Multiplicative group of integers modulo n#General composite numbers

It is a straightforward exercise to show that, under multiplication, the set of congruence classes modulo n that are coprime to n satisfy the axioms for an abelian group.

Indeed, a is coprime to n if and only if {{nowrap|1= gcd(a, n) = 1}}. Integers in the same congruence class {{nowrap|a ≡ b (mod n)}} satisfy {{nowrap|1= gcd(a, n) = gcd(b, n)}}; hence one is coprime to n if and only if the other is. Thus the notion of congruence classes modulo n that are coprime to n is well-defined.

Since {{nowrap|1=gcd(a, n) = 1}} and {{nowrap|1=gcd(b, n) = 1}} implies {{nowrap|1=gcd(ab, n) = 1}}, the set of classes coprime to n is closed under multiplication.

Integer multiplication respects the congruence classes, that is, {{nowrap|a ≡ a' }} and {{nowrap|b ≡ b' (mod n)}} implies {{nowrap|ab ≡ a'b' (mod n)}}.

This implies that the multiplication is associative, commutative, and that the class of 1 is the unique multiplicative identity.

Finally, given a, the multiplicative inverse of a modulo n is an integer x satisfying {{nowrap|ax ≡ 1 (mod n)}}.

It exists precisely when a is coprime to n, because in that case {{nowrap|1=gcd(a, n) = 1}} and by Bézout's lemma there are integers x and y satisfying {{nowrap|1=ax + ny = 1}}. Notice that the equation {{nowrap|1=ax + ny = 1}} implies that x is coprime to n, so the multiplicative inverse belongs to the group.

The set of (congruence classes of) integers modulo n with the operations of addition and multiplication is a ring.

It is denoted $\backslash mathbb\{Z\}/n\backslash mathbb\{Z\}$  or  $\backslash mathbb\{Z\}/(n)$  (the notation refers to taking the quotient of integers modulo the ideal $n\backslash mathbb\{Z\}$ or $(n)$ consisting of the multiples of n).

Outside of number theory the simpler notation $\backslash mathbb\{Z\}\_n$ is often used, though it can be confused with the p-adic number when n is a prime number.

The multiplicative group of integers modulo n, which is the group of units in this ring, may be written as (depending on the author) $(\backslash mathbb\{Z\}/n\backslash mathbb\{Z\})^\backslash times,$   $(\backslash mathbb\{Z\}/n\backslash mathbb\{Z\})^*,$   $\backslash mathrm\{U\}(\backslash mathbb\{Z\}/n\backslash mathbb\{Z\}),$   $\backslash mathrm\{E\}(\backslash mathbb\{Z\}/n\backslash mathbb\{Z\})$   (for German Einheit, which translates as unit), $\backslash mathbb\{Z\}\_n^*$, or similar notations. This article uses $(\backslash mathbb\{Z\}/n\backslash mathbb\{Z\})^\backslash times.$

The notation $\backslash mathrm\{C\}\_n$ refers to the cyclic group of order n.

It is isomorphic to the group of integers modulo n under addition.

Note that $\backslash mathbb\{Z\}/n\backslash mathbb\{Z\}$ or $\backslash mathbb\{Z\}\_n$ may also refer to the group under addition.

For example, the multiplicative group $(\backslash mathbb\{Z\}/p\backslash mathbb\{Z\})^\backslash times$ for a prime p is cyclic and hence isomorphic to the additive group $\backslash mathbb\{Z\}/(p-1)\backslash mathbb\{Z\}$, but the isomorphism is not obvious.

The order of the multiplicative group of integers modulo n is the number of integers in $\backslash \{0,1,\backslash dots,n-1\backslash \}$ coprime to n. It is given by Euler's totient function: $|\; (\backslash mathbb\{Z\}/n\backslash mathbb\{Z\})^\backslash times|=\backslash varphi(n)$ {{OEIS|id=A000010}}.

For prime p, $\backslash varphi(p)=p-1$.

