Below is a clear, complete, and exam-oriented explanation of Integral Domains and Fields — perfect for BCA/MCA/University exams.
Integral Domains and Fields
Both integral domains and fields are special kinds of rings.
They impose extra conditions on multiplication to avoid problems like zero divisors.
⭐ 1. Integral Domain
An integral domain is a commutative ring with identity (1) in which zero divisors do not exist.
✔ Formal Definition
A ring (R) is an integral domain if:
- (R) is commutative under multiplication
- (R) has a multiplicative identity (1 ≠ 0)
- No zero divisors:
[
ab = 0 \Rightarrow a = 0 \text{ or } b = 0
]
⭐ Zero Divisor
An element (a \neq 0) is a zero divisor if:
[
\exists b \neq 0 \quad \text{such that } ab = 0
]
Integral domains do not allow such elements.
⭐ Examples of Integral Domains
✔ 1. Integers ℤ
No zero divisors
1 is identity
Multiplication is commutative
→ Integral domain.
✔ 2. Polynomial rings over a field
F[x] is an integral domain.
✔ 3. Rational numbers ℚ (but note: ℚ is actually a field)
Every field is an integral domain.
✔ 4. Real numbers ℝ
✔ 5. Complex numbers ℂ
⭐ Non-examples (NOT Integral Domains)
✘ 1. ℤ₆ (integers mod 6)
2 × 3 = 0 (mod 6) → zero divisors exist.
✘ 2. 2×2 matrices
Matrix multiplication is non-commutative and has many zero divisors.
✘ 3. ℤ₄
2 × 2 = 0 (mod 4)
So these are not integral domains.
⭐ Key Property of Integral Domains
[
ab = ac \text{ and } a \neq 0 \Rightarrow b = c
]
Integral domains satisfy the cancellation law for multiplication.
⭐ Relationship
Every field is an integral domain,
but every integral domain is not a field.
⭐ 2. Fields
A field is a commutative ring with identity in which every non-zero element has a multiplicative inverse.
✔ Formal Definition
A ring (F) is a field if:
- (F) is commutative under multiplication
- (F) has a multiplicative identity (1 ≠ 0)
- Every non-zero element is invertible:
[
\forall a \neq 0, \exists a^{-1} \text{ such that } aa^{-1} = 1
]
⭐ Examples of Fields
✔ 1. Rational numbers ℚ
Every non-zero rational a/b has inverse b/a.
✔ 2. Real numbers ℝ
✔ 3. Complex numbers ℂ
✔ 4. Finite fields 𝔽ₚ (or ℤₚ) where p is prime
Example: ℤ₇ is a field
(1 to 6 all have inverses)
⭐ Non-Examples (NOT Fields)
✘ 1. Integers ℤ
Inverse of 2 is not an integer.
So ℤ is an integral domain but not a field.
✘ 2. ℤ₆
Has zero divisors → cannot be a field.
✘ 3. Polynomial rings F[x]
Infinite, not every polynomial has multiplicative inverse.
⭐ Key Comparison
| Feature | Integral Domain | Field |
|---|---|---|
| Ring is commutative | Yes | Yes |
| Has multiplicative identity | Yes | Yes |
| Zero divisors | No | No |
| Multiplicative inverse for every non-zero element? | No | Yes |
| Example | ℤ, ℤ[i] | ℚ, ℝ, ℂ, ℤ₇ |
⭐ Hierarchy of Algebraic Structures
[
\text{Field} \ \Rightarrow \ \text{Integral Domain} \ \Rightarrow \ \text{Commutative Ring with Identity} \ \Rightarrow \ \text{Ring}
]
Meaning:
- Every field is an integral domain
- Every integral domain is a ring
But not every ring is an integral domain, and not every integral domain is a field.
⭐ Special Theorems
✔ Theorem: Finite integral domains are fields.
If R is a finite integral domain, then every non-zero element has an inverse → R is a field.
⭐ Quick Exam Answer Summary
Integral Domain:
A commutative ring with identity and no zero divisors.
Field:
A commutative ring with identity where every non-zero element has a multiplicative inverse.
Key Points:
- Fields ⊂ Integral Domains
- Integral domains generalize integer arithmetic
- Fields allow division (except by zero)
Examples:
- ℤ (integral domain, not a field)
- ℚ, ℝ, ℂ (fields)