The purpose of this paper is to introduce two new classes of rings that are closely related to the classes of Prüfer domains and Bezout domains. Let H = {R | R is a commutative ring with 1 6= 0 and Nil(R) is a divided prime ideal of R}. Let R ∈ H, T (R) be the total quotient ring of R, and set φ : T (R) −→ RNil(R) such that φ(a/b) = a/b for every a ∈ R and b ∈ R \ Z(R). Then φ is a ring homomorphism from T (R) into RNil(R), and φ restricted to R is also a ring homomorphism from R into RNil(R) given by φ(x) = x/1 for every x ∈ R. A nonnil ideal I of R is said to be φ-invertible if φ(I) is an invertible ideal of φ(R). If every finitely generated nonnil ideal of R is φ-invertible, then we say that R is a φ-Prüfer ring. Also, we say that R is a φ-Bezout ring if φ(I) is a principal ideal of φ(R) for every finitely generated nonnil ideal I of R. We show that the theories of φ-Prüfer and φ-Bezout rings resemble that of Prüfer and Bezout domains.
[1]
Ayman Badawi.
On Nonnil-Noetherian Rings
,
2003
.
[2]
Ayman Badawi.
Remarks on pseudo-valuation rings
,
2000
.
[3]
Ayman Badawi.
On divided commutative rings
,
1999
.
[4]
J. Huckaba.
Commutative Rings with Zero Divisors
,
1988
.
[5]
D. D. Anderson,et al.
Characterizing prüfer rings via their regular ideals
,
1987
.
[6]
T. G. Lucas.
Some results on Prüfer rings.
,
1986
.
[7]
D. Dobbs.
DIVIDED RINGS AND GOING-DOWN
,
1976
.
[8]
Max D. Larsen,et al.
Multiplicative theory of ideals
,
1973
.
[9]
R. Gilmer,et al.
Multiplicative ideal theory
,
1968
.
[10]
C. U. Jensen.
Arithmetical rings
,
1966
.