{{main article|primitive root modulo n}}

The group $(\backslash mathbb\{Z\}/n\backslash mathbb\{Z\})^\backslash times$ is cyclic if and only if n is 1, 2, 4, p^k or 2p^k, where p is an odd prime and {{nowrap|k > 0}}. For all other values of n the group is not cyclic.{{MathWorld|title=Modulo Multiplication Group|urlname=ModuloMultiplicationGroup}}

{{Cite web |title=Primitive root - Encyclopedia of Mathematics |url=https://encyclopediaofmath.org/wiki/Primitive_root |access-date=2024-07-06 |website=encyclopediaofmath.org}}{{Harvnb|Vinogradov|2003|loc=§ VI PRIMITIVE ROOTS AND INDICES|pp=105–121}}

This was first proved by Gauss.{{sfn|Gauss|1986|loc=arts. 52–56, 82–891}}

This means that for these n:

:$(\backslash mathbb\{Z\}/n\backslash mathbb\{Z\})^\backslash times\; \backslash cong\; \backslash mathrm\{C\}\_\{\backslash varphi(n)\},$ where $\backslash varphi(p^k)=\backslash varphi(2\; p^k)=p^k\; -\; p^\{k-1\}.$

By definition, the group is cyclic if and only if it has a generator g (a generating set {g} of size one), that is, the powers $g^0,g^1,g^2,\backslash dots,$ give all possible residues modulo n coprime to n (the first $\backslash varphi(n)$ powers $g^0,\backslash dots,g^\{\backslash varphi(n)-1\}$ give each exactly once).

A generator of $(\backslash mathbb\{Z\}/n\backslash mathbb\{Z\})^\backslash times$ is called a primitive root modulo n.{{sfn|Vinogradov|2003|p=106}}

If there is any generator, then there are $\backslash varphi(\backslash varphi(n))$ of them.

Modulo 1 any two integers are congruent, i.e., there is only one congruence class, [0], coprime to 1. Therefore, $(\backslash mathbb\{Z\}/1\backslash ,\backslash mathbb\{Z\})^\backslash times\; \backslash cong\; \backslash mathrm\{C\}\_1$ is the trivial group with {{nowrap|1=φ(1) = 1}} element. Because of its trivial nature, the case of congruences modulo 1 is generally ignored and some authors choose not to include the case of n = 1 in theorem statements.

Modulo 2 there is only one coprime congruence class, [1], so $(\backslash mathbb\{Z\}/2\backslash mathbb\{Z\})^\backslash times\; \backslash cong\; \backslash mathrm\{C\}\_1$ is the trivial group.

Modulo 4 there are two coprime congruence classes, [1] and [3], so $(\backslash mathbb\{Z\}/4\backslash mathbb\{Z\})^\backslash times\; \backslash cong\; \backslash mathrm\{C\}\_2,$ the cyclic group with two elements.

Modulo 8 there are four coprime congruence classes, [1], [3], [5] and [7]. The square of each of these is 1, so $(\backslash mathbb\{Z\}/8\backslash mathbb\{Z\})^\backslash times\; \backslash cong\; \backslash mathrm\{C\}\_2\; \backslash times\; \backslash mathrm\{C\}\_2,$ the Klein four-group.

Modulo 16 there are eight coprime congruence classes [1], [3], [5], [7], [9], [11], [13] and [15]. $\backslash \{\backslash pm\; 1,\; \backslash pm\; 7\backslash \}\backslash cong\; \backslash mathrm\{C\}\_2\; \backslash times\; \backslash mathrm\{C\}\_2,$ is the 2-torsion subgroup (i.e., the square of each element is 1), so $(\backslash mathbb\{Z\}/16\backslash mathbb\{Z\})^\backslash times$ is not cyclic. The powers of 3, $\backslash \{1,\; 3,\; 9,\; 11\backslash \}$ are a subgroup of order 4, as are the powers of 5, $\backslash \{1,\; 5,\; 9,\; 13\backslash \}.$   Thus $(\backslash mathbb\{Z\}/16\backslash mathbb\{Z\})^\backslash times\; \backslash cong\; \backslash mathrm\{C\}\_2\; \backslash times\; \backslash mathrm\{C\}\_4.$

