RINGS WITH UNIQUE ADDITION

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RINGS WITH UNIQUE ADDITION Dedicated R. E. JOHNSON to the Memory of Tibor Szele Introduction. The ring {R; +, } is said to have unique addition if there exists no other ring {R; +', } having the same multiplicative semigroup {7?; J. If {R; +, } and \R; +', } are different rings, then the 1-1 mapping 8: ad = a, a F, of {7?; +, } onto \R; +', } is multiplicative but not additive. Conversely, if there exists a 1-1 mapping 6 of ring {R; +, } onto ring {S; +', } that is multiplicative but not additive, then the ring R does not have unique addition. For we need only define +' on 7? by: a-\-'b = (a6-\-'b9)d~l to obtain a new addition operation on R. Thus, it is clear that every 1-1 multiplicative mapping of ring R onto some ring 5 is additive if and only if 7? has unique addition. Rickart [l ] has shown that a semi-simple1 ring satisfying certain minimum conditions has unique addition. We shall extend Rickart's results to a larger class of rings with minimum conditions in this paper. We have not been able to find any general results for rings without minimum conditions. Preliminary remarks. If the multiplicative semigroup {R; } can be made into a ring, then there must exist a unique zero element 0 in 7? such that 0a = a0 = 0 for every a F. Let us assume that R has a zero element 0. An operation o on R will be called a DO-operation if the following two conditions are satisfied: (D) (a o b)c = ac o be, c(a o b) cao cb, a, b, c F. (O) ao0=0o8 = 0, aer. If a o b = 0 for every a, bea, a subset of R, then o is said to vanish on A. A ring without unique addition has DO-operations defined on it in an obvious way. Thus, if {R; +, } and {R; +', } are different rings, define o on R as follows: aob = (a+ b) - (a +' b), a, b R. It is easily verified that o is a DO-operation R. that does not vanish on Presented to the Society December 29, 1956; received by the editors April 3, 1957. 1 While Rickart does not specifically say that the ring is semi-simple in his Theorem II, it is not difficult to show that his assumptions imply semi-simplicity. 57

58 R. E. JOHNSON [February It is clear from our remarks above that if all DO-operations on a ring R vanish on R, then R has unique addition. This fact will play a primary role in proving the uniqueness of addition on the rings of the next section. We shall designate by Ar ia1) the right (left) annihilator of the subset A of a ring R. We shall also designate by (E) the lattice of all right ideals of R and by A(E) the sublattice containing all AQ (R) for which Ar\B?*0 for every nonzero E (E). Rings with zero singular ideal. If R is a ring, the set RA = {x;xq R, x' Q A(E)} is an ideal of R, called the singular ideal in [2]. We shall assume in the remainder of the paper that R is a ring such that For each ^4 (E), let us define As = {x; x RA = 0. R, x~la A(E)}, where x_1^4 = {y; xy ^4 }. It is easily shown that ^4" (E), 5 is a closure operation on (E) [3, 6]. and that Lemma 1. If AQ ir) and o is a DO-operation on the ring R that vanishes on A, then o vanishes on A". Proof. Let x, yqa3 and B=x~1Ar\y~1A, an element of A(E). Since xbqa and ybqa, (xoy)5 = 0; and therefore xoy=0 since (x o y)r A(E). This proves the lemma. A minimal nonzero element of 'ir)= {A*; ^4 (E)}, if such exists, is called an atom. The closure operation s on (E) is called atomic if each nonzero element of "(E) contains at least one atom. The union S of the atoms of S(E) is called the base of R. It may be shown that 5 is an ideal of R and that 5' = 0 if and only if 5 is atomic. If R is a semi-simple ring with minimal right ideals and if the union S of the minimal right ideals of R is such that 5( = 0, then clearly RA = 0 and 5 is an atomic closure operation on (E). An example of a ring that satisfies our assumptions but is not semi-simple is given below. Example 1. Let 7 be the ring of integers and E = en7+e2i7-(-e227, the ring of 2X2 triangular matrices over 7. This ring has a radical, namely the nilpotent ideal e2i7. Each A A(E) necessarily contains elements of the form &ien + &2e2i with kt9*0. Clearly, then, EA = 0. The right ideals enr and e22r are atoms of 8(E). Hence 5 is atomic even though the ring R itself has no minimal right ideals.

