On primitive integer solutions of the Diophantine equation t2=G(x,y,z) and related results

Abstract

In this paper we investigate Diophantine equations of the form T2=G(X),\; X=(X1,…,Xm), where m=3 or m=4 and G is specific homogenous quintic form. First, we prove that if F(x,y,z)=x2+y2+az2+bxy+cyz+dxz∈[x,y,z] and (b-2,4a-d2,d)≠ (0,0,0), then the Diophantine equation t2=nxyzF(x,y,z) has solution in polynomials x, y, z, t with integer coefficients, without polynomial common factor of positive degree. In case a=d=0, b=2 we prove that there are infinitely many primitive integer solutions of the Diophantine equation under consideration. As an application of our result we prove that for each n∈\0\ the Diophantine equation equation* T2=n(X15+X25+X35+X45) equation* has a solution in co-prime (non-homogenous) polynomials in two variables with integer coefficients. We also present a method which sometimes allow us to prove the existence of primitive integers solutions of more general quintic Diophantine equation of the form T2=aX15+bX25+cX35+dX45, where a, b, c, d∈. In particular, we prove that for each m, n∈\0\, the Diophantine equation equation* T2=m(X15-X25)+n2(X35-X45) equation* has a solution in polynomials which are co-prime over [t]. Moreover, we show how modification of the presented method can be used in order to prove that for each n∈\0\, the Diophantine equation equation* t2=n(X15+X25-2X35) equation* has a solution in polynomials which are co-prime over [t].