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  • In a ring R, every element has an additive inverse, but not every element

  • will have a multiplicative inverse. Put another way, for a ring R, the

  • elements form a group under addition, but the nonzero elements may not form a

  • group under multiplication. However, there may be elements in the

  • ring which do have multiplicative inverses. We call these elements Units,

  • and they form a group under multiplication:

  • the group of units in a ring.

  • Let R be a ring. An element X is called a unit if there's an element Y

  • where x times y equals 1 and y times x equals 1. This is the notation for the

  • inverse of X. The set of all units for the ring R is written with a little

  • multiplication symbol up above. Let's first see a few examples before we talk

  • about the units abstractly.

  • The integers Z are a commutative ring. The only numbers

  • with the multiplicative inverse are 1 and negative 1. For every other nonzero

  • integer, the inverse would be a fraction, not an integer.

  • For example, the inverse of 3 is 1/3, which is not an integer. So the units for

  • this ring is a group with only 2 elements: 1 and negative 1. Here is a

  • group multiplication table for these units.

  • Next, let's look at the integers mod 12.

  • To find the units, let's look at the multiplication table for the non-zero

  • elements 1 through 11. We can find the units by looking for rows or columns

  • that contain the multiplicative identity 1. The only rows and columns that contain

  • a 1 are 1, 5, 7, and 11.

  • These are the 4 units for the ring of integers mod 12.

  • You can check that this is a group by looking at the group multiplication

  • table for these 4 units. This table only contains the numbers 1, 5, 7, and 11, so

  • it's closed under multiplication. There's a 1 in every row in column so each

  • element has an inverse. So the units for the integers mod 12 form a group of

  • order 4. Now that we've seen a couple of examples,

  • let's talk about the units more generally. In the previous examples, we

  • saw that the units form a group under multiplication.

  • Let's now see why this is always true.

  • Let R be any ring. Let's look at the set

  • of units and show that it's a group. To do this, we need to check that all the

  • group axioms hold. First, the set of units does contain the identity element 1,

  • since 1 is its own inverse under multiplication. So this set has an

  • identity. We inherit associativity from the ring R, so we can check that off. Next,

  • by definition, every element X in this set has an inverse Y, so we can mark off

  • the inverse axiom. This leaves closure. In other words, if x

  • and y are elements in this set, is their product also in the set? That is, if X has

  • an inverse and Y has an inverse, does X times y also have an inverse? Indeed, it

  • does. The inverse of x times y is y inverse times X inverse. Since x times y

  • has an inverse, it must also be in the set of units. So we have closure. This

  • shows the units do indeed form a group under multiplication.

  • Let's return to the example of the integers Z.

  • This ring has two units: 1 and negative 1. If you

  • multiply any integer by a unit, you get what's called an associate. For example,

  • if you multiply the integer 2 by the units, you get 2 and negative 2. These

  • integers are associates. Similarly, 3 and negative 3 are associates, as are 4 and

  • negative 4,and so on. The ideas of units and associates are needed for a more

  • precise discussion of factoring numbers.

  • Most people know you can factor any

  • integer greater than 1 uniquely into a product of primes. This is known as a

  • fundamental theorem of arithmetic. We don't include one, because it's a unit,

  • and units aren't prime and do not have a unique factorization. For example, we can

  • factor the integer 1 as 1 times 1, 1 times 1 times 1, and so on...but what about

  • the negative integers? Do they have a unique factorization? They do, but you

  • need to use units and associates to describe it. For example, negative 12 can

  • be written as 2 times 2 times negative 3. It can also be written as negative 2

  • times negative 3 times negative 2, or as 2 times negative 2 times 3.

  • We can even factor it as negative 1 times 1 times 2 times 2 times 3.

  • But these factorizations are all related,

  • because 2 and negative 2 are associates, and 3 and negative 3 are also associates.

  • The last factorization just includes a few units thrown in. You can absorb these

  • units into the first factor. If we reorder the factorizations

  • so the associates line up with one another, we see the factorizations are

  • all the same - the only difference being the terms are associates of one another.

  • We often say the factorizations are unique up to order and associates. This

  • is the fundamental theorem of arithmetic generalized to all integers. It applies

  • to every integer except 0 and the 2 units 1 and negative 1. The problem of

  • finding the units in a ring is a major topic in number theory. This is because

  • the integers and the rational numbers have been generalized into extensions

  • call the ring of integers and number fields; and many problems in number

  • theory require an understanding of how many units there are and what is a

  • structure of this group. Describing the group of units is a difficult problem

  • that is still being researched today. As a final example, look at the ring of 2 by

  • 2 matrices with integer entries. Most of these matrices do not have an inverse

  • under multiplication. For example, the inverse of the matrix 1

  • 2 3 4 is the matrix negative 2 1 3 halves and negative 1/2. This matrix is

  • not in the ring, because two of the entries are fractions. But look at the

  • matrix 2 7 1 4. The inverse of this matrix is 4 negative 7 negative 1 2

  • which is in the ring. Their product is the identity matrix, regardless of the

  • order, so this matrix is a unit. In fact this ring has an infinite group of units:

  • the set of all matrices with determinant 1 or negative 1. We won't prove this here,

  • but it's a very rewarding challenge to try to convince yourself this is true.

  • Here's a fun problem for you to discuss: look at the integers mod n from N equals

  • 2 through 50. For each ring, find all the units and then, compute the

  • percentage of elements that are units. Which ring has a smallest percentage of units?

  • Next, compare this to the percentage of subscribers who support us on Patreon.

  • One of these fractions is way too small. You should do something about that.....

In a ring R, every element has an additive inverse, but not every element

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