1958] RINGS WITH UNIQUE ADDITION 59 If 5 is atomic, it is known [3, 6.9] that for x F, (xr)s is an atom of "(7?) if and only if xt is a maximal element (r^r) of S(R). Lemma 2. 7/x, yer are chosen so that xr+y A(F), then x o y = 0 for every DO-operation o on R. Proof. Since (x o y)xr = (x o y)yr = 0, (xo y) (xr +yr) = 0 and x o y = 0. Lemma 3. If s is atomic and A is an atom of "(R) such that A" is not a maximal element of "(R), then every DO-operation vanishes on A. Proof. Let o be a DO-operation on R. If x and y are nonzero elements of A such that xr^yr, then xr+yre A(R) and xoy = 0 by Lemma 2. If xr = yr, there must exist some nonzero z ^4 such that zt9 xr, for otherwise Ar = xr, a maximal element of '(R). Now (y-\-z)r is a maximal element of S(R) and (y+z)r^xr; hence x o (y-\-z) =0. Since [x o (y-\-z)]zr = (x o y)zr = 0 and (xoy)xr = 0, (x o y)(xr+zr) =0 and x o y = 0. This proves the lemma. The reason for the hypothesis that AT is not maximal in S(R) is apparent if we let F be a field. Then R is an atom of '(R) and Fr = 0, a maximal element of "(R). However, not all fields have unique addition, as Rickart shows in his paper. Lemma 4. If s is atomic and AE "(R) is an atom such that AT is maximal in "(R), then there exists an atom BE "(R) such that Br = Ar and B is an integral domain. Proof. Since RA = 0, there exists an atom 73 S(F) such that BC\Ar = 0. Thus xbp^o and xbb'^0 for each nonzero xea and b, b'eb. Hence B is an integral domain, with Br = Ar. Let us call two atoms A and B of '(R) perspective [3, 6], and write A~B, if and only if a'=br for some nonzero aea and beb. If R is semi-simple, two minimal right ideals are perspective if and only if they are isomorphic as right F-modules. We shall also call an atom A of "(R) isolated if BT is a maximal element of "(R) for every B~A. Lemma 5. If s is atomic and o is a DO-operation o vanishes on each nonisolated atom of S(R). on the ring R, then Proof. Let A be a nonisolated atom of S(R). If Ar is not maximal in *(F), o vanishes on A by Lemma 3. If Ar is maximal, then by Lemma 4 there exists an atom B such that Br = Ar and B is an integral domain. Since B is nonisolated, there exists an atom C~^4 such that Cr is not maximal in "(R). Also C~73 and there exist nonzero

60 R. E. JOHNSON [February bqb and cqc such that bt = C. Clearly bb9*0, and therefore cb9*0. Since o vanishes on C, c(x o y) =cx o cy = 0 for every x, y E. Hence bixo y)=bxo by = 0 for every x, y E, and o vanishes on bb, and also on B = ibb)s by Lemma 1. Now for any nonzero aqa, ab9*0. Since a(xoy)=0 for every x, y E, o vanishes on ab and also on A = iab)s. This proves the lemma. We might suspect from Lemma 5 that if the ring R has no isolated atoms, so that every DO-operation vanishes on each atom, then the ring has unique addition. That this is not true is illustrated by the following example. Example 2. Let E be the field of integers modulo 2 and R = enf +e2ie+e3ie-f-e32e be a subring of the ring of 3X3 matrices over F. Define the mapping 0 of R onto R as follows: if a = 22,- oiidi + ae32, let a0 = a + aia2e3x. It is an easy exercise to prove that 0 is a 1-1 multiplicative of R onto R and that 02 is the identity mapping. Since mapping (en + e2i)0 = en + «2i + eil; clearly 0 is not additive on R. If en0 + e2i0 = «n + e2i, b = 2 /3,-eii + ^e32, then E has another addition +' defined by: a +' b = (ad + bd)d = a + b + (a^ + a2/3i)e3i. All the atoms of 8(E) for this example are perspective, and one of them, namely e3ie- -e32e, has an annihilator e3ie+e32e which is not maximal in *(E). Thus every DO-operation o vanishes on each atom of *(E) by Lemma 5, although o does not necessarily vanish on E, since E does not have unique addition. It is clear from this example that some further restriction must be placed on the ring R to insure unique addition. We shall give two possible ways of doing this. Theorem 1.7/5 is atomic and the base S of Ris such that Sr = 0, and if '(E) has no isolated atoms, then the ring R has unique addition. Proof. Let o be a DO-operation on R. By Lemma 5, o vanishes on each atom of '(E). If x, yqr, then c(x o y) =cx o cy = 0 for every c in some atom C. Since Sr = 0, evidently xoy = 0. This proves the theorem.

1958] RINGS WITH UNIQUE ADDITION 61 The ring E of Example 1 satisfies the conditions of Theorem 1. Therefore addition is unique for this ring. In Example 2, S = R and S' = e3ie+e32e^0. Theorem 2. If s is atomic and, for each atom A of "(E), Ar is not maximal in "(E), then the ring R has unique addition. Proof. Let o be a DO-operation on R. If A and B are atoms and xq-a, yq-b, then xoy = 0 by Lemma 2 if xr9*yr. If xr = yr9*r, we may select a nonzero zqa such that zr9*xt. Since ix-\-z)r9*yr, (x+z)oy = 0 by Lemma 2. Hence [(x-f-z) oy]zr=(x oy)zr = 0, (x o y)xr = 0, and x o y = 0. We conclude that x o y = 0 if x and y are in atoms of *(E). If x, yqr, then for every aqa, an atom of "(E), either xa = 0 or (xa)r is a maximal element of "(E), and similarly for ya. Hence each of xa and ya is in an atom of "(E), and (x o y)a=xa o ya = 0 by the previous paragraph. Thus (xoy)5 = 0 and xoy = 0 since Sl = 0. This proves the theorem. The ring R of Example 2 fails to satisfy the conditions of Theorem 2 in that many of the atoms have maximal annihilators. Bibliography 1. C. E. Rickart, One-to-one mappings of rings and lattices, Bull. Amer. Math. Soc. vol. 54 (1948) pp. 758-764. 2. R. E. Johnson, The extended cenlralizer of a ring over a module, Proc. Amer. Math. Soc. vol. 2 (1951) pp. 891-895. 3. -, Structure theory of faithful rings, II. Restricted rings, Trans. Amer. Math. Soc. vol. 84 (1957) pp. 523-544. Smith College

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