p-complete square-free Word-representation of Word-representable Graphs

A graph $G = (V,E)$ is word-representable, if there exists a word $w$ over the alphabet $V$ such that for letters ${x,y} \in V$ , $x$ and $y$ alternate in $w$ if and only if $xy$ is an edge in the graph $G$. In this paper, we introduce the concept of $p$-complete square-free word-representable graph $G(V,E)$. A word $w$ defined over alphabet $V$ is called $p$-complete square-free word if there does not exist any subset $S\subseteq \Sigma$ such that the word $w_{S}$ contains a square $XX$ where $|X| \ge p$ and $1\le p \le |w|/2$. A word-representable graph is considered $p$-complete square-free word-representable if there exists a $p$-complete square-free word-representant of that graph. This pattern is significant as it proves the existence of patterns that do not depend on graph labelling and cannot be avoided by certain classes of word-representable graphs. The class of word-representable graphs includes both $p$-complete square-free word-representable graphs and non-$p$-complete square-free word-representable graphs. Additionally, this concept generalises the square pattern found in the words. A word-representable graph is $p$-complete square-free uniform word-representable if its $p$-complete square-free word-representant is a uniform word. We analyse the properties of $p$-complete square-free uniform words and find that the graphs represented by these words avoid having $K_p$ (the complete graph on $p$ vertices) as an induced subgraph. We provide classifications for small values of $p$: for $p=1$, only complete graphs and for $p=2$, only complete and edgeless graphs satisfy the condition. We find that $K_3$-free circle graphs are 3-complete square-free uniform word-representable. Furthermore, we establish that only graphs with representation number at most 3 can be 3-complete square-free uniform word-representable and provide a constructive method to generate such graphs.