The pattern shown by 8 and 16 holds{{sfn|Gauss|1986|loc=arts. 90–91}} for higher powers 2^k, {{nowrap|k > 2}}: $\backslash \{\backslash pm\; 1,\; 2^\{k-1\}\; \backslash pm\; 1\backslash \}\backslash cong\; \backslash mathrm\{C\}\_2\; \backslash times\; \backslash mathrm\{C\}\_2,$ is the 2-torsion subgroup, so $(\backslash mathbb\{Z\}/2^k\backslash mathbb\{Z\})^\backslash times$ cannot be cyclic, and the powers of 3 are a cyclic subgroup of order {{nowrap|1=2^{k − 2}}}, so:

$(\backslash mathbb\{Z\}/2^k\backslash mathbb\{Z\})^\backslash times\; \backslash cong\; \backslash mathrm\{C\}\_2\; \backslash times\; \backslash mathrm\{C\}\_\{2^\{k-2\}\}.$

By the fundamental theorem of finite abelian groups, the group $(\backslash mathbb\{Z\}/n\backslash mathbb\{Z\})^\backslash times$ is isomorphic to a direct product of cyclic groups of prime power orders.

More specifically, the Chinese remainder theoremRiesel covers all of this. {{Harvnb|Riesel|1994|pp=267–275}}. says that if $\backslash ;\backslash ;n=p\_1^\{k\_1\}p\_2^\{k\_2\}p\_3^\{k\_3\}\backslash dots,\; \backslash ;$ then the ring $\backslash mathbb\{Z\}/n\backslash mathbb\{Z\}$ is the direct product of the rings corresponding to each of its prime power factors:

:$\backslash mathbb\{Z\}/n\backslash mathbb\{Z\}\; \backslash cong\; \backslash mathbb\{Z\}/\{p\_1^\{k\_1\}\}\backslash mathbb\{Z\}\backslash ;\; \backslash times\; \backslash ;\backslash mathbb\{Z\}/\{p\_2^\{k\_2\}\}\backslash mathbb\{Z\}\; \backslash ;\backslash times\backslash ;\; \backslash mathbb\{Z\}/\{p\_3^\{k\_3\}\}\backslash mathbb\{Z\}\backslash dots\backslash ;\backslash ;$

Similarly, the group of units $(\backslash mathbb\{Z\}/n\backslash mathbb\{Z\})^\backslash times$ is the direct product of the groups corresponding to each of the prime power factors:

:$(\backslash mathbb\{Z\}/n\backslash mathbb\{Z\})^\backslash times\backslash cong\; (\backslash mathbb\{Z\}/\{p\_1^\{k\_1\}\}\backslash mathbb\{Z\})^\backslash times\; \backslash times\; (\backslash mathbb\{Z\}/\{p\_2^\{k\_2\}\}\backslash mathbb\{Z\})^\backslash times\; \backslash times\; (\backslash mathbb\{Z\}/\{p\_3^\{k\_3\}\}\backslash mathbb\{Z\})^\backslash times\; \backslash dots\backslash ;.$

For each odd prime power $p^\{k\}$ the corresponding factor $(\backslash mathbb\{Z\}/\{p^\{k\}\}\backslash mathbb\{Z\})^\backslash times$ is the cyclic group of order $\backslash varphi(p^k)=p^k\; -\; p^\{k-1\}$, which may further factor into cyclic groups of prime-power orders.

For powers of 2 the factor $(\backslash mathbb\{Z\}/\{2^\{k\}\}\backslash mathbb\{Z\})^\backslash times$ is not cyclic unless k = 0, 1, 2, but factors into cyclic groups as described above.

The order of the group $\backslash varphi(n)$ is the product of the orders of the cyclic groups in the direct product.

The exponent of the group, that is, the least common multiple of the orders in the cyclic groups, is given by the Carmichael function $\backslash lambda(n)$ {{OEIS|id=A002322}}.

In other words, $\backslash lambda(n)$ is the smallest number such that for each a coprime to n, $a^\{\backslash lambda(n)\}\; \backslash equiv\; 1\; \backslash pmod\; n$ holds.

It divides $\backslash varphi(n)$ and is equal to it if and only if the group is cyclic.

