In this paper, we consider the Goldbach's problem for matrix rings, namely, we decompose an n × n (n 〉 1) matrix over a principal ideal domain R into a sum of two matrices in Mn,(R) with given determinants....In this paper, we consider the Goldbach's problem for matrix rings, namely, we decompose an n × n (n 〉 1) matrix over a principal ideal domain R into a sum of two matrices in Mn,(R) with given determinants. We prove the following result: Let n 〉 1 be a natural number and A = (aij) be a matrix in Mn(R). Define d(A) := g.c.d{aij}. Suppose that p and q are two elements in R. Then (1) If n 〉 1 is even, then A can be written as a sum of two matrices X, Y in Mn(R) with det(X) = p and det(Y) = q if and only if d(A) [ p - q; (2) If n 〉 1 is odd, then A can be written as a sum of two matrices X, Y in Mn(R) with det(X) = p and det(Y) = q if and only if d(A) | p + q. We apply the result to the matrices in Mn(Z) and Mn(Q[x]) and prove that if R = 7. or Q[x], then any nonzero matrix A in Mn(R) can be written as a sum of two matrices in Mn(R) with prime determinants.展开更多
文摘In this paper, we consider the Goldbach's problem for matrix rings, namely, we decompose an n × n (n 〉 1) matrix over a principal ideal domain R into a sum of two matrices in Mn,(R) with given determinants. We prove the following result: Let n 〉 1 be a natural number and A = (aij) be a matrix in Mn(R). Define d(A) := g.c.d{aij}. Suppose that p and q are two elements in R. Then (1) If n 〉 1 is even, then A can be written as a sum of two matrices X, Y in Mn(R) with det(X) = p and det(Y) = q if and only if d(A) [ p - q; (2) If n 〉 1 is odd, then A can be written as a sum of two matrices X, Y in Mn(R) with det(X) = p and det(Y) = q if and only if d(A) | p + q. We apply the result to the matrices in Mn(Z) and Mn(Q[x]) and prove that if R = 7. or Q[x], then any nonzero matrix A in Mn(R) can be written as a sum of two matrices in Mn(R) with prime determinants.
