$\newcommand\la{\langle}\newcommand\ra{\rangle}$Let $K$ be a field and $K\la x,y,z\ra$ the non-commutative polynomial ring in 3 variables.
Question 1: Are there three (fewer is probably not possible?!) polynomials $f,g,h \in K\la x,y,z\ra$, which are sums of monomials of degree at least two, such that the algebra $K\la x,y,z\ra/(f,g,h)$ is finite dimensional?
Is there a systematic way to construct such polynomials?
For two variables we can take for example $f=xy+yx$ and $g=x^3+y^3$, but I do not know (or forgot) such examples for more than 2 variables.
(If possible we should also have (this is equivalent to $(f,g,h)$ being an admissible ideal) that there exists an $n \geq 2$ such that $J^n \subseteq (f,g,h)$ where $J=\la x,y,z\ra$ is the ideal generated by $x,y,z$.)
Question 2: Let $f_i$ for $i=1,\dotsc,n-1$ be polynomials spanning an admissible ideal in the non-commutative polynomial ring in $n-1$ variables $x_i$. Can we find $g$ such that $\la f_i,g\ra$ is an admissible ideal in $K\la x_i,y\ra$?
\DeclareMathOperatorimparts the spacing of, well, an operator to its argument. Note the difference between $\DeclareMathOperator\la{\langle}\DeclareMathOperator\ra{\rangle}K\la x, y, z\ra$\DeclareMathOperator\la{\langle}\DeclareMathOperator\ra{\rangle}K\la x, y, z\raand just $K\langle x, y, z\rangle$K\langle x, y, z\rangle. I have edited accordingly. (But thanks for using\langle\rangleat all!) $\endgroup$