If n is composite, there exists a possibly proper subgroup of $\backslash mathbb\{Z\}\_n^\backslash times$, called the "group of false witnesses", comprising the solutions of the equation $x^\{n-1\}=1$, the elements which, raised to the power {{nowrap|n − 1}}, are congruent to 1 modulo n.{{cite journal | zbl=0586.10003 | last1=Erdős | first1=Paul | author1-link=Paul Erdős | last2=Pomerance | first2=Carl | author2-link=Carl Pomerance | title=On the number of false witnesses for a composite number | journal=Mathematics of Computation | volume=46 | issue=173 | pages=259–279 | year=1986 | doi=10.1090/s0025-5718-1986-0815848-x| doi-access=free }} Fermat's Little Theorem states that for n = p a prime, this group consists of all $x\backslash in\; \backslash mathbb\{Z\}\_p^\backslash times$; thus for n composite, such residues x are "false positives" or "false witnesses" for the primality of n. The number x = 2 is most often used in this basic primality check, and n = {{nowrap|1=341 = 11 × 31}} is notable since $2^\{341-1\}\backslash equiv\; 1\; \backslash mod\; 341$, and n = 341 is the smallest composite number for which x = 2 is a false witness to primality. In fact, the false witnesses subgroup for 341 contains 100 elements, and is of index 3 inside the 300-element group $\backslash mathbb\{Z\}\_\{341\}^\backslash times$.

The smallest example with a nontrivial subgroup of false witnesses is {{nowrap|1=9 = 3 × 3}}. There are 6 residues coprime to 9: 1, 2, 4, 5, 7, 8. Since 8 is congruent to {{nowrap|−1 modulo 9}}, it follows that 8⁸ is congruent to 1 modulo 9. So 1 and 8 are false positives for the "primality" of 9 (since 9 is not actually prime). These are in fact the only ones, so the subgroup {1,8} is the subgroup of false witnesses. The same argument shows that {{nowrap|n − 1}} is a "false witness" for any odd composite n.

For n = 91 (= 7 × 13), there are $\backslash varphi(91)=72$ residues coprime to 91, half of them (i.e., 36 of them) are false witnesses of 91, namely 1, 3, 4, 9, 10, 12, 16, 17, 22, 23, 25, 27, 29, 30, 36, 38, 40, 43, 48, 51, 53, 55, 61, 62, 64, 66, 68, 69, 74, 75, 79, 81, 82, 87, 88, and 90, since for these values of x, x⁹⁰ is congruent to 1 mod 91.

n = 561 (= 3 × 11 × 17) is a Carmichael number, thus s⁵⁶⁰ is congruent to 1 modulo 561 for any integer s coprime to 561. The subgroup of false witnesses is, in this case, not proper; it is the entire group of multiplicative units modulo 561, which consists of 320 residues.

This table shows the cyclic decomposition of $(\backslash mathbb\{Z\}/n\backslash mathbb\{Z\})^\backslash times$ and a generating set for n ≤ 128. The decomposition and generating sets are not unique; for example,

(but $\backslash not\backslash cong\; \backslash mathrm\{C\}\_\{24\}\; \backslash cong\; \backslash mathrm\{C\}\_8\; \backslash times\; \backslash mathrm\{C\}\_3$). The table below lists the shortest decomposition (among those, the lexicographically first is chosen – this guarantees isomorphic groups are listed with the same decompositions). The generating set is also chosen to be as short as possible, and for n with primitive root, the smallest primitive root modulo n is listed.

For example, take $(\backslash mathbb\{Z\}/20\backslash mathbb\{Z\})^\backslash times$. Then $\backslash varphi(20)=8$ means that the order of the group is 8 (i.e., there are 8 numbers less than 20 and coprime to it); $\backslash lambda(20)=4$ means the order of each element divides 4, that is, the fourth power of any number coprime to 20 is congruent to 1 (mod 20). The set {3,19} generates the group, which means that every element of $(\backslash mathbb\{Z\}/20\backslash mathbb\{Z\})^\backslash times$ is of the form {{nowrap|3^a × 19^b}} (where a is 0, 1, 2, or 3, because the element 3 has order 4, and similarly b is 0 or 1, because the element 19 has order 2).

