This should be a simple question on basic definitions.
In an integral domain $R$ we will say that $gcd(x,y)$ exists and is equal to some $r\in R$ if $r$ divides $x$ and $y$, and any common divisor $r'$ of $x,y$ divides $r$ (i.e. there exists an $e\in R$ such that $r=r'e$).
Now, is it always true for $x,y,z\in R$ that $gcd(zx,zy)$ necessarily exists if $gcd(x,y)$ does (then it can be easily verified that $gcd(zx,zy)=z\cdot gcd(x,y)$)? This statement seems to be wrong in general: for a field $k$ consider the domain $R=k[x,y,z,t]/(xt-yz)\cong k[x,y,z,yz/x]$. Then $gcd(x,y)=1$, whereas $gcd(zx,zy)$ does not exist, since both $x$ and $z$ are common divisors of $zx$ and $zy$. Is this correct?
Also (as shown by this example) it seems that $gcd(x,yz)$ does not have to be $=1$ if $gcd(x,y)=gcd(x,z)=1$. Is this true?
