0\}$: Can we find a characterization of abelian groups that satisfy the property $nG = \{0\}$? What implications does this property have for the structure of the group?

By exploring these and other questions, we can gain a deeper understanding of the structure of abelian groups and their properties, and develop new tools and techniques for studying these groups.

References

• [1]: Hungerford, T. W. (1974). Algebra. Springer-Verlag.
• [2]: Lang, S. (1993). Algebra. Springer-Verlag.
• [3]: Rotman, J. J. (1995). An Introduction to the Theory of Groups. Springer-Verlag.

Note: The references provided are a selection of classic texts on group theory and algebra. They are not exhaustive, and readers are encouraged to explore other sources for a more comprehensive understanding of the subject.

Q: What is an abelian group?

A: An abelian group is a group that satisfies the commutative property, i.e., for any two elements $a$ and $b$ in the group, $ab = ba$. This means that the order in which we perform the group operation does not matter.

Q: What are some examples of abelian groups?

A: Some examples of abelian groups include:

• The group of integers under addition, denoted by $\mathbb{Z}$
• The group of rational numbers under addition, denoted by $\mathbb{Q}$
• The group of real numbers under addition, denoted by $\mathbb{R}$
• The group of complex numbers under addition, denoted by $\mathbb{C}$

Q: What is the difference between a free abelian group and a divisible abelian group?

A: A free abelian group is an abelian group that has a basis, i.e., a set of elements such that every element in the group can be expressed uniquely as a finite linear combination of elements from the basis. A divisible abelian group is an abelian group that has the property that for any element $a$ in the group and any positive integer $n$, there exists an element $b$ in the group such that $nb = a$.

Q: What is the maximal condition in an abelian group?

A: The maximal condition in an abelian group states that every non-empty set of subgroups of the group has a maximal element. This means that for any set of subgroups, there exists a subgroup that is not contained in any other subgroup in the set.

Q: What is the minimal condition in an abelian group?

A: The minimal condition in an abelian group states that every non-empty set of subgroups of the group has a minimal element. This means that for any set of subgroups, there exists a subgroup that contains every other subgroup in the set.

Q: What is the property $nG = \{0\}$ in an abelian group?

A: The property $nG = \{0\}$ in an abelian group states that for any positive integer $n$, the group $nG$ is equal to the trivial subgroup $\{0\}$. This means that for any element $a$ in the group, $na = 0$.

Q: Can an abelian group satisfy the maximal or minimal condition and still not be free or divisible?

A: Yes, an abelian group can satisfy the maximal or minimal condition and still not be free or divisible. For example, the group of integers under addition, denoted by $\mathbb{Z}$, satisfies the maximal and minimal conditions, but it is not free or divisible.

Q: Can an abelian group satisfy the property $nG = \{0\}$ and still not be free or divisible?

A: Yes, an abelian group can satisfy the property $nG = \{0\}$ and still not be free or divisible. For example, the group of integers under addition, denoted by $\mathbb{Z}$, satisfies the property $nG = \{0\}$, but it is not free or divisible.

Q: What are some open problems in the study of abelian groups?

A: Some open problems in the study of abelian groups include:

• Characterizing abelian groups that satisfy the maximal or minimal condition
• Studying the structure of free and divisible abelian groups
• Investigating the property $nG = \{0\}$ in abelian groups

Q: What are some potential applications of the study of abelian groups?

A: The study of abelian groups has potential applications in various fields, including:

• Algebraic geometry
• Number theory
• Representation theory
• Computer science

Q: What are some resources for learning more about abelian groups?

A: Some resources for learning more about abelian groups include:

• Textbooks on group theory and algebra
• Online courses and lectures on group theory and algebra
• Research papers and articles on abelian groups
• Online communities and forums for discussing group theory and algebra

Note: The questions and answers provided are a selection of common questions and answers about abelian groups. They are not exhaustive, and readers are encouraged to explore other sources for a more comprehensive understanding of the subject.