Smallest primitive root mod n are (0 if no root exists)

:0, 1, 2, 3, 2, 5, 3, 0, 2, 3, 2, 0, 2, 3, 0, 0, 3, 5, 2, 0, 0, 7, 5, 0, 2, 7, 2, 0, 2, 0, 3, 0, 0, 3, 0, 0, 2, 3, 0, 0, 6, 0, 3, 0, 0, 5, 5, 0, 3, 3, 0, 0, 2, 5, 0, 0, 0, 3, 2, 0, 2, 3, 0, 0, 0, 0, 2, 0, 0, 0, 7, 0, 5, 5, 0, 0, 0, 0, 3, 0, 2, 7, 2, 0, 0, 3, 0, 0, 3, 0, ... {{OEIS|id=A046145}}

Numbers of the elements in a minimal generating set of mod n are

:1, 1, 1, 1, 1, 1, 1, 2, 1, 1, 1, 2, 1, 1, 2, 2, 1, 1, 1, 2, 2, 1, 1, 3, 1, 1, 1, 2, 1, 2, 1, 2, 2, 1, 2, 2, 1, 1, 2, 3, 1, 2, 1, 2, 2, 1, 1, 3, 1, 1, 2, 2, 1, 1, 2, 3, 2, 1, 1, 3, 1, 1, 2, 2, 2, 2, 1, 2, 2, 2, 1, 3, 1, 1, 2, 2, 2, 2, 1, 3, 1, 1, 1, 3, 2, 1, 2, 3, 1, 2, ... {{OEIS|id=A046072}}

• Lenstra elliptic curve factorization

{{reflist}}

The Disquisitiones Arithmeticae has been translated from Gauss's Ciceronian Latin into English and German. The German edition includes all of his papers on number theory: all the proofs of quadratic reciprocity, the determination of the sign of the Gauss sum, the investigations into biquadratic reciprocity, and unpublished notes.

• {{citation

| last = Gauss | first = Carl Friedrich

| author-link = Carl Friedrich Gauss

| translator-last = Clarke | translator-first = Arthur A.

| title = Disquisitiones Arithmeticae (English translation, Second, corrected edition)

| publisher = Springer

| location = New York

| year = 1986

| isbn = 978-0-387-96254-2}}

• {{citation

| last = Gauss | first = Carl Friedrich

| translator-last = Maser | translator-first = H.

| title = Untersuchungen uber hohere Arithmetik (Disquisitiones Arithemeticae & other papers on number theory) (German translation, Second edition)

| publisher = Chelsea

| location = New York

| year = 1965

| isbn = 978-0-8284-0191-3}}

• {{citation

| last1 = Riesel | first1 = Hans| author-link = Hans Riesel

| title = Prime Numbers and Computer Methods for Factorization (second edition)

| publisher = Birkhäuser

| location = Boston

| year = 1994

| isbn = 978-0-8176-3743-9}}

• {{citation

| last = Vinogradov | first = I. M. | author-link = Ivan Matveyevich Vinogradov

| title = Elements of Number Theory

| publisher = Dover Publications

| location = Mineola, NY

| year = 2003

| isbn = 978-0-486-49530-9

| chapter = § VI Primitive roots and indices

| pages = 105–121

| chapter-url = https://books.google.com/books?id=xlIfdGPM9t4C&pg=PA105}}

• {{MathWorld |title=Modulo Multiplication Group |id=ModuloMultiplicationGroup}}
• {{MathWorld |title=Primitive Root |id=PrimitiveRoot}}
• [http://hobbes.la.asu.edu/groups/groups.html Web-based tool to interactively compute group tables] by John Jones
• {{OEIS el|A033948|Numbers that have a primitive root (the multiplicative group modulo n is cyclic)}}
• Numbers n such that the multiplicative group modulo n is the direct product of k cyclic groups:
• k = 2 {{OEIS el|A272592|2 cyclic groups}}
• k = 3 {{OEIS el|A272593|3 cyclic groups}}
• k = 4 {{OEIS el|A272594|4 cyclic groups}}
• {{OEIS el|A272590|The smallest number m such that the multiplicative group modulo m is the direct product of n cyclic groups}}

Category:Finite groups

Category:Modular arithmetic

Category:Multiplication