>A topological space $A$ that is also a ring with operations '+' and '.'   where  $ A\times A$  carries product topology, is a semi-topological ring if the mappings $$a_1: A\times A \to A\ \text{such that}\ (x,y)\to x+y$$ , $$a_2: A \to A\ \text{such that}\ x\to -x$$ and $$a_3: A \to A\ \text{such that}\ (x,y) \to x.y$$ are semi-continuous.

>A topological space $A$ that is also a ring with operations '+' and '.'   where  $ A\times A$  carries product topology, is a B-topological ring if the mappings $$a_1: A\times A \to A\ \text{such that}\ (x,y)\to x+y$$ , $$a_2: A \to A\ \text{such that}\ x\to -x$$ and $$a_3: A \to A\ \text{such that}\ (x,y) \to x.y$$ are b-continuous.

where,

>A function $f:X \to Y$ from topological space $X$ to topological space $Y$ is said to be b-continuous (semi continuous) if for each $x\in X$ and
each open set $U \subset Y$ containing $f(x)$ there exists a b-open (semi-open) set $V \subset X$ containing $x$ such that $f(V) \subset U$.

> A set $B$ is called b-open if $B \subset Int(cl(B)) \cup cl(Int(B))$ and $S$ is semi open if $S \subset cl(Int(S))$

Clearly, Topological rings $\implies$ semi-topological rings $\implies$ B-topological rings but not conversely.

After all these definitions I seek a B-topological ring that is not semi-topological. I already have other counterexamples but this one I have